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Electronics in Industrial Applications A Discussion of Fundamental EMC Principles for Electronic Controllers In an Industrial Environment By William D. Kimmel, PE i

Kimmel Gerke Associates. Ltd EMC problems eth mdustna! controls are bances are a well known icdustnal problem.

cally a power disturbance prob:em. is oft aggravated by harsh environments, mixed in fact when a problem occurs. the first the camer of residual effects of pow technologies and a lack of uruform EMC thougt.t is to blame the power company, disturban:es. Any industnal or commere gwdelines. This art:cle mil concentrate on Often power cuahty is a problem (especia:Iy structure has sign:Seant :ow 'requen the common aspects of electroruc controls if groundmg issues are included). but the l

m an :ndustnal env:ronment, which is problem is almost always generated by system. sometimes because the energy currents arculating through the grou generally much harsher than the of5ee adiacent equipment.

intentionally dumped onto the ground (su environment.

Traditional problems with power include as with an arc welder) and sometim What is the industnal environtnent and spikes and transients, sags and surges. and because of unmtentional couphng or ev.

what can be done about it? The em tronment outages, which threaten the electrorucs via an inadvertent connection between neuu mcludes the enure gamut of the basic the power supply. These problems are threats. power disturbances. RFI. and fairly well documented and are often solved and ground somewhere in the facdity.

Radio Frequency Interference. R ESD. RFI and power disturbances may be using power conditionen or UPS.

dio frequency interference affects bo ba!!y generated or not. Mixed technolo-The most common power problems analog and digital ciremts, with analc gies cocund the problem. Digital circuits confrontmg electronics today is the sag circuts being generally more susceptibh are used to switch Ime voltages via relays.

which typically occurs dunng turn en and Surpnsing to many, the prmople threat.

Analog sensors are mput devices to digital

controls, the spikes which typically occur dunng turn not the 'IV or FM station down the roac off of heavy inductive loads. "he sags but rather it is the hand held transtn:tte Increasingty, there is a need for a simply starve the electronics. The high camed arouno by faalices personnel. A on.

ooperaove effort between the designers.

frequency transients barrel right through watt radio will result m an electnc 6 eld c manufacturers and installers to co_me up the supposedly filtered power supply to five volts / meter at a one meter distance with a rock. solid system. A common attack the electronics inside.

complaint is that the mstallers or mainte-Digital circuits are most vulnerable to enough to upset many electrorucs systems IEC 801.3 spec 5es imrnurury to electn nance people won't follow the installation spikes which cause data errors or worse.

Belds of one to ten volts per mete reqwrements. This may be true, but it Analog arcuits are most vulnerable to depending on the equipment, with thre must change. smee there are problems which cannot be solved at the board level.

conunuous RF riding on top of the power.

volts per meter being the level for typic:

FIPS PUB 94 provides guidelines on equipment. As can be seen from the abov It is also ' rue that manufacturers often electncal power for commercial computers.

specify installauon requirements which are His is good information, but beware that approximation, three volts per meter is nc not practical to implement, and there are factory power is much noisier than commer-an excessive requirement, and even te:

volts per meter is fairly modest.

documented cases where the prescribed cal power.

Electrostatic Discharges. Electro-instal! acon procedures wid cause rather The guidelines of IEC 801.4 rpeci5es an static discharge is an intense short duracon than cure a problem.

electrically fast transient (EF'i; that simu-pulse, harmg a nsetime of about The lack of uniform guidelines has ham-lates stems and other high speed noise, nanosecond. His is equivalent to a burst one pered EMC progress in the indust:ial EFTS are quite short ranged - they of 300 MHz interference. Staue buddups arena. Fortunately, the European Commu.

dimmish rapidly with distance due to induc.

of 15 kV are not uncommon.

ruty is working to adopt the IEC 801.x tance in the line. But at Short range, they Dry climates, including northern climates specifications, and domestic compacies are devastatmg.

would be wise to adopt them, even if there Unfortunately, attention is placed on the is no intention to export.

I front end of the electrorucs, the power William Kunmelis a pnnapal wrth Kimmel The Basic Threats supply. With industnal controls, the prob.

Gerke Associates, Ltd. The Erm spenal-The three basic threats to industrial lem is the controlled elements. If the ises in prerecong and solving electromas-electrornes are power disturbances, radio electronics is controlling line power, the neoc intederence and companbibry (EMI/

frequencyinterference. and ESD.

disturbances sneak in the back end where EMC) problems. Mr. Kimmel can be little or no protection exists.

reached at 1544 N Pascal. St. Paul, MN Power Disturbances. Power distur-System ground, while not being specs-55106, or telephone 612-330-3725.

EMC Test & Design 35 t

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Figure !. Amph5er demodulation.

Figure 2. Trans>ent feedback path.

m w mter, offer opportunity for ESD.

encounters a nordineanty such as a semicon.

Industnai environments, w:th the:r movmg ductor device. A!! such devices give nse to to heavy equipment, whJch is character equipment, are loaded mth potential ESD a DC level shift when confronted mth RF.

by heavy startmg l cads and inducuve sources: rubber roDers, belts, and produc.

In a radio receiver they are caBed detec-at turn off. Typicany the e!ectroruc con switch line power utmg relays or tr tion output such as plastic and paper reus, tors. Nordineanoes are mirumized in liacar - This exposes the back end of the con a:1 add up to a real ESD threat, and this devices. but there is always enough to cruse to substcntialline transients, which ec threat is more hkely to occur even m problems. The upshot is that the amph5er back to the ciremt power and ground relauvely moist environments. I.ook to IEC demodulates the RF, generates an errose-disrupt the distal ciremtry as show 801.2 for ESD standards.

ous signal, and passes this error on. This Figure 2.

Electronics Design effect is shown in Figure 1. Output lines are It is mandatory that the transient simdarty affected, with capacitive coupling rents be diverted or blocked. since Electronics is generacy the uiumate back to the mput, vicum of mterference. The interference digital system cannot mthstand the ma finds :ts way through various paths to the The solution is to prevent the RF from tudes IIkely to occur with an educuve k gettmg to the amph5er, either by shielding uniese special steps are taken.

electrorucs eqwpment its?If. Let's concen-or Stenng. The most common path to the Self Jammmg can be lirruted by control trate on what can happen to your electronics ampli5er is via an external signalline from when you switch the line, usmg 2 from the back door, that :s. by direct the sensor, but if the electronics is not crossing devices. Of parucular importa.

ratauon into the electrorucs and by con-shielded. direct radiat on to the circuit board is the turn off, since that is when ducted sterference through the signal and may also present a problem, inductrve kick occurs.

control bnes.

Assunung Stenng is the selected method, If aH power switchmg used zero cross Sensors. Low level sensors such as use a lugh frequency Ster, designed to devices, the transient levels in the fact.

thermocouples, pressure sensors, etc., are block signals up to 1 GHz or even trore.

would be dramaticaDy reduced. Unfot charactenzed by very low bandwidths and Use femtes and high frequency capacitors.

nately, that goal is well off in the futu l

4 low s:g':a! levels. A major threat to these Do not rely on your low frequency Star to Until then. expect that high voltage pos sensors is radio frequency mterference, take out RF.

transients will occur, and they must be de

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either from nearby hand held transmitters At the op amp. you should also decouple with.

or more distance land mobde or f:xed your plus and mmus power to ground at the Optical couplers and relays do not prov 1

transtrutters.

chip. If your ground is carrymg RF, you can sufficient isola 00n by themselves. Th

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But these are high frequency, much anticipate the same problem mentioned high -

provides an exceuent h:

above the bandpass of your arcph5er, right?

above, since it wd! corrupt the reference frequency path, and if they are stacked Wrong! Low frequency amph5ers are level.

in an array, the capacitance m0 add up plagued by two phenomena: out of band Data Lines. Digital data lines will be peas surprisingfy low frequences. The response and audio recuScation. These combine to provide false information on upset by the RF problem as in analog, but capacitances can't be ehminated, but y<

the levels necessary to upset are higher, can design your control circuits to muunu.

levels to the system.

Instead, digital data lines are much more coupleg paths and to maximize low unpe All amplifiers have a normal bandpass, susceptible to transient glitches. AI signal ance attemate paths.

typt5ed by a 20 dB/ decade rolloff or more lines should be Stered to paas only the Trsasient suppressors should be instaUe at the high end. But resonances due to stray mductance and capaatance mU give nse to frequences necessary for operation. If the at the loed, which is the source of the spik.

threat lies in the bandpass of the signal, but they can be insta!!ed at the controue amphfier response Sve orders of magnitude then shielding or opucal links will be as we2.

or more above the nominal bandpaas of the needed.

An interesting effect occurs when con arnplifier. This means an audio amph5er Switched Power Lines. His refers bining zero crossmg SCR regulators mt wdl respond to signals m the hundreds of MHz.

specfically to the power being controDed low level sensors which use line frequene by the controller device. Induatrial control-noise canceling techmques. Very sens:uv The second aspect occurs when RF lers are commonly tasked to control power sensors sometimes are sampled for a 36 My M: gust ?

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i Figure 3. Cominon mdustnal power supply.

Figure 4. Muluple ground paths.

entre power cycle to cancel the line More citen the problem is conducted.

eliminate RF or g ound noise. That frequency component. If the samp'e occurs either via power or ground. The problern or off, the average to the sensor will be occurs due to power and ground distur-work, but these problems can be so concurrently with ;ine power switching on bances caused by the equipment. It is an all with an isolation transformer to e!imi upset, and an error wdl be recorded.

neutralto ground noise and mth EMI po too common pract;ce to draw contro!!er line Siters. So you may want to try System Design and Installation power from the same source as feeds the inexpensive approach first.

power eg.upment. This power may provide Once the electronics is designed, it the necessary energy to dnve the equip-Data Links. Data links are strung becomes a problem of the system integrator ment, but it is not suitable to power the over the entire fact!ity, exposing therr and insta!!er to ensure that the electrorucs electrorucs (Figure 31.

two prtnciple effects, ground noise and is provided mth the environrnent for which Hopefully, all industrial equipment wiu pickup. Ground noise mD cause data ert work is performed by power experts and have electronics powered from a separate unless the electronics has been designet it was designed. Most of the time, this electncians, and they are not always aware low power 120 volt circuit. It solves several accommodate potental differences of s of the mterference problem. Often, on site.

problems. First, it separates the electron-eral volts or more. This is accompi:st mth differential dnvers and receivers tf t!

the power quality is blamed for the equip-its power from the. probably very noisy must be direct coupled. Optical links -

ment anomahes. But the problem can often industr:al grade power, preventing the eventually take over these links.

be avoided by followmg a few basic prmes.

smtching transients and startup sags from The other aspect is RF pickup. Icexpe ples.

gettmg to the electronics. Second, if it is sive shielded cable is suitable for t.

necessary to condition the electronics power The mdustrial control device is either from an external problem, it is far cheaper purpose. Ground both ends! Do not apt integrated into a system at the factory or to condition the watts needed for electronics smgle pomt ground techniques to RF. It instared separately on site. Controuers power than it is to condition the kilowatts low frequency ground loop problem is handle a vanety of devices such as motor required by the system.

threat, then one end can be capacmve speed controls, positioning devices, weld-grounded.

ers, etc. Interference presented to the If power cannot be separated, then it is electrornes can be sigm6cantly reduced by necessary to provide a bulletproof power Summary appropriate measures outside of the elec-supply, preferably including an isolation Industrial electronics are subjected to trenics box, transformer. to separate the entire power harab environrnent. Good design and inst.

There is no way to accurately assess the supply from the electncal equipment.

threat mthout test data. But regardless of Ground Noise. Ground noise, inevits-lation techtsques will mirumtre problems the mformation available, much can be ble in industrial environments, must be the 6 eld. Adherence to the Europe:

accomplished by correct instaBation, and it diverted from the electronics module, standards,1EC 801.x is a good start. eve doesn't cost much if done at the start.

Multiple grounds in a system wil often if you are only marketing in the USA, s

Retro 6ts become costly, especiaDy if ac-result in ground currents circulaang through Bibliography comparued with factory down time, the equipment, and ground noise circulating FIPS PUB 94, Guidelme on Electncs let's consider the same problems from through the electronics path wiH cause Power for ADP Instauauons. Septembet malfunction. Figure 4 shows some typical 1983.

a system standpoint. Your goal is to limit ground loop situations.

the interference which must be handled by A common approach is to demand a super for industriabprocess measurement IEC 8012, Electromagnetic compatibilit'.

the electrorucs.

Direct radiation to the electrordes is not earth ground. This is good, but it is not a an(

often a problem in an industnal environ-cure all, and often a super ground cannot control equipment. Electrostatic discharge requirements.1964.

be achieved, no matter how you try How IEC 801-3, Electromagnetic compaubilit).

ment. but it does occur, and most often with do you get a super ground from the third for industriahprocess measurement a plasoc enclosure. The NEMA type door? The reat need is to get a stable ground control equipment. Radiated electromag-anc enclosures provide enough shielding for reference to allinterconnected equipments.

netic 6eid requirements,1984.

most mdustnal needs. If you don't want to If this equipment is closely located, then a use a metal enclosure, be sure to get very low impedance interconnect is feasi-IEC 8014. Electromagnetic companbi!ity electronics which mu withstand the RF

ble, for industnal-process measurement ar.s which mil occur.

contro! equipment, Electncal fast transienu Power conditioners are often tasked to burst requirements.1984.

EMC Test & Deun

REFERENCE 2 Industrici Equipment Equipment Ground Bonding -

Designing for Performance and Life A Discussion of Ground Connection Fundamentals to Con By D.B.L. Durham Dyteena Ltd. UK The problem of achieving sausfactory earth bonds or ground connect 2ons has plag.ted eqmpment to a stable ground point achiev.

EMC eng:neers for many years, not only ing adequate levels of cable shielding and for inductance. At very high frequencies because the bonds are often vital for the many other reasons. Many designen un-stray capacitance across the strap achievement of satisfactory equipment pe6 derstand the requirement for short, fat bond dommate. This means that the volt d; formance but because they affect the long leads to minimtre gmund inductance but across a bond is generally a function term performance of eqwpment after it has few appreciate that a critical aspect is the inductance and frequency. Based on Ohr.

been introduced mto service.

connecuen resistance with which the bond Law this volt drop is shown in Equaton For transients the voltage drop as given Recommendacons on bonding have ex-strap is attached to the equipment ground Equanon 5.

isted in the form of mditary specificanons, pomt. The basic requirement of any bond such as Mil Std 1310. MH 188-124A and is that it should have as low an impedance 7,j R' + w L8 2

V i

Md-B 5087 (ASG) for some years and these as possible (unless it is a deliberate induc.

have genera!!y proved satisfactory for most tive bond to limit ground currents). The Y*II"NU new builds. However, these spec 5 cations impedance is a combination of the resistive

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i have certam limitations in that they gener-and the inductive components. The resis-ally do not speedy consistently low levels tive element is a function of the bond strap y = -L y

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of bond impedance, nor a suitable test resistivity, cross sectional area and length, method. The introduction of new EMC see Equation 1 whilst theinductive compo-where Z = strap impedance, w = rada.

specificanons in Europe with the EEC nent is a more complex function of the bond frequency, V = voltage. and ! = current, i

From this, the higher the mductance th.

Directve on EMC and the requirements for strap charactenstics as shown in Equation 2.

more isolated the circuit or box become i

long tenn stability in EMC characteristics R=g from ground. This can have sign:fican i

4 has directed the UK military to review

^

(1) e5ects on eqtapment. including enhance exisung specScations and introduce a new mest of nonne iniection onto occuits, redue Defence Standard to tighten up perform-L.&;

2f tion of fDter performance, and loss o i

ance requirements for military equipment.

2n b+c 2f,

standpoet it may result in more radiauer C

in

+ 0.5 + 0.2235 commention range. From a TEMPES1 Def Stan 58-6 (Part 1)/1 has been intro.

duced to address this area as far as mobile (2) from eqmpment. It would seem from this and transportable communications insta!!a.

i where R = resistance, a = resistivity, f=

that the entens for any bond is the tions are concerned, but the reqmrements length. A = area. 4 = permeability of free inductance and hence the choice of sho j

should have implications in industnal appti.

space. L = inductance, g = relative David Durham served for 22 years in the cations and over the whole electromes 4

permeability, b = strap width, and c = strap Birash Array, where he market iflong term product performance is thickness.

to be guaranteed.

in electncal eagmeenng. gaswd his de The frequency at which the inducuve Alter service in a vanery of appostments be retired to join Bond Degradation element dommates the impedana expres.

the RacalSES company as the Techmcal sion when calculating the totalinductance Earth or ground bonds are generally is, from Equation 3. typically 1 kHz. It wig Afaneser responsihie for the design and considered essentia$ not only for safety reasons but as a means of divertmg EMI be seen therefore that to aB intents and development at communkstion systems.

purposes the bond except at DC and power la N bejamed Dyrecna as the 5fager currents. " locking" careuit boards and frequencies, may be assumed to be an of the Ensmeenns Division, and now is 38 currently Technica/Marketmg3fmger.

July / August 1991 d

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_ i i=r Figure 1. Bond resistance.

Figure 2. Four wire bridge method.

bcnd straps. However, an analysis of :he progressive degradation of bonds, whilst bond inductance shows that for a bond strap the latter can reduce the efficiency of the current the layers heat up and are vapo.

of 100 mmlong,15 mm mde and2 mm thick the impedance at 1 MHz will be 3.8 Ohms.

bond from the moment it is instaued. It is nsed. After the current is removed the film i

parucularly important in commumcations can return. Thus high current techmques 1

It sounds extremely sirr.ple, but work systems, where Sters are instaDed and are not recommended for tesung EMI l

I performed in the USA and UK shows that shielded cable ternunations are made thatbonds. De new Defence Standard in the.

I tf an error is made in the way the strap is the bonds are oflow resistance and retainUK specSes a maximum probe voltage of

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ternunated then a progressive increase in their performance.

100 microvolts. His represents typica!!y a the resistance of the bond strap to box probe current of 50 miHiamps under short juncuan can occur as the equipment ages.

Bond Performance and cirest (< 1 mG) conditions. This is i

EventuaHy the resistance wtB begm to Measurement meuscient to destroy surface sms. The exceed hundreds of ohms and may eventu-ally go open c:rcuit. This can negate the Expenence has shown over a number of classic method for measuring low resistance j

has been to use a four tenninal bndse a effect of the bond strap completely as part years that for long term consistent bond shown in Figure 2. In this case the current of the EMIprotection.

performance a low value of resistance must. is drtven between. two poin!

i What happens with bonds to cause this

. be achieved. Bis is typically 15 nuDiohms.

In Def Stan 56 6 (Part 1)/1 the value hasvoltage across the sample is measured mth change? Essencally a ground connectaon is been set at a maximum of 2 mdbohms. nis e5ects of the probe contact resistance and a high resistance probe. This removes the -

a senes of impedances from the strap level is measured through the individual lead resistance. His is generauy consid.

through to the ground matenal as shown in Figure 1. Each point of contact contnb-bonds. The logic behind this level is '

ered to be a laboratory method as the use -

utes to the total bond performance. As a twofold. Firstly, experience has shown that of four contacts can be awkward. If the lead with communications equipment in particu-result, a change in any contact condition can lar this value of bond resistance is requred resistance can be removed by a calibracon.

result in a change in the total bond resistance. As is weH appreciated, the if consistent performance is to be achieved '

techaque then the four terminals may be contact resistance between two rnetal sur-in terms of reception ef6ciency and trans-repisced with a two terminal system.

faces is a function of the pressure. De mission characteristics. his is i J.d A further possible refinement to the pressure exerted by the tip of a drawing pin so for TEMPEST protected equipments.i techaque is to use a frequency that is not is vastly greater than that from the thumb ne second point is that if the bond has a DC or 50/60/400Hz. In this case 10.4 Hz pressing by itself. Thus the contact from a bisher resistance then there is a pena 5 cant has been chosen. If an acove filteris used j

sharp pomt grves a much higher pressure likelihood that progressive degradation wW to Star out au other electrica! noise, then than a flat point and therefore lower contact occur and the bond resistance wilincrease it is possible to use the bond resistance sneter on powered up systems. It is worth resistance. Measurernents have shown that in value. There wig then be a progressive noting that at this frequency the impedance loss in performance.

sharp points enable contact resistance of a is stiB largely represented by resistance -

few r::icroohm to be achieved whilst similar The mam problem with inessunne bond rather than inductance. The two termma!

i pressures on flat surfaces result in mil-resistances is that it should be measured method is shown in Figure 3.

i lichms of contact resistance. It might be using a low voltage / current technaque.

The introduction of. new EMC/EMI felt that there is little or no diference Most techniques to date for assessmg safety specdications in Europe has made it more between these values. but in reahty there involves driving a large current through the unportant that once made the bonds have is. An essential aspect of a good bond is bond. This checks the bond's abihty to consistent long term performance. This that it should remam so after the equipment carry current but does not necessanly check means measurmg on penodic inspection and has entered use. High pressures also have its EMI protection performance. The rese after memtenance, it is an essential aspect the effect of squeezmg out corrosive maten-son is that many bonds may when in normal of insurmg conastent performance, it has als and insulatmg Ems. The former causes use have a high resistance due to onde and been shown that within months apparendy greasy Sms. but when subjected to a high good bonds can detenorate to high resis.

EMC Test & Design 29 i

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UK Military Experience as a ma:ntenance taso

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There have been two major ;re i

f caused by poor bonds expenenced ;

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l Ni by md ary eqummen: asers. The nrst 4

rinco ecs.stANet

,f degrada: ion.n perictmance &eady j

i tiened m ttus article. The loss of ecm j

i j

cauon range. poor EMI performance A'

other effects all con:nbute to a cons:

l reduct on m equement effaency and.

1 l

ability. The second effect which is.

i difficult to idenufy is that of No Fault F j

(NFF) problems. An analysis of repc i

i faDures from military reliabGty data

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~FlXED RESISTANCE LEADS high, parucujarly in humid chmates.

shown that NFF incidents can be e I

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has been partially confreed by repons :

the Gulf War when a!! forces reportec p.___

- ---I increase m svadabdi:y of equipment ;r.

g dner chmate. Many faults are due to electncal contacts in connectors, but a la g

j Figure 3. Two tennmal bndre method.

nurnber have been idenufied as exces-EMI induced through poor ground bor This may be caused by e:ther a loose gro I

strap or connector terminacon to the t A signiScant unprovement ;n equgm a

i 0

availabQity and performance is expec a

when more recent stausces are analysec The introduction mto the Bnusn Ar e

service of the Dyteena Bond Resistar i

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Test Set - DT 109 has enabled the 1

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8 installed equipment and reduce the c A** M' A

curances of NFF errors. The UK mdita

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mEchm cahbration standard. Th:s mea

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nal bndge method and an accurate 0

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o9 urement procedure and equipment is ah

.g ot y ** p,8 gg where by rmbtary and naval forces who has in use by other NATO nations and e!s, p.

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recognized the same problem.

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sensitzve and secure commurucanons equm CUSTOMlZING Ts 4

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.slON ment. This coupled with an incressmg neet Ao'p>

,sA*f., nuators, protection has lead to an mcreased emphasa COMPAC RF At.

to achieve higher and higher levels of EM j

Coaxial Terrn.

1. s#

snnectors, bems placed on the effectiveness of all types j

of system grounds. These, funher com-Cata 1

. quest bined with a requirement to ensure the long hfe of systems once m service, have

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resulted in the assessment that bonds and a

termmations are one of the pnmary causes 1Ut%12 bncoln Avenue. Hoibrook. NY 11741 of EMI faDures in systems. The require.

1 6%);B5-1200 f AX ;164851914 ment to test these is clear, however the

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means to do so have not always been j

40 INFO / CARD 29 avadable to engineers.

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REFERENCE 3 a

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d Panel Session 4

i PES Summer Meeting, July 12,1989 Long Beach John G. Kappenm, California an, Chairman Power System Susceptibility To laduc'd currents in the system, 2) the interconnected sys-Geomagnetie Disturbances:

tems tend to be more stressed by large region-to-region Present And Future Concerns tr.nsfers, combined with GlC which will simultaneously turn

'""Y"***'i"'"'6"'""**'"'

j power consumer and harmonic current generator and 3) in general, large ENV transformers, static var compensators and i

John C. Kappenman, Minnesota Power relay systems are more susceptible to adverse influence and The effects of Solar-Geomagnetic Disturbances have been found impact of the Marchobserved for decades.on power systems. However, the pro-TRANSFORMER OPERATION 13.1989 geomegnetic distur-The primary concem with Geomagnetically-induced bance has created a much greater level of concem about the rents is the effect that they have upon the operation of large phenomena m the power industry.

ower transformers. The three ms Several man-made systems have suffered disruptions to their in transformers le il the incrosse)or effects d var consumption of the normal operation due to the occurrence of geomagnetic phe-affected transformer,21 the increased even and odd hermon-nications, have been made less susceptible to the phenom-nomena. Most bilities of equipment damaging stroy flux heating. As is well ens through technolog! col evolution (microwave and fiber- - documented, the presence of even a s optic have replaced metallic wire systeine). However the (20 empe or less) will cause a large power transformer to bulk transmission system, if anything, is more suscep,tible hatf-cycle saturate. The half cycle saturation distorted excit-4 today than ever before to geomagnetic disturbance events Ing current is rich in even and odd hermonics which becom And if the present trends continue it is likely the bulk trans-Introduced to the power system. The distortion of the excit-mission network will become more, susceptible in the future.

ing current a6so determines the real and reactive power re-Some of the most concoming trends are:

1) The transmission quirements of the transformer. The saturation of the core systems of today span greater distances of earth-surface-steel, under hetf-cycle saturation, can cause stray flux to en-potentist which result in the flow of larger geomagnetically-ter structural tank members or current windings which has IEEE Power Engineering Review, October 1989 the potential to produce severe transformer heatino.

15

,.~

m

_m

.... ~. o.mr fee tests on ex-isting large power transformtts to evaluate the response o'. ' hemtsonses. Th@ auroral el;ctrojets can oroduce transr2r diffsring transformer core types. The field test results in@*

fluctuations in tM3 carth's magnetic fleid that are termai.

cafe that smgle phase transformers half cycle saturate much geomagnetic storms when thay are of sufficient severityc 3

more easily and to a much greater dagree than Comparable

[

inree phase units. These transformers produce higher mag-SUNSPOT CYCLES AND GEOMAGNETIC '

nituces of harmonics and consume larger amounts of resc-I tive power when compared with tr.ree phase designs.

i On the average, solar activity, as measured by the number of RELAY AND PROTECTIVE SYSTEMS monthly sunspots follows an 11-year cycle. The present i

sunspot cycle 22 had its minimum in September 1986, and 1

There are three basic failure modes of relay and protective is expected to peak in 1990-1991. Geomagnetic field dis.

systems that can De attributed to ggeomagnetic distur-turbance cycles do not have the same shape as the sunspot bences:

number cycles, even though they are cyclical. Figure 1 shows the nature of the sunspot numbers and geomagnetic activit False Operation of the protection system. such as hav-ing occurred for SVC. capacitor and line relay opera-tions where the flow of harmonic currents are misin-svag taat.tess y;Q' -

{

terpreted by the relay as a fault or overload condition.

crm ir cym to cym is cnie 20 cnte 21 ce,sa..,

This is the most common failure mode, I

I I

I

, as a as aos Failure to Operate when an operation is desirable. this

• • ""*** **f****'

N f

I has shown to be a problem for transformer differential protect;on schemes and for situations in which the f 120 output of the current transformer is distorted.

l; lm Slower than Oesired Operation, the presence of GlC y

a; {j fj

,\\

l

.l can easdy build-up high levels of offset or romanent 0 #.,\\'6 l

l

- l'I(?)t ' f **

1. ', D tium in a current transformer The high GlC induced off.

(

se 1-set can significantly reduce the CT time to-saturation.

g l

(./ (

=a,

> 4e i*

for offset fault currents.

', ' V,,

3 Most of the relay and protective system misoperations that are attributed to GlC are directly caused by some malfunc-h M " W " A W "E T E T ys*"s'E"E~~sb tion due to the harsh harmonic environment resulting from -

1.

large power transformer half-cycle saturstion. Current trans-ens of me Yeady-Aweeed Sunepct Number and

'i n

Dieturbed Deye from 1932-1988.

former response errors are more difficult to directly associate '

with the GlC event. For example in the case of CT remen-ence, the CT response error may not occur until several days cycles from 1932 to 19861 after the GlC event that produced the romanence. Therefore, disturbance cycles con have a double peak, one of which can -

i these types of failures are more difficult to subetontiste, leg the sunspot cycle peak. While geomagnetic activity in the

)

present cycle is expected to maximise in approximately CONCLUSIONS 1993-1994, time during the cycle; the K 9 storm of Marchsevere As evident by the March 13th blackout in the Hydro Quebec 13,1989 was a strik8 g exempie; system and transformer heating failures in the eastem US, longe. The power mdustry is more susceptible than ever tothe power industry is f P TENTIAL AND the influence of geomagnetic disturbances. And the mdustry CEOMAGNETICALLY. INDUCED-CURRENTS will continue to become more susceptible to this phenome.

_j The euroral electrojets produce transient fluctuations in the non unless concerted efforts are made to develop mitigation earth's magnetic field during magnetic rtorms. The earth is techniques.

e conducting ophore and portions of it experience this time-varying magnetic field, reeutting in an induced sorth swac e-i Geomagnetic Disturbance CauseS potential (ESP) that can have values of 1.2 to 6 vo'tokm (2 to to voitsimine> durin And Power System Effect$'

8"' '"** **"" **"*g severe geomagnetic storms m re-

• ""'*Y'*'

I i

Electric power systems become exposed to the ESP through Vernon D. Abertson the grounded neutrals of wye connected treneformers at the University of Minnesota oppoelte ende of long transmission lines, se shown in Figure i

i

2. The ESP scte se en ideal voltage source irnpressed be-

- tween the grounded neutrais and hee a frequency of one to SOLAR ORIGINS OF CEOMAGNETIC STORMS a few mehens. De goemagnetically-induced currents (GtC)

The solar wind is a ratified plasma of protons and electrons are then determined by dividing the ESP by the equivalent dc resistance of the paralleled transformer windings and line flares, coronel holes, and disappearing filamente, and the so-cmrfted from the sun lir wind particles interact with the earth's magnetic field to ' neutrals, excess of 100 emperos have been measured in produce eurotel currents, or eurotel electrojets, that follow generally circular paths around the geomagnetic poles et al-titudes of 100 kilometers or more (1). The eurora borealis is - - POWER SYSTEM EFFECTS OF G visual evidence of the euroral electrojets in the northern The per-phose GlC in power transformer windmgs can be

. 16 IEEE Power Engineering Review.' October 1989 i

o g

_,m m..

9' fi g'

4 and retuced tim 7-to-s:turstion in currsnt trans i

~

cause relay misopfration (5),

1

/

^

s

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REFERENCES i

East.e scaract

1. Akosofu, S..l., "The Dynamic Aurore." Scient:fic Amen.

a t'**

,g Magazine. May 1989, pp. 90-97 j

i

? -EARTS$# ACE SQTENT'AL - t

2. Joselyn. J. A., "Real.7,rne Prediction of Global Geom Fisure 2. Induced Earth Surface-Potentist(esp) Producins Georneg-Activity," Soter Wind Megnetosphere Coupling. pp.

12 141 Terre Scientiflc Publishing Company, Totvo,1988.

notically-induced Cunente (G1 Clin Power Systems.

3 Thompson. R. J., "The Amplitude of Solar Cycle 22 " r Radio and Space Services Technical Report TR-87 03.

cor 1987.

many times larger then the HMS ac magnetizing current. re.

4 V. D. Albertson and J. A. Von Boeien.'"Electnc and sutting in a de bias of transformer core flux, as in Figure 3.

Fielde et the Earth's Surface due to Aurote Transections on Power Apperatus and Systems. vol.

No. 2. April 1970, po. $78-584 I

5. J. G. Koppenmen. V. D. Albertson, N. Mohen, "Cu Treneformer and Relay Performance m the Presence e{

4j magnetically. induced Currents,"1EEE Transactior e on Pow j;

Apparatus and Systems. Vol. PAS 100. No. 3, pp.107 toes. Merch 1 set.

lI l a T,

The Hydro-Quebec System Blackout Of March 31,1989 to.oi Q

jetc),,

. Danle! Souller, y

Hydro-Quebec -

On March 13, t g8g, an exceptionally intense magnetic stom Fleure 3. DC eles of Treneformer Core Flus Due to GIC. caused seven Static Ver Compensators iSVC) on the 735-kN network to trip or shut down. These compensatora are es i

sential for voltage control and system stability. With theit.

loss, voltage dropped and frequency increased. This led to The half-cycle saturation of transformers on a power system system Instability and the trippmg of all the La Grande trans.

is the source of nearly aH operating and equipment problems mission lines thereby depriving the HQ system of 95 Quences of the half-cycle transformer saturation are: caused by GlC's during system blackout affected ad but a few substations isola The transformer becomes a rich source of even and colgwreting stations.

odd harmonics A great increase in inductive vars drawn by the trans. Power wee graduelty restored over a nine hours period. De-e former lays in restoring power were encountered because of dam-i Possible drastic stray leakage flux effects its the trans. aged equipment on the La Grande netw former with resulting excessive localized hosting.

There are a number of effects due to the generation of high SYSTEM CONDITION PRIOR TO levels of harmonics by system power transformers, includ-ings Total system generation prior to the events was 21500 MW, Overloading of capacitor bends most of it coming from remote power-generating stations at Possible misoperation of relays u Grande. C m and Churchm Ms. Exports to -

Sustained overvoltages on long-line energization neighbonne Systems totalled 1949 MW of which 1352 MW were on DC interconnections. The 736-kV transmissi Higher secondary are currents during single-pole work was loded at M of its stabWty HmA switching.

Higher circuit breaker recovery voltage Overioeding of harmonic filipre of HVDC converter ter.SEQUENCE OF EVENTS minals, and distortion in the ac voltage wave shape At 2:48 a.m. on March 13,~s very intense magnetic storm that may result in loss of dc power transmission.

led to the consequential trip or shut down of seven SVC's, The increased inductive vars drawn by system transformers Containing me impact of me event trough opermor inter-during half cycle soturation are sufficiert to cause intoior-vention wee impossible ed SVC's hovmg tripped et consed to MVAR flow on transmission lines, and problems with gener.able system v s.) after the lose of the last SVC, all five ator vor limits in some instances.

- 735-kV lines of the La Grande transmission network tripped '

. In addition to the half-cycle saturation of power trans-due to an out of step condition. These line tnps deprived the formers, high levels of GlC can pro 6sr.e a distortea response system of 9500 MW of generation and subsequently led to a IEEE Power Engineering Review, October 1949 complete system collapse.

17.

~

, _. - _ _. _ ~.. _,

'^m W 3I ADL C.WE. MAT R TRImNCS Three SVC's w:re tnoo:c by capacrtor current overtoad pro-

{ffectS Of Geomagnetic taction wnle remaining four SVC s shut down by capacitor DiSttirbanceS On Power Transformers voltage unbalance protect:on. Analysis of vcitage and cut-rent escillograms taken at the Chibougamau site before the SVC rnos showed the following harmonic contents.

Robert J. Ringlee James R. Stewart AC AC Current at 16 kV Harrnonic Vcirage Power Technologies Inc.

Order at 735 kV TCR Branche TSC Branche This discussion addresses the effects of geomagnetic distur.

bances on power transformers. The primary effect is due to 1

100 *,

100 ",

100".

2 9%

38 %

core saturation resulting from geomagnetically induced cut-3 2 ",

12 ".

Ma rents. GlCs. Core saturation can impose severe temperature g

3,,

problems in windings, leads, tank plate and structural mem-bers of transformers and place heavy var and harmonic but-6 l ',

1 *.

16 %

dens on the power system and voltage support equipment.

7 0 *.

3 ".

4%

GlC's of 10 to 100 amperes are more than more nuisances QuasnDC currents generated by the magnetic disturbance, in the operation of power transformers, the manner of flow saturating in the SVC coupling transformers are thought to can result in saturation of the core and consequent changes be the cause for such a large second harmonic component of in system var requirements, increases in harmonic current current in the TSC branch.

magnitudes, increased transformer stray and eddy losses.

and problems with system voltage control.

GENERAL OBSERVATIONS ON THE SYSTEM BEHAVIOR CIC EFFECTS VERSUS CORE AND WINDINC CONFICURATIONS The system blackout was caused by loss of all SVC on La Grande Network. Seven SVC tnpped or stopped functionmg. Principal concems in this discussion are for E Prior to and during the event all the DC interconnections be-with grounded Y transformer banks providing conducting i

haved properfy. No relay falso trips or misoperation of special paths for GIC and zero sequence currents. Core and w protection systems were observed. Telecommunications configurations respond differently to zero sequence open.cir.

were not affected. No equipment damage was directly attrib-cuit currents and to GlCa. Note: as used here, the ter utable to GlC but once the system split. some equipment was circuit" refers to tests performed with all detta conne damaged due to load rejection overvoltages.

opened or broken. For example, the three-phase three leg core form transform,ers are less prone to GlC induced satu-ration than three phase shell form transformers. But, both REMEDIAL ACTIONS TAKEN core form and shell form single phase transformers are sus.

ceptible to GIC induced saturation.

Since the event, the following actions were implemented:

Winding and lead arrangements respond differently to GlC SVC protection circuits have been readjusted on four induced core saturation as weH. For example. the current dis.

SVC's so as to render their operation reliable during tribution within parauel wind:ng paths and w magnetic storms similar work is being performed on leads depends upon the leakage flux paths and mutual cou-the four remaming SVC's.

es w n ngs an a a may change sgh Energy, Mines and Resource Canada now provides Hy-cantly under GlC-induced saturation owing to the change in dro-Quebec with updated forecasts on the probabiHty magnetic field intensity, H, and the resultant changes m the of magnetic disturbances. These forecasts are used by boundary conditions for the leakage field path, the System Control Center dispatcher to position the transmission system within secure limits.

Y ES IN STEEL MBERS A.C. voltage asymmetry is monitored at four key lo-The changes in the magnetic intensity, H, and the magnetic cations on the system (Boucherville, Arnaud, LG2, boundary conditions resulting from the GIC excitation bias Chatgeaguay). Upon detection of a 3% voltage asym.

can increase the losses m steel plate, the losses for fields metry at any one location, the system control center paraffel to the plane of the plate increase nearly as the square dispatcher is alarmed and willimmediately take action of H. Note also that the level of losses incrasse approxi-j to position system transfer levels within secure limits mately as the square root of the frequency of H, owing to the if this hasn't already been done because of forecasted effect of depth of penetratson. The magnetic field along yoke magnetic activity.

clamps and leg plates in core form transformers and in Tee beams and tank plate in shou form transformers closely OPERATING LIMITS DURING matches the magnetic gradient in the core. Areas of the tank MACNETIC DISTURBANCES and core clamps are subjected to the winding leakage field.

(AND ALERT SITUATIONS)

(f the core naturates, the magnetic field impressed upon the j

steel members may rise ten to one hundred times normal due The following operating IImits are now being applied:

to the saturation and the effects of the leakage field. The fosses in the steel members wul rise hundreds of time 10% safety margin shall be applied on maximum trans-forlimrts mal. non under haN-wck satwah On W steel swfaces Maximurn transfer limits shall not take into account the oddy loss density may rise ten to thirty watts per square inch.

i appr sching the thermal flux denarty of an electric range ele-availability of static compensators deemed unreliable, ment.

Adjust the loading on HVOC circuits to be within the j

40% to 90%, or less, of the normal futiload rating.

Surface temperatures rise rapidly with this thermal flux and can resutt in degradstion of insulation tovenmg the steel 18 t

IEEE Power Engineering Review. October 1989 i

t I

I h

L

=

t ATTACitMmT 3 l

DeUtient v M r Design Deficiency manust UPS has Wendor no bat.ery manual f

test maintenance circuit sectaon does not mention batteries.

Batteries have not COF

.ed in MP Design Deficiency

,s f

g.$

y ~ niay g cg g,

' I treaker L

char ac t er ist-batteries srput to

. deg

' l ses prevents fastction

. AC g

transfer to per desigra enverter

[

Iogac power tput.

54 ply is

'me a@nt enance preferred l

1 Gremd Voltase AC pouer to logic power logic trips greakers leads fault occurs en transient logic modate stoply on power pygS-UP51A 8, 08-f,CE.4 do not auto toss of ett 25 i

S phase of main on stat 6en for UP$1A-0,G cutput supply-

~

C.D,G trip open; transfer to toads on d

tr ansf ormer AC power empersences voltage fassure.

2 I

sisyt y the transtent goes tou

. does re,t

- maint.

UPS14 0*G

.ggag gy.

i x

1 6

Fault Permissives e ibit C3-4 is cleared g1 i.

in 6 cycles; eater from I

transfer ctosing I

'coupleted in 12 cyctes f,

b' CS-4 needed to transf maint.sig,er gy to enverter i

output jc m m.m

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ELECTRICAL DISTRIBUTION SYSTEM EVALUATION REPORT OF EVENT ON 8/13/91 - NMP2 PREPARED BY:

RWk c> lrfm ELECTRICAL DESIGN GROUP - UNIT 2 l

REVIEWED / CONCURRED BY:

V-l4"

'l/rl?)

A.K. JULKAf SUPERVISOR' /-

ELECTRICAL DESIGN - UNIT 2 mm1

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TABLE OF CONTENTS EVENT DESCRIPTION BACKGROUND l

INFORMATION AVAILABLE l

EVENT EVALUATION System Conditions / Disturbance-Oscillograph Relay Room Indications l

Switchgear 2NPS-SWG001 and 003 Evaluation Main Generator Evaluation Plant Communication Fire Protection Systems Plant Essential Lighting System Group 9 Isolation Valves Closure Reactor Manual Control System Feedwater Control System Feedwater Pump Trip Annunciators and Computers CONCLUSION RECOMMENDATIONS ATTACHMENTS NSK2 1

t

i

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NMP2 ELECTRICAL DISTRIBUTION SYSTEM Event Description On August 13, 1991 at about 6:00 a.m.,

the NMP2 plant was running at full power and connected to the Scriba Substation 345 KV bus through line #23.

The onsite normal power distribution system 13.8 KV buses, 2NPS-SWG001 and 003, were receiving power from the NSS transformer 2STX-XNS1.

The onsite emergency distribution system 4.16 KV buses 2 ENS *SWG101, 102, 103 were receiving power l

from RSS transformers 2RTX-XSRIA and IB which were connected to Scriba substation through 345/115 KV transformers.

When the plant was running at full power at about 6:00 a.m., the main step up transformer 2MTX-XM1B developed _ a fault and the appropriate protective relays sensed the abnormal conditions and activated their respective lockout relays.

The lockout relays in turn initiated a main turbine trip and transferred normal power distribution loads from the NSS transformer to the RSS transformers through fast transfer relaying.

During the fast transfer of power supplies to the normal distribution system, five (5) plant UPS's 2VBB-UPS1A, 1B, 1C, ID and 1G tripped and caused a power loss to plant computer systems, annunciation systems in main control room, communication systems, essential lighting and fire protection panels annunciation in the main control room.

Background

The NMP2 unit generator 2GMS-G1 is connected to the main generator step up transformers 2MTX-XM1A, 1B, and 1C which step up the generator voltage of 25 KV to 345 KV for interconnection to the NMPC grid at Scriba Substation via a 345 KV transmission line.

The generator step up transformer consists of four shell i

type oil immersed, single phase units.

Three of these four transformers are connected to form a 3 phase 24.3 KV delta on the low voltage side and 3 phase 345 KV grounded Wye on the high voltage side.

The fourth transformer is a spare unit.

The plant normal station service (NSS) transformer 2STX-XNS1 is i

also connected to the unit generator which steps down 25 KV j

output of the generator to 13.8 KV for the plant normal power

)

distribution system.

The NSS transformer'is a 3 winding (split-secondary) transformer and feeds two 13.8 KV buses, 2NPS-SWG001 and 2NPS-SWG003, to supply power to plant nonsafety related-loads.

NSK2 2

O The two reserve station service (RSS) transformers 2RTX-XSR1A and 1B provide offsite power to the onsite power system.

These RSS transformers step down the 115 KV offsite power to 13.8 KV and 4.16 KV for the plant normal and emergency power distribution systems respectively.

Under normal operating conditions, the plant onsite normal power distribution system is energized from the unit generator via the NSS transformer.

In the case of a loss of the unit generator, the offsite power sources provide alternative power for the normal onsite power system through the RSS transformers.

The onsite normal power distribution system 13.8 KV buses 2NPS-SWG001 l

and 2NPS-SWG003 are normally energized from the NSS transformer 2STX-XNS1, In case of a loss of power from the normal source, these buses are automatically transferred to the offaite power sources via RSS transformers 2RTX-XSR1A and 2RTX-XSR1B respectively.

This transfer can be accomplished in two modes; fast or slow.

A single line representation of the above arrangement is shown in Attachment 1.

l The UPS system is divided into the emergency or safety related UPS system and the normal or non-safety related UPS system.

The plant normal uninterruptible power supply (UPS) system provides power to the plant non-safety instrumentation and control loads, annunciators, computers, communication systems, fire protection

panels, RPS system and essential lighting.

The plant emergency UPS system provides power to plant safety related instrumentation l

and control systems. A single line representation of the plant UPS system is shown in Attachment 2.

The 75KVA normal UPS's affected during the event on 8/13/91 provide power to the plant normal instrumentation, controls, essential lighting, annunciators, computer loads, communication and Fire protection panels.

Protective Relayinc Description The main generator, main step up transformer and NSS transformer are protected by the following four protection schemes;

1) unit protection alternate 1,

2) unit protection alternate 2,

3) generator backup protection,

4) unit protection-backup.

NSK2 3

s This is illustrated in Attachment #3 in a single line diagram.

Protection schemes 1 and 2 above consist of high speed protective relays and the 3 &4 schemes use slow speed relays.

Unit protection schemes 1 & 2 initiate a fast transfer of the switchgear buses 2NPS-SWG001 and 2NPS-SWG003 to the RSS source which occurs within 6 cycles after loss of normal power.

If automatic fast transfer is not accomplished within 6 cycles, then the fast transfer is blocked and a slow transfer is initiated after a time delay to allow for decay of residual voltage on the deenergized buses and to shed selected motors from the power source to prevent excessive surges upon restart of the equipment.

This fast / slow transfer scheme is described in detail in USAR Section 8.3.1.1.2, Page 8.3-4.

Information Available The following data for the event was collected and is provided in Attachments 4 and 5.

1.

Scriba station oscillograph chart for 115 KV buses and 345 KV bus.

2.

NMP2 normal and emergency distribution system protective relaying status from control room records.

No other data is available because the NMP2 computer and annunciation systems were inoperable due to the loss of the normal UPS's.

In addition, the control room oscillograph was found to be out of service at that time.

Event Evaluation The evaluation of various items during this event is provided as follows:

a)

System Conditions / Disturbances-Oscilloaraoh The record of event and system conditions are recorded in the oscillograph chart obtained from Scriba substation which is provided in Attachment 4.

This chart shows that NMP2 was operating at full power prior to the event on 8/13/91.

At the initiation of the event, the chart indicates a decrease in voltage on Phase

'B' of the 345 KV bus for approximately l

6 cycles after which the voltage returned to normal without any further visible transient behavior.

During the same period, the current in one of the phases of the 345 KV line connecting NMP2 and the Scriba Substation sharply increased to 3-4 times its prior value indicating a fault.

After 6 cycles, the fault was cleared and line 23 (345 KV line to Scriba from the plant) was isolated.

This confirms that the fault lasted only for about 6 cycles.

NSK2 4

l l-

e The oscillograph chart for the Scriba Station 115 KV Bus reveals that during the fault duration of 6 cycles, the 115 KV bus voltage dropped.

After the 345 KV line #23 was isolated, the 115 KV bus voltage returned to normal.

The oscillograph chart for the 115 KV bus confirms that the fast transfer of the NSS transformer loads to the RSS transformer 1

occurred after about 6 cycles from clearance of the fault and is in accordance with USAR Section 8.3.1.1.2.

The oscillograph charts for the 115 KV and 345 KV buses do not show any disturbances before occurrence of the fault and after clearance of the fault.

b)

Relav Room Indications The relays that actuated during the event are shown on the abbreviated single line in Attachment 3.

A review of the relay data indicates that the main transformer differential relay actuated.to isolate the fault in the transformer.

Initiation of this relay actuates lockout relays of the unit protection schemes, initiates a turbine trip and fast transfer of the NSS transformer loads to RSS transformers.

In addition to the main transformer differential relay, the unit differential relay also actuated, which initiated a turbine trip and fast transfer.

Generator protection and unit protection backup relays also actuated.

The fast transfer occurred before these backup protection schemes could block the fast transfer.

During the transfer of the normal power distribution system from the normal source to its alternate source, the flags on the degraded voltage relays of the Class 1

1E power distribution system came in, but there was no indication of offsite power breaker tripping and diesel generator starting.

The degraded voltage condition appears to have occurred only during the duration of the fault as evidenced by the Scriba substation oscillograph chart for the 115 KV buses.

Since the l

degraded voltage trips are time delayed without loss of coolant accident (LOCA), the diesel generators signal i

was not initiated and the offsite breakers did not trip.

The degraded voltage scheme, therefore, functioned as designed and agreed with USAR commitment.

l This degraded voltage scheme is discussed in USAR Section 8.2.2, Page 8.2-24C.

NSK2

e c)

Switchaear 2NPS-SWG001 and 003 Evaluation The 13.8 KV switchgear 2NPS-SWG001 and 003 receive their normal power from the NSS transformer.

In the case of a loss of power from its normal source, the power supply to these switchgear buses is automatically transferred to the RSS transformers.

The relay actuation and Scriba oscillograph chart indicate that the fast transfer occurred the way it was designed and as described in USAR Section 8.3.1.1.2, Page 8.3-4 for both the switchgear buses.

Further investigation of the event by NMPC operation revealed that the circuit breakers feeding 13.8 KV reactor feedwater pumps and condensate booster pump j

fed from switchgear 2NPS-SWG001 were tripped.

A detailed review of automatic transfer scheme was performed to determine if these large motors were tripped due to this transfer scheme.

The automatic transfer scheme is designed such.that the large motors trip before slow transfer to avoid residual voltage.

l The review of the Scriba Substation 115 KV oscillograph chart clearly confirms that fast transfer scheme worked and loads were picked up by the 115 KV reserve power sources.

A further review of the feedwater system revealed that the loss of power supply from the normal UPS's caused the opening of minimum flow valves which-in turn triggered tripping of the feedwater pumps and condensate booster pump. See Section

'L' for further l

analysis of this occurrence.

1 d)

Main Generator and Other Related Eculement Evaluation

'(

The fault on the main step up transformer was detected by protective relaying which tripped the main turbine / generator which in turn initiated an automatic scram of the reactor.

The fault on the main transformer was on the 345 KV winding which is wye I

connected.

The fault on the secondary side was j

transferred to the low voltage side windings.

The low i

voltage side winding was damaged.

The main l

generator / turbine was tripped by unit protection alternate 1 and 2 lockout relays within about 6 cycles i

from the event as is evidenced by the 345 KV line oscillograph chart.

The generator may have been coasting for some time with residual excitation and

. supplying fault current to the 25 KV system after the trip.

This current is small compared to the initial l

fault current on the secondary side due to main l

transformer impedance.

This small fault current may L-NSK2 6

I e

not have any significant effect on the main generator thermal capability but it is recommended to megger main generator and check surge arrestors prior to startup.

In addition, as recommended in Attachment 10 by General Electric, the generator manufacturer, a thorough inspection of the generator and its component should be performed.

It is recommended that this inspection be performed during the next refueling outage.

It is also recommended that the unfaulted transformer units be meggered and dobled in accordance with manufacturer's recommendation.

The generator and i

l associated equipment have been tested and details are included in the transformer report.

e)

Plant Communication Systems NMP2 plant communication systems consist of the following:

1)

Dial Telephone System A dial telephone system provides communication between selected office areas and selected locations inside and outside the station.

The dial telephone system is connected to the NMPC telephone tie system for offsite communication.

The telephone system main equipment receives its power from the plant normal UPS system.

2)

Radio Communication Systems A hand held portable radio communication system _is provided for communication between station personnel within the plant.

This system utilizes a leaky wire antenna system which are fed from the plant normal UPS system.

3)

Pace Partv/Public Address System A PP/PA system with five party channels and one page channel is provided for communication for various station buildings and locations.

The system is powered from the plant normal UPS system.

4)

Maintenance and Calibration Communication System An M/CC is provided for voice communication in areas requiring communication for testing, NSK2 7

naintenance, etc.

It is powered from the plant normal 120V AC power system.

5)

Sound Powered Communication System An SPC is provided for voice communication in case of total loss of electric power to PP/PA and M/CC systems.

This system requires no plant electrical power.

Event Evaluation Three of the five communication systems require plant UPS systems to function.

Due to loss of normal UPS systems during the event, the three communication systems, dial telephone system, radio communication system, and page party /public address system, were lost.

The only communication systems available were the maintenance and calibration communication-system and the sound powered communication system which is mostly used for testing and maintenance activities.

Even though the PP/PA system is grouped in two separate independent paging systems with three UPS systems to provide redundant paths of communication throughout the plant, the communication systems were lost due to the multiple failures of the normal UPS system.

The existing communication system design with redundant paths of communication throughout the plant using three normal UPS's is adequate; the root cause of the multiple failure of the normal UPS's will be determined / evaluated and appropriate corrective action taken if required to ensure that multiple normal UPS failure will not reoccur.

The plant communication system is described in USAR Section 9.5.2.

f)

Fire Protection System NMP2 Fire Protection and Detection systems are fed through the two stub buses 2NNS-SWG016 and 015 through an automatic transfer switch.

The primary source which feeds the two stub buses is the unit generator 2GMS-G1 through the normal station service transformer 2STX-XNS1.

In the event of unit trip, these stub buses are transferred to the offsite power sources through a fast or slow transfer of 13.8 KV buses 2NPS-SWG001 and 003 respectively.

In the case of loss of offsite power, these stub buses are connectable to emergency diesel generators if there is no LOCA.

l l

NSK2 8

l

i-l 0

l NMP2 has two fire pumps, one diesel driven and one motor driven.

The motor driven fire pump is powered l

from 4.16 KV non-safety related bus 2NPS-SWG012.

Further information on this system is provided in USAR Appendix 9A.

l The Unit 2 fire detection system is fed through the two stub bases through an automatic transfer switch.

The primary source which feeds the two stub buses is the unit generator, and the secondary sources include i

either of the two offsite power sources, or the diesel generators.

In case of the loss of the primary source, the transfer switch automatically connects the system to the secondary source.

This arrangement satisfies the intent of the requirements of NFPA 72D, Section 2220.

This fire detection system is described in USAR Section 9A.3.6.1.6, Page 9A.3-49.

A listing of fire panels installed in NMP2 is provided on the following.pages.

Each panel powered from AC is provided with a primary and backup power source.

In the event of momentary loss of both primary and backup, l

the system is provided with an internal battery power l

supply except for 2 CEC-PNL849, 2FPM-PNL200 and 201.

l These are powered from normal UPS 2VBB-UPS1G.

2 CEC-PNL849 provides main control room alarm for fire in any area in the plant; 2FPM-PNL200 and 201 are fire protection computer panels.

This level of detail is not provided in the USAR.

Status of Fire Panels The status of fire panels during the event is shown in i.

As indicated in Attachment 6, 2FPM-PNL 200 and 201 were lost when the UPS was lost.

In j

addition, 2 CEC-PNL849, which is fed from the normal UPS System, was also lost causing the loss of annunciation in the main control room for fire protection systems.

The status of fire panels reported above, is in l

accordance with the existing fire panel design.

Event Evaluation As reported in Attachment 6, of the 20 fire panels at Unit 2 only two (2) transferred to internal battery l

back-up_during this event.

This transfer is in l

accordance with the local fire panel design.

While on battery power, because the normal AC was still available, functions of these two panels were still available.

NSK2 9

i As indicated in Attachment 6, some panels provided local trouble alarms and it is due to the fact that their supervisory control circuits detected a momentary dip in the normal AC power supply as they are designed to do so.

This level of detail is not provided in the USAR.

During this event plant-communication was not available.

However, as stated in Attachment 6,_ fire i

l brigade started its roving patrol soon after the i

failure of the transformer and they have used had held portable radios with Channel 10, which is their normal practice during the loss of communication-systems.

During this event, control room did not have the capability to monitor various fire panel annunciations.

However, fire suppression / indication could have been initiated locally.

In addition fire suppression capabilities existed from.the~ control room, because the control circuits in control room are powered from local i

panels.

In addition, it'is concluded that this event did not involve any 10CFR 50 Appendix "R" concerns because the e

event is not associated with any exposure fire.

j Fire Protection and Detection Panels and Their Power Supplies The NMP2 plant fire protection panels and their power supplies are as follows:

Component ID Power Source 2FPF-PNL136 2SCA-PNL500 2 SCI-PNLA102 2FPL-PNL176 2BYS-PNLA101 (DC Power) 2BYS-PNLB101 (DC Power) 2FPL-PNL176-1 2BYS-PNLA101 ~ (DC Power) 2FPL-PNL176-2~

' 2BYS-PNLA101 ~ (DC - Power) 2FPL-PNL177 2BYS-PNLA101 (DC Power) 2BYS-PNLB101 (DC Power) 2FPL-PNL177-l' 2BYS-PNLA101 (DC Power) 2 FPL-PNL177-2 2BYS-PNLA101 (DC Power).

2FPL-PNL230 2BYS-PNLA101 (DC Power)

NSK2 10 I

i l

l.

Component ID Power Source i

2FPL-PNL231 2BYS-PNLA101 (DC Power) 2FPL-PNL273 2BYS-PNLA101 (DC Power) l 2FPM-PNL101 2SCA-PNL500 2SCA-PNL600 2FPM-PNL103 2SCA-PNL600 l

2SCA-PNL500 l

l 2FPM-PNL104 2SCA-PNL600 l

2SCA-PNL500 2FPM-PNL105 2SCA-PNL600 2SCA-PNL500 2FPM-PNL106 2SCA-PNL600 2SCA-PNL500 i

l 2FPM-PNL107 2SCA-PNL600 l

2SCA-PNL500 l

2FPM-PNL108 2SCA-PNL600 2SCA-PNL500 l

2FPM-PNL113 2SCA-PNL500 2SCA-PNL600 2FPM-PNL114 2SCA-PNL500 2SCA-PNL600 2FPM-PNL117 2SCA-PNL500 2SCA-PNL600 2FPM-PNL119 2SCA-PNL600 2SCA-PNL500 2FPM-PNL120 2SCA-PNL600 2SCA-PNL500 2FPM-PNL121 2SCA-PNL500 2SCA-PNL600 2FPM-PNL123 2SCA-PNL500 t'

2SCA-PNL600 NSK2 11

4 Component ID Power Sonrce 2FPM-PNL125 2SCA-PNL500 2SCA-PNL600 2FPM-PNL126 2SCA-PNL500 2SCA-PNL600 2FPM-PNL127 2SCA-PNL500 2SCA-PNL600 2FPM-PNL128 2SCA-PNL500 2SCA-PNL600 l

2FPM-PNL129 2SCA-PNL600 2SCA-PNL500 2FPM-PNL131 2SCA-PNL500

- 2SCA-PNL600 2FPM-PNL132 2SCA-PNL600 2SCA-PNL500 2FPM-PNL200 2VBB-UPS1G 2FPM-PNL201 2VBB-UPS1G 2FPM-PNL233 2SCA-PNL102 2SCA-PNL600 2FPM-PNL234 2SCA-PNL102 2SCA-PNL104 g)

Plant Lichtina Systems NMP2 station lighting consists of the following:

j 1

1)

Normal Lighting System 2)

Emergency Lighting System 1

3)

Essential Lighting System

\\~

1

-4)

Egress Lighting System j

5) 8-Hour Battery-Pack Lighting System NSK2 12 i

...-L---

..,.n g-n

,n.,

~

The normal lighting system provides adequate illumination in all areas of the station under normal operating conditions.

The emergency lighting system provides adequate illumination in areas required for operating the safety-related equipment during emergency 4

conditions.

The essential lighting system provides partial illumination for certain critical areas of the station requiring continuous lighting such as the control room and for passageways to and from areas where safety-related equipment is located.

The egress lighting system provides adequate illumination for all egress signs and egress routes inside the plant.

The 8-hour battery pack lighting provides illumination in all areas required for operation of safe shutdown equipment and in access and egress routes thereto in case of exposure fire.

The above discussion of the plant lighting systems are consistent with USAR Section 9.5.3.

The normal lighting system is powered from the plant normal power distribution system except reactor building normal lighting, the emergency lighting system is powered from the plant emergency power distribution system, the 8 hour9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> battery pack lighting system is powered by their own battery.

The Reactor Building normal lighting receives power from offsite source in a way similar to the emergency lighting system.

The normal reactor building lighting is tripped from the Class 1E bus by an accident signal and is blocked from closing as long as the accident signal is present.

The Reactor Building normal lighting is also tripped upon sustained undervoltage on the load center from where it receives power.

The essential lighting system receives power from station normal UPS system 2VBB-UPS 1B, 1C and 1D.

A single line representation of the power supplies involved with the UPS is provided in Attachment 2 and the critical areas of the plant provided with essential lighting is shown in Attachment 7.

The plant egress lighting also receives power from the plant normal UPS panels 2VBB-UPS 1B, 1C and 1D.

This is in accordance with USAR Section 9.5.3, Page 9.5-20.

Status of Essential and Earess Lichtina During the event on August 13, 1991, power supplies from normal UPS panels 2VBB-UPS 1B, 1C and 1D were not available.

All areas of the plant that are provided with essential and egress lighting, loss of partial illumination NSK2 13

l resulted until such time the power to these UPS's was restored.

However, one or more of the other lighting systems namely, emergency, normal and 8 hour9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> battery pack were available in these areas during this event.

The stairwells are provided with essential lighting only except where 8 hour9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> battery pack lighting is added for Appendix R compliance.

Illumination to these stairwells was not available due to loss of normal UPS.

The 8 hour9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> battery pack lighting did not energize because there was no loss of normal power.

Event Evaluation The root cause of loss of power from normal UPS is evaluated separately in another report.

During the event, some areas of the plant lost partial illuminations provided by essential lighting for sometime.

Areas critical for safe shutdown where this lighting are identified are provided in Attachment 7.

During this event the plant was safely shutdown from the control room.

Because the control room is provided with adequate lighting without the essential lighting, loss of essential lighting did not adversely affect the operator actions needed to bring the plant to safe shutdown.

The access route used by the operators during this event for restoration of the normal UPS power (Attachment 8) supplies was illuminated from normal lighting except for the stairwell where portable handheld lights were used.

(FSAR Sec. 9.5.3.3 allows the use of portable lighting in the form of handheld flashlights for short excursions into the plant).

The normal UPS locations were illuminated by normal lighting.

Therefore, restoration of UPS power was unaffected by loss of essential lighting.

Even though the essential and egress lighting are powered by three normal UPS's, during this event due to multiple failures of all normal UPS's, essential and egress lighting systems were not available.

The existing essential and egress lighting design is adequate, however, the root cause of the multiple failures of the normal UPS's will be determined / evaluated and appropriate corrective action taken if required to ensure that multiple normal UPS's failure will not reoccur.

The proposed plant modification 89-042 will enhance the reliability of stairwell lighting where 8 hour9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> battery pack lighting is provided.

NSK2 14

1 I

Status of Normal Reactor Buildina Lichtina During the event on August 13, 1991, it was reported by the operators in the reactor building that some areas of the reactor building lost lighting momentarily.

Event Evaluation Normal lighting for reactor building general areas, work areas and electrical equipment areas is provided with low wattage high pressure sodium vapor lights.

In the event of power interruptions or voltage dip lasting for more than one cycle, these fixtures extinguish and do not restart until the lamp cools and pressure decreases.

When a power supply to continuously energized sodium vapor light is interrupted, it has a cooldown period before a restrike of the lighting-can occur.

The cooldown period depends upon the rating of the light bulbs.

During the event, the emergency distribution system experienced a transient due to the fault on the Phase B main transformer.

During the event, the Reactor Building normal lighting in certain areas where these high pressure sodium vapor fixtures are provided, was interrupted for approximately 30 seconds.

This momentary loss of lighting was due to the inherent design of low wattage high pressure sodium vapor lighting which requires cooldown period prior to restrike whenever power is interrupted.

The same scenario could occur in the plant wherever power supply to high pressure sodium vapor fixture is interrupted momentarily, however, there is no indication of such a loss in other areas of the plant.

Therefore, it is consistent with NMP2 lighting design and USAR Section 9.5.3.

I h)

Groun 9 Isolation Valves Closure The group 9 primary containment isolation valves are part of containment purge system.

These valves are listed in Technical Specification Table 3.6.3-1, Page 3/4 6-24 and USAR Table 6.2.56, Page 11 of 24.

The function of group 9 isolation valves is to limit the i

potential release of radioactive materials from primary containment.

These isolation valves are opened during power operation only at infrequent intervals to allow injection of nitrogen into primary containment to inert or de-inert the primary containment at a desired pressure.. These valves, if open, receive signal to close if any of the following happen:

NSK2 15 l

I t

a)

High radiation through standby gas treatment system (SGTS).

The SGTS radiation monitor located in the main stack is designed to continuously monitor offsite release and provide isolation signals to these isolation valves.

l b)

High drywell pressure.

c)

Reactor low water level.

d)

Manual isolation of main steam isolation valves.

Event Evaluation During this event, the group 9 primary containment isolation valves closed.

This isolation is the safe mode of operation limiting potential releases of radioactive material from primary containment.

The initiating condition for these valves occurred as a result of loss of power to radiation monitor 2GTS-RE105 when UPS power to the DRMS computer was interrupted.

The actual isolation occurred when the logic was reenergized upon restoration of the UPS power supply to the monitor's auxiliary relay circuit.

Therefore, group 9 isolation valves closed as designed and is consistent with USAR Section 6.2.5.2.4, Page 6.2-77.

j)

Reactor Manual Control System The reactor manual control system (RMCS) provides the operator with means to make changes in nuclear reactivity via the manipulation of control rods so that reactor power level and core power distribution can be controlled.

This system is a power generation system and is not classified as safety related.

The RMCS receives electrical power from the 120 V'AC normal UPS.

The RMCS does not include any of the circuitry or devices used to automatically or manually scram the reactor.

The RMCS control and position indication circuitry is not required for any plant safety function nor is it required to operate during any associated DBA or transient occurrence.

The reactor manual control circuitry is required to operate only in the normal plant environment during normal power generation operations.

The discussion of RMCS is consistent with USAR Sections 7.7.1.1, Pages 7.7-1, 2,

14.

J NSK2 16

l l

Event Analysis The RMCS was lost during this event because its power source, the normal nonsafety related UPS, was lost.

The loss of RMCS is not a concern during this event.

Since the plant was automatically scrammed during this event, the RMCS need not perform any function after the scram.

This RMCS is used by operator only during normal plant operations.

Therefore, if the plant had not automatically scrammed during the event, loss of RMCS would not have caused a safety concern based upon

)

the following:

1)

EOP's provide guidance to the operator under situations involving failure to scram, and 2) various ATWS mitigating design aspects of the plant were fully operable throughout the event.

Although this system was lost during this event, its importance diminished once the automatic scram occurred.

Therefore it is concluded that the RMCS function was consistent with USAR Section 7.7.1.1.

k)

Feedwater Control System The feedwater control system controls the flow of feedwater into the reactor vessel to maintain the vessel water level within predetermined limits during all normal plant operating modes.

During normal plant operation, the feedwater control system automatically regulates feedwater flow into the reactor vessel.

The system can be manually operated.

The feedwater flow control instrumentation measures the water level in the i

reactor vessel, the feedwater flow rate into the reactor vessel and the steam flow rate from the reactor vessel.

During automatic operation, these three measurements are used for controlling feedwater flow.

The feedwater control system receives its normal power supply from the normal UPS.

The feedwater control system is designed to lock in its last position upon a loss of power to its control electronics.

The feedwater control system is discussed in USAR Section 7.7.1.3, Page 7.7-23.

Event Analysis During this event, upon loss of the normal UPS's, the feedwater control system performed as designed and failed in its last position.

Therefore, it is concluded that the feedwater control system function was consistent with USAR Section 7.7.1.3.

NSK2 17

i i*

1)

Feedwater Pumo Trin:

Feedwater is provided to the Reactor Pressure Vessel (RPV) via the Condensate Pumps, Condensate Booster Pumps and the Reactor Feed Pumps shown in Attachment 9.

The Condensate Pump draws condensate water from the Condenser and provides the necessary Net Positive Suction Head (NPSH) for the Booster Pumps.

The Condensate Booster Pumps provide the necessary NPSH for the Reactor Feed Pumps.

A minimum flow control header is provided off the discharge header of each pump to ensure that the minimum flow is maintained through the associated pump.

The minimum flow control valves and associated instrumentation actuates to maintain this minimum flow.

The main feedwater control valves (LV10), located on the discharge header of the Reactor Feed Pumps, modulate to control reactor water level.

The feedwater control system is powered by normal UPS power supplies.

The above discussion is consistent with USAR Section 10.4.7.

Event Evaluation It was reported during this event that feedwater pumps l

tripped.

An evaluation of this condition reveals that reported happenings are consistent with the system as l

designed and is in consistence with USAR Section 10.4.7.

The instrumentation controlling the minimum flow recirculation valves on the condensate, condensate l

booster and the feedwater pumps is powered from the normal UPS's.

These instruments are also designed to open the valve upon loss of power in order to protect the pumps.

Upon loss of normal UPS, the feedwater control valves fail locked in their last position.

Following the turbine trip, an ATWS signal would attempt to drive the feedwater control valves closed, however since an ATWS signal was not present, this did not occur.

With the feedwater control valves failed locked and the minimum flow control valves (FV2) driven full open, feedwater flow increases and approaches pump run-out.

The Reactor Feed Pump NPSH decreases to the low-low pressure trip point, tripping the Feedwater Pumps.

The Feedwater pump control circuit does not utilize an auto transfer logic to standby Feedwater Pump; therefore, feedwater flow is lost.

The instrumentation circuits for all other minimum flow control valves are also powered by normal UPS power supplies.

These valves all fail in the open position with the loss of UPS and contribute to the loss of Feedwater pump and condensate booster pump.

This is consistent with USAR Section 10.4.7.

NSK2 18 l

l

m)

Annunciators and Computers The plant annunciator system provides information to the plant operators by windows located on the main operator panelboards and on back panels within the Power Generation Control Complex (PGCC).

This system does not include annunciators on local panels throughout the plant and on special panels, e.g.,

fire protection, within the PGCC.

The plant annunciator system is non-safety related and is connected to the normal power distribution system through normal UPS's.

The plant annunciator system is not discussed in the USAR.

Several computer displays, with inter-active keyboards, are located in the PGCC.

These displays are from the

)

following computer systems.

Plant Process Computer PMS Liquid Radwaste Computer, which has the LWS following subsystems:

i LWS

- Liquid Radwaste Control

{

l GENTEMP - Generator Temperature Monitoring ERF

- Emergency Parameter Display System SPDS

- Safety Parameter Display System Digital Radiation Monitoring System DRMS 3D Monicore -

A system used primarily for. core calculations and monitoring In addition, noble gas information is provided to the i

plant operators from the GEMS (Gaseous Effluent Monitoring System) computer by chart recorders on a back panel; and the operators have access to the GETARS (General Electric Transient Analysis & Recording System) computer.

All of the above computer systems are non-safety related and are connected to the normal power i

distribution systems through normal UPS's.

There are l

some safety related radiation monitoring skids that provide input to the DRMS computer.

However, these skids also provide safety related indication in the PGCC that is independent of the DRMS computer.

NSK2 19 l

l

The Plant Process Computer is discussed in Section 7.7.1.6 of the USAR, where it is mentioned that the computer is non-safety related.

l USAR Section 11.2.1.2 covers the Liquid Radwaste System l

design basis and states that the power supply for all Radwaste System components is provided from non-Class

]

l 1E power sources.

This is compatible with the Safety Parameter Display requirements since NUREG-0737, i

Supplement 1 states that the SPDS need not be qualified to Class 1E requirements.

The process and effluent radiological monitoring and l

sampling systems, which include the DRMS and GEMS l

computers, are discussed'in USAR Section 11.5.

This section defines which monitors are safety related and which are non-safety related.

The DRMS and GEMS design complies with this USAR section.

Area radiation and airborne radioactivity monitoring instrumentation, which include the DRMS and GEMS computers, are discussed in USAR Section 12.3.4.1.

This section defines which monitors are safety related and which are non-safety related.

The DRMS and GEMS design complies with this USAR section.

A description of the 3D Monicore computer system was added to USAR Section 7.7.1.6 by LDCN U-1235.

This LDCN states that the 3D Monicore system is non-safety related.

The designation of the computer systems mentioned above l

as non-safety related is consistent-with the explanation of the Uninterruptible Power Supply System in USAR Section 8.3.1.1.2.

In this section it is stated that 2VBB-UPS1A feeds the radwaste computer l

hardware, 2VBB-UPS1B feeds local non-safety related l

radiation monitoring microprocessors, and 2VBB-UPS1G feeds plant computer loads.

Event Evaluation With the loss of the normal UPS's, the plant annunciation system and the computer systems listed above became inoperative due to the loss of power.

This is consistent with the plant design and the description of the plant in the USAR.

These systems are non-safety related and, hence, are not required to shut down the plant following a design basis event.

l NSK2 l

20 l

l l

)

CONCLUSION Based on the above evaluation, it can be concluded that the plant responses during the event on 8/13/91 is consistent with USAR descriptions.

RECOMMENDATIONS Based on the above evaluation, the following long term recommendations are provided.

1l Plant Oscillograph - The in-plant oscillograph should be replaced with a more reliable and functional unit.

If this oscillograph was functional during the event on 8/13/91, adequate data _could have been available to accurately evaluate the cause of the disturbance.

2)

Essential Lighting - The proposed modification 89-042 should be implemented as soon as possible to enhance the reliability of stairwell lighting where 8 hour9.259259e-5 days <br />0.00222 hours <br />1.322751e-5 weeks <br />3.044e-6 months <br /> battery pack lighting is provided.

3)

Ccotrol Power Supplies - During the Electrical Distribution System evaluation, it was revealed that most of the systems important to plant operations such as feedwater system, annunciation system, etc, receive their control power from either normal UPS 1A, 1B or both.

It is recommended that control power supplies for these systems be evaluated and reconfigured to I

avoid plant transient due to loss of single normal UPS.

4)

Main Generator - It is recommended that a thorough visual inspection be performed of the generator stator l

and winding support system during the next refueling I

outage (see Attachment 10).

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pTAcHmeNTS Pace ~2WS LIST OF PROTECTIVE RELAY ACTUATED QN AUGUST.13, 1991 Unit Protection Alt 1 Protective Relav Lockout Relav Action Ref. Dwa.

86-1-2SPUX01

• Initiate Turbine Trip ESK-8SPUO1 87-2SPMX01 Main Transformer 86-2-2SPUXO2

• Initiate Fast Transfer ESK-8SPUO2 Differential to Reserve Station ESK-5NPS13 Protection Relay Transformer ESK-5NPS14 Unit Protection Alt 2 Protective Relay Lockout Relav Action Ref. Dwa.

87-2SPUYO2 86-1-2SPUYO1

• Initiate Turbine Trip ESK-8SPUO1 Unit Differential 86-2-2SPUYO1

• Initiate Fast Transfer ESK-8SPUO3 Protection Relay to Reserve Station ESK-5NPS13 Transformer ESK-5NPS14 63-2SPMY01 86-1-2SPUY01

• Initiate Turbine Trip ESK-8SPUO3 Fault Pressure 86-2-2SPUY01

• Initiate Fast Transfer Sh.-2 Transformer to Reserve Station ESK-8SPUO3 Transformer Sh. 1 ESK-5NPS13 ESK-5NPS14 Unit Protection Backup I

l Protective Relav Lockout Relav Action Ref. Dwa.

l 50/51N 86-1-2SPUZ01

• Initiate Turbine Trip ESK-8SPUO4 i

2SPMZ01 86-2-2SPUZO1

• Initiate Slow Transfer ESK-5NPS13 l

Protection Relay After 30 Sec.

ESK-5NPS14 Block Fast Transfer After 6 Cycles Generator Protection Protective Relav Lockout Relal Action Ref. Dwa.

Gen. Phase OC During 86-1-2SPGZO1

• Initiate Turbine Trip ESK-8SPG01 Startup 86-3-2SPGZ01

• Initiate Slow Transfer ESK-8SPG04 50-2SPGZO2 After 30 Sec.

ESK-5NPS13 Block Fast Transfer ESK-5NPS14

• This Relay Picks Up Only When Unit is Off Line

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ATTJC BiENT 3 PAGE 3 of 3 Degraded Voltage Switchaear Lockout Relav Action-Ref. Dwa.

2 ENS *SWG103 27BA-2ENSB24 No Action Took Place ESK-5 ENS 18 27BB-2ENSB24 Degraded Voltage Stays ESK-8 ENS 02 27BC-2ENSB24

'During Fault Conditions 2 ENS *SWG101 27BA-2ENSA24 No Action Took Place ESK-5 ENS 14 27BB-2ENSA24

. Degraded Voltage Stays.

ESK-BENS 01 27BC-2ENSA24 During Fault Conditions 2 ENS *SWG102 27BA-2ENSC08 No Action Took Place 807E183TY.

27BB-2ENSC08 Degraded Voltage Stays Sh. 7 27BC-2ENSC08 During Fault Conditions I

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I ATTA f.LMal 4 i~ VOLTAGE PROFILE FOR THE NORMAL SUPPLY PEE 4er4 1 TO UPS DURINO FAULTED CONDITION f 4 FAULTED 345Kv CONDITION I t f o a 5 b j /s 180kV iso ww -- 2MTX-XM1A. B. C N 232KV 2.bf 2 , 21.55u [ mm 82.5Kv altKV L 2' 3 ' t o 2 S ~23 KV I a a n2 24.9/ ww A2STX XNSI j j i m v 13.8KV TM 7.5'/. 16kV N 8 AV!. /\\ 3 2 " 21.55KV ! i S !!, o h 3 2 16KV 2NPS-SVG003 } = a 8.9K V E 13.5 3/ WW d2ATX-XS3 g 4.16KV mm 3 i 5.57. g u 8.9KV N 2.59 0 3 2 !!.9KV 2NNS SVG015 l 3.46 - h 2' 8.9Kv 3 4 y 2.5eKv b 4056/ WW d2NJS-X3E 600V m m /1 5.75'/. Ni i l o o 2NJS-US6 2.5BKV $w 3say 3.46KV 12V 3 2 e aa 482v t DROP 2.5skv 3 v 2 " @208 120VmmA 2VBB-XD600 600/ 3 ev /1l: 5.57 \\l l t I REGULATING h5 i 89v I Y I 348v N ll4V 3 2 47ev o 65V 154v DC A 34ev 3 2 o UPS j s5v m o Il4V 2VBB-UPSID l

• FROM SCRIBA SUBSTATION OSCILLOGRAPH RECORD

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- ME 15 '91 158de P91 PCr MGPf7 & Corti DTS A r r h C M n e + lo INTERNR CORRESPONDE.NCa PNJ / oF4 as v ~ gy w,,cn. =e FROM A. R.- bb Nine Mile Point Nuclear station DitfMCf 15 August 91 FILE CODE TO Distr DATE xR Nine Mile Point smEcf Fire Protection Awvg.a Post Event Interviews After interviews conducted today with Fire Chief Bernie Harvey, and Firemen Pat Brennan and Nark Locurcio, and concurrence Terry Verallysa, System Expert Fire Detection and John with Pavlicko of Caution Equipment Inc., I have reached the following, conclusions. 1. of the 20 fire panels at Unit 2, is maintained a normal power supply. l 2a. Two fire panels LFCP113 and 123 transferred to internal battery backup. 2b. These two panels while on battery will still function normally as long as the 120 VAC is available in the LFCP, which it was. There was no-interruption or doorease of fire protection / detection / suppression at the local fire panels. Fire Panels 849 and 200/1 being fed from UPS did have a power interruption. This would have left the control switches operable 4 at Panel 849, (as they are fed from LFCP), but control Room with no fire annunciation. Any fire suppression / indication could also have been initiated locally. ARA:dic Distribution T. Tomlinson A. Julka (FAX 7225 - SM) D. Pringle w-, ,o ,---..n~-

MAG 15 't1 1544 foi tET NGMT & Corm DTS P.3 A"PTACAtMGW-dp l' INTERNAL CSRRESPONDENCE Pgg pq Nu w.m y ~~ ~ j Pnou A. en b Ni"* Mil" 8'i"* I"'1*** 8""ti'" omTRm 15-August 91 MLECODE l To Fil cayg g l ~T Nine Mile Point, Unit 2 susJact i Fire Protection Program 4 Post Event 9/13/91 Interviews \\ j Pire Dept. Personnel Interviews, Post Event of August 12, 1991 5 { Bernie Marvey - Chief - In early for coverage, interviewed for loss l cf power in Centrol Building. Lights blinked, loud noise (louder { than ever heard in plant), was in Fire Dept. office, told shift to j get out into plant. Pat Wilson was in Rx Bldq, switched radios to Channel 10, standard, j Fire Dept. practice if suspect loss of repeator. I Pat Brennan was in the Foam Room and proceeded to the Chief's desk. 1 j Chief Harvey heard fire panel alarming when he got to Control Building. Want past Fire Panel 114 in Turbine Building passageway, i no audible alarms, seemed normal. l Mark Locuroie went to Panel 126 - 214 elev. while chief Narvey went to Panel 127 - 244 elev. ; these were sounding trouble alara and DAX j was clear. Want past Panels 120, 121, 128; they were normal - no audible. I l Prior to Site Area Emergency (SAE) message and evacuation being Pat Brennan reported Panels R.B. normal, called on j announced l Gaitronics - had to silanos Panels 113 on T.B. 250 and then silenced all Panels in R.B., Panels 101, 103, 104, 105, 106, 107 and lot. j chief Harvey was going to trip systems wet in R.B, and. have man in R.S. Guards Lynn Root, accompanied by Larry ochener, called his supervisor, when _they saw transformer blow. j Chief Marvey would have liked to get to transformer quicker for i fire evaluation. He feels it was at least one hour before,/ evaluation. chief Harvey feels Fire Dept. should have been part of initial j investigation / inspection team with operations. j a E i

RJE 15 ota iss 42 rm trr Merr a Com DTS W A C H # G w 1. (,, . FMe s r 4 ji - Aug. 13, 1991 Interview (Cont'd) 1 Pat Pat was in Foam Room approximately 0550, heard loud noise, went to 1 chief's office and asked what noise was. Lighting diassed, one string of lights off (NOTE: these feed from Emergency - UPS should have gone off) 4 J which were on water Then he went on rover - heard alarms treatment system panel, then went to Panel 123. There were no j displays on DAX panel, was blank no lights were on. Power lights j were off. Trouble light blinking. i Want to T.B. 251 NW, signed sheet, stairtower dark 1(no problem, i j knew way around), Turbine Track Bay dimly lighted. y j Went to T.B.-306 - OK, signed sheet T.B. Swgr 377 - CK, signed. sheet i T.B. 250 by Feedpumps - noted not running i by Panel 113 - no lights on, no audible or trouble alarm I i estimates time approximately 0605 l Continued rover rounds to Panel 106 - South Stairtower R.B. 289 was alarming display said "on internal clock" had two troubles displayed j Want to R.E. 215 - Fire panel 103 alazzing - silenced R.B. 1st - Fire panel 101 alarming - silenced j both panels were in trouble - unknown ii R.S. 175 - Signed sheet R.B. 261 - SEGTS - CK Panel 105 - silenced troubles l CO2 Room, about this time, evacuation alarm sounded went a to Unit 2 Control Room assembly point lt Walked around with Pat Brennan on 8-15-91 to Panal 123 and Panel l i 113, power on light was burned out on Panel 123. " Power on" light-was on, on Panel 113. 4 5 i i i 4 3 4

AUG 15 '9& 15 da ret ICT r1GMT & Cortl DTS P.5 kTh&#T (, PbG 6. +op4 Poet y Aug. 13, 1991 Interview (Cont'd) Mark Leemasie (called at home) Was located in the Fire Dept. Office when lights flickered and noise was heard. Radio communication was gone. Hear Mere was out. chief Narvey directed personnel to cover vital areas. Pat Wilson was in RX Bldg. Pat Brennan was roving T.B. Bernie & Mark were to cover control 31dg. Trip to c.B. uneventful Panels Passed in routes Panel 114 Elect. Say Elv. 261' Normal Panel 120 C.B. Elv. 2618 Norinal Panel 125 C.B. Elv. 261' Normal Panel 121 C.B. Elv. 261' Normal Panel 125 C.B. Elv. 261' Normal Panel 127 C.E. Elv. 244' Trouble Morn sounding - Silenced Panel 126 C.B. Elv. 214' Trouble Horn sounding = silenced, also an amber 1 light was lit on panel Checked valve room on C.B. elv. 214' light was on in room. No indication of system actuation. stairwells were dark, Elv. 261' C.B. was dark. S.A.E. announcement-and reported to control Room.

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I p11AcumEH7 7 PAGE J *f 9 L 88F2 LIGHTING SYSTEM POWER S0lEl af4) MINIMIN ILLUMENATION AVAllaeLE Pa0E 7 MODES (F (PERATION TRaNStENT 9(lRMAL LOCA LOCA & SEISMIC w Tw 'r E Of-1 0F POWER tLLUN. "I"* 1 0F um MIDL 1 0F % OF LW MtN. - gg Mpl gg MIN. ESSDITimL gg PRUviDEO AMIL. POWER PRovtDED AMR. POWER PROVIDED AVAll. POWER 8F007 SOURCES PRDv!OED "'"E-* PUWER SOURCES B7 POWER rFOOT m PRUvt0ED "" L* lI0HII"U S0WCE CA80LD B7 POWER NT SWRTS BY POWER FOOr Ems BY POWER NI EN RE944RR$ StamCE CMOLD BY POWER S0WCE CANOLD SOURCE CaNI]LD gggggg CWOLO IIL 800RM L YES NORMAL NONE* N0pp4mL NO NORMAL NO NORMmL YES MTOR m EL. 215 2 WEB 4 PS!C EE-67C ESSENTIAL YES ESSENTlal YES ESSEurial NO ESSEurtal YES ESSEMital YES sPDsi FUEL e HOW pc gar.Paca g e MoUR 8 HOUR 8 HOW G MOUR ent. Pack YES ent. Pack YES ent.Pacw YES ent.Pacw 880NE L NORMmL 'YES WORMmL NONE* NORMAL NO 880RMfL peg NORMAL YES EaCTOR BLD(L g EL.290'-F ESSDsYlat YES ESSENTIAL YES ESSENilmL NO ES D rtal. YES Essosttat TES EE-67D 9 MlUR S HERp 8 H0tp 8 HOLD Bar.PnOf Ont. PmO( YES enT. Pact M 6N ent.Pacg YES g,y,,o,tR NUE gg 880pmaL YES NORMAL NONE* N0fMmL NO es0RDM. NO NORMAL YES 2v994PStC ACCESS PATH G4.Y E8CNIN ESSENTIAL YES ESSOffM YES ESSENT1mL NO ES!KNital YES ESSEMital YES EE* .M Raf.PmOC N OmT.PmOC YES car. Pact YES ent. Pack YES enT.Pacu 'OE NtpMat. YES ~ NtpMal NipdEe N0pteal NO MORMmL 3s0 peRMmL YES NWC E{Tm ESSENilat YES ESSENT1mL YES ESSDITM NO ESTuttal YES ESE Nrtal YES ae Baf. PaDL eni.PaOC YES ShT.PnCE YES enT. Pack YES est. PaCR NODE NDRMAL YES MORMmL NUE* NORMAL NO edORMfL 00 0 NORMAL YES 2YBB-UPSID I Skg-E310silmL YES ESsostNL YES ESSENT M NO ESSEwitas YES ESSDettal YES EE-67N 8 Belm Bar Pact 'IUT. 8 69UR 8 MRR S MULF Bn F. P6 .YES ear. Pack YES env. Pack TES S HotM I car.Pacu NONE I e titWMat. LIGNil80 IN EACTOR BUILDING IS POWEND FROM PLANT EMERENCY POWER i DrSTRImlfitM SYSTEM. OURfMG LOCA. THIS NON-iE LICHT!*G SYSTEM POWER IS TRIPPED si see scCiDDef Siment i

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9 [ACHMGMf-8 ACCESS ROUTE TAKEN BY OPERATOR FROM CONTROL ROOM TO UPS i ROOM IN NORMAL SWITCHGEAR BUILDING ON 8-13-91 1 The following route was taken by operator from control room to go to UPS room in switchgear building to j transfer alternate power source to UPS units ; ] Operator left the control room EL 306 through south door and proceeded to west. Then he turned north along the corridor on the westside of the control room. Then he exited the control room building through north west door EL 306 to Auxiliary building. He then took the stairway just south of the elevator to go to EL 261. Then at EL 261 of Auxiliary building, he proceeded to south and entered the corridor ( Electrical equipment Tunnel). From the corridor he entered the normal switchgear building EL 261 and proceeded to stairway located in the center of the building (West half) down to EL 237 where the UPS units 2VBB-UPS1A, 1B, 1C and 1D are located. He then transferred the UPS power to maintenance power source. After restoring power to the above UPS units, the operator proceeded to UPS 2VBB-UPS1G via the door on the east end of the room, went south down the hall, through the door on his left (eastside) and entered the control building. He then took the stairs down to EL 214 where f UPS 2VBB-UPS1G is located and transferred the power to the maintenance power. m p % l f p. g. [cA BMM L ) i t x 7 M se l l

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==._i =ER CouuD6mTE BODSTUt PM MPLFLOW MADEM FEEDPUPP MIE FLOW MA[ER C0xBORO PAEL TYPICAL TRAIN A, B, & C TRAIN A - 2 CEC-PNL825 [ CROSSOVER HEADERS BETWEEN TRAINSh TRAIN B - 2 CEC 4HL826 \\ PROVIDE CROSSOVER FLOW / TRAIN C - 2 CEC 4'NL627 FEEDWATER CONTROL PANEL 2 CEC-PNL612 l

GE Industrial WYh(MM&7 {Q & Power Systems l-PA GE_L of 2 ItYt" 02**"for Ser nce: Oggime? e ,n ' [r'T CC"La'i 353.? Jam 57. FC bca 484?. Sca=se, tJY 13221 t NIAGARA MOHAWK POWER CORPORATION cc: NIAGARA MOHAWK POWER CORP. NINE MILE POINT NUCLEAR STATION 1 l UNIT #2, GENERATOR #180X632 R. Abbott l GENERATOR INSPECTION - POSSIBLE N. Kabarwal l PHASE-TO-PHASE FAULT M. McCormick l GENERAL ELECTRIC COMPANY i L. Jordan (37-3) l August 28, 1991 W. Judd S. Kolb l R. Smith l W. Turk Mr. Anil K. Julka NIAGARA MOHAWK POWER CORPORATION l 301 Plainfield Road I North Syracuse, New York 13212 Dnar Mr. Julka: Due to the August 13, 1991 failure of the phase B step-up transformer on Nine Mile Point Unit #2, General Electric Generator Engineering recommends performing a thorough visual inspection of the generator stator end winding support system at the next convenient opportunity. The inspection should include all accessible components of the stator end winding support system, including stator bar end arms, blocks, ties nose rings, and outer axial supports. This inspection should be accomplished by a GE Generator Specialist trained to detect the potentially subtle indications of damage. The above recommendation is based upon the possibility of l phase-to-phase generator short circuit currents through the failed transformer as high as 5pu. The initial. recommendation for the immediate generator inspection considered the possibility of higher l currents, resulting in several times greater end winding forces. l Physical evidence of high current forces at the transformer low side was the primary driver for this recommendation, since measurements of generator currents were not available. Our engineers continued to review the limited data available and subsequently concluded that currents high enough to do probable damage to the generator were not j likely. This conclusion was reached primarily by considering a measurement of depressed generator voltage during the incident, inferring generator currents, and specific capabilities of the generator design. I ~ l l

A Tf 4M Mf / 0 ( W46 %dF 3,,,. Pcge II Mr. Anil K. Julka August 28, 1991 Should you have any questions regarding this recommendation,. please i l contact me. <Very rul yours S %\\ 0 i i J eph . Kirhch Ma.ager Enginehring Services / Pow'er Generatioh Services ~SfRACUSE OFFICE JAK/bs JAK-059 i i i l i I}}