| title = Niagara Mohawk Nine Mile Point Unit 2 Event of 910813.

{{#Wiki_filter:Niagara Mohawk Nine Mi>e point Unit 2 Event of 13 August ]991 Report by:   Melvin L. Crensbam Consulting Engineer Po~er Systems Engineeriag Department General Electric Company Schenectady, NY 8 September   1991

5 iagara Mohawk 5 ine Mile Point Unit                         2 E vent of 13 August 1991 05:4S Qn August 13, 1991, at 5:48   Abf the Unit 2 phase B generator step-up transtormer failed. Oscillographic records of the event are available from a digital data recorder at the Scriba Substation. They show various 345 kV and 11 5 k V system voltages and currents. Figure A with notations is attached.

The four cycles preceding the fault show no signs of a gradual degradation or a developing disturbance. The oscillographic traces and station protective relay targets reported, indicate a ground fault occurred on the high voltage winding.

Depression of the 345 kV phase 8 bus voltage to about 39% of the prior value was observed from the oscillographic trace. This suggests the involvement of only a portion of the entire winding. The 345 kV line currents and voltages show rapid development of the ground fault beginning at point 1 with the ground current reaching a constant value of 1,300 amperes in 1 1/2 cycles at point 4, The flashover in the faulted transformer occurs just preceding a maximum in phase 2 to neutral voltage (as would have been expected) at point 2. The 345 kV line current in an unfaulted phase increases in step function manner to 350/o of the prefault value at point 3, No high speed recordings of voltages or currents within the plant were available. No sequence of event recordings were available to correlate relay operation times. Due to the large amount of magnetic energy coupling the generator rotor and stator, and known electrical parameters, thc decay of fault current contributed by the generator to the solidly connected transformer would have spanned a number of seconds as thc field decayed.

: 2. Transformer Neutral Current Relay (Type       IAC).

: 3. Overall Unit Differential Relays (Type BDD) in phases 2 and 3.

: 4. Generator Phase Overcurrent Relays (Type PJC) in phases 2 and 3.

r Fv Following isolation of the generator and failed transformer from the power grid, marked 5 on Figure A. only a single 345 kV phase to ground voltage record is available. The magnitude of this voltage on an unfaulted phase is 74fo of the pre-fault value. Since generator neutral current is limited to less than 8 amperes. it is known that the faulted transformer appears as a line to line fault with some impedance to the generator. By trial and error calculation, generator.

line currents are found to be 0, 1.9 and 1.9, multiples of the rated value of 31,140 amperes. The line-to-line voltages have magnitudes 74 lo 74 lo, and 25%

of the rated value of 25,000 volts. The decay of this voltage for 0.2S seconds of the recording has a measured time constant of 2.7 seconds. The calculated value of the impedance of the faulted transformer as seen by the generator is 0.23 per unit.

Conditions prevailing during the six cycle time period following the fault, marked 2 on Figure A, cannot be determined with certainty. The exact nature of the fault within the transformer is not known and the physical evidence will be strongly affected by the continued flow of energy from the generator due to the inherent time constant. The flashover of only a portion of the HV winding is evident since the 345 line voltages to neutral remain at 39%o, 867o and 86'1o of the pre-fault values. The presence of "residual" in the measured 345 kV line currents provides the evidence of transformer neutral to ground current. This requires that the fault involves a path for current to ground from the high voltage winding. Recorded voltages and currents show a step change to new values and no dramatic change during the time period of the record, which totals somewhat less than 1/2 second. It could be said they are "cleaner" and less distorted than commonly seen oscillograph recordings of faults.

Given these observations and since both the generator and the system were supplying fault current into the faulted transformer, generator line-to-line voltages preceding isolation would be expected to be greater than those immediately following isolation.

It has been speculated that very high frequency energy (mHz region) may have causal malfunction of logic and control circuitry in the UPS equipment. A broad-range of frequencies would be expected in any arcing phenomenon such as occurred in this fai1ure. Nothing in the available data or design parameters of the plant equipment would suggest an extraordinary generation or propagation of higher frequency components. 'Ihe failure of a transformer and internal arcing is not a rare occurrence. Comparison of oscillographic charts

from similar events in other plants show nothing unexpected or unusual in this particular failure. It must be borne in mind that the sampling rate of the recorder is listed as 5.814 kHz and frequency components in excess of perhaps 500 Hz would not be accurately portrayed.

GE experience in testing of typical power transformers (such as the Lnit Auxiliaries Transformers) provides an indication of the expected coupling between windings at radio frequencies in the region of 1 megahertz: The attenuation factors range from 1,000: 1 to 10's of thousands: 1. Direct measurements could be made in this plant to determine attenuation factors for individual transformers over a range of frequencies. These tests would be made on non-energized transformers using an RF signal generator and a sensitive, calibrated detector.

Attached recent articles on electro-magnetic interference.           Reference 1 discusses IEC 801,4 and the characteristics of electrically fast transients.

V   i The possibility of elevation of thc station grounding system as a result of this disturbance was postulated. The relatively high level of ground fault current, estimated at 1,300 ampercs from the available recording, would not have been conducted into the plant. This current can only fiow in Rom the 345 kV system for the 6 cycle period required for relay and circuit breaker operation to achieve isolation. The generator ground current would have been limited to less than 8 ampcres by the neutral grounding equipmcnt. Elevation or differences in ground potential within the plant would therefore not have been expected during this event.

Reference 1 discusses the problem of achieving a "super" ground and concludes that a stable ground reference for interconnected equipment is of greater significance. Since normally circulating ground currents are not expected, testing with very low voltages and currents is recommended. Note especially the recommendation to test with a frequency non-harmonically related to the power line &equcncy.

The transformers stepping the voltage down to successively lower voltage levels are connected in a manner to minimize coupling of power frequency and higher frequency. components between thc various busses.                   Specific configurations are:

: l. Normal Station Service Transformer-delta 25 kV to wye 13.8 kV with 400 ampere resistive grounding on the 13.8 kV side.

: 2. Load Center Transformers-delta 13.8 kV to wye 4.16 kU with 4R   ampere resistive grounding on the 4.16 kV side..

: 3. Load Center Transformers-delta 13.8 kV or 4.16 kV to wye 600 volts with neutral solidly grounded on the 600 volt side.

: 4. Reserve Station Service Transformers-wye 115 kV, delta 4.16 kV, wye 13.8 kV, The 13.8 kV neutral is 400 ampere resistive grounded. The 4.16 kV circuit is connected to a zig-zag grounding transformer with a resistor in the neutral connection, presumably for 400 amperes.

While no evidence is seen of voltage distortion in the four cycles preceeding the failure, excessive duty could have occurred if these transformers had been subjected to low level direct current previously. References 3 and 4 are attached for perusal.

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fncfustrfal Equfpment EISCtt'OfllCS                               Ill lndLIStl'Igf APPIiCatienS A Discussion of Fundamentaf ENlC Princfpfes for Electronic Controllers ln an industrial Environment By 4t'iHiam 0. Kimmel. PE Kimmei Gerke Associates, Ltd EDDIC problerrs i~:h:ndustra! ccnuois are     bances are a weH known    irdustral problem. cally a power disturbance prob'.em.:s: .

aggravated by harsh eni.ronments. mixed         In iac:. when a problem occurs. ke tirst      the car..er of residual eiiects of o-.

:ec.'".noiogies and a laclc of umform E!ifC     though': is:o blame the power company.        disturbances. Any 'ind;sinai or commer:

guidebnes. T:is arLicie '>el concentrate on     Often power quality is a problem (especially  suucture has sigiu8cant .'ow ~equen

    ;he common as;ec:s of electronic controls     if grounding issues are inciudedl. but the      currents circulating:hrough t.".e grou in an !ndustnal en>".ronment. which is         problem is almost always generated by          system. sometimes because the .nergy generally mucn harsher:ban the ofGce           adjacent equipment.                            intentionally dumped onto the ground (s.

envirOnmenL                                         Tradiuonal problems with power include      as with an arc weider) and someur..

What is the industrial enviroment and       spikes and transients, sags and surges, and    because of unintenuonal coupling or v what can be core about it! The environmen       outages. which threaten the eiectroiucs via    an inadvertent connection between neu includes the entire gamut of '.he basic         the power supply. These problems are            and ground somewhere in the!aciiity.

threats. power disturbances. RFI. and           fairly weil documented and are often solved        Radio Frequency Interference.        R ESD. RFI and power disturbances may be         using power conditioners or UPS.                dio frequency interfer~nce affects bo locally generated or not. Mixed technolo-           The most common power problems              analog and digital circuits. with ana'c gies compourd:he problem. Digital circuits     confronting electronics today is the sag        circuits being generally more susceptibl are used to switch."ne voltages via relays. which ~icaily occurs during turn on and         Surprising to many, the pnncipie threat Analog sensors are input devices:o digital      the spikes which typically occur during turn     not the TV or FM stauon down the roai controls.                                      off of heavy inductive loads. ~<..e sags         but rather it is the hand held L~snut:~

Increasingly. there is a need for a        simply starve the electronics. The high        carried around by facilities personnel. A or.

:ooperauve effort between the designers.        frequency ttansients barrel right through        watt radio will result in an electnc ne!d ~

manufacturers and instailers to come up        the supposedly Stered power supply to          (Ne volts/meter at a one meter distance with a rock-solid system. A common              attack the electronics inside.                  enough to upset many electromcs systems complaint is that the mstallers or mainte-          Digital circuits are most vuhierable to        IEC 801.3 speciGes immunity to elec ".

narce people won't follow the instaUation      spikes which cause data ettors or worse.        Gelds of one to ten volts per mete requirements. This may be true, but it          Analog circuits are most vukierable to          depending on the equipment. with tive must change. smce there are problems            continuous RF riding on top of the power.        volts per meter being Se level for typic which cannot be solved at the board level.          FIPS PUB 94 provides guidelines on          equipment. As can be seen from the abov It is also true that manufacturers often        eiectrical power for commercial computers.      approximation, three volts per meter is nc specify installation .equirements which are    This is good infortnation, but beware that      an excessive requirement, and even:e not practical to impleinent, and there are      factory power is much noisier than commer-      volts per meter is fairly modest.

documented cases where the prescribed          cial power.                                          Electrostatic Discharges. EiecLc installauon procedures wil! cause rather            The guidehces of IEC 801.4 speci5es an      static discharge is an intense short durauoi titan cure a probietts.                        electrically fast uansient (EFT) that simu-      pulse, having a riseame of about one The!adt of umiken guidelines has ham-      lates arang and other high speed noise.          nanosecond. This is equivalent:o a burs.

pered EMC prtiless in the industriat            Ebs are quite short ranged  they                of 300 MHs interference. Static buildup.

arena. Fortunately, the European Commu-        diminish rapidly with distance due to induc.      of 15 kV are not uncommon.

nity is working to adopt the IEC 801.x          tance in the line. But at short range, they          Dry climates, including northern climate'.

would be wise to adopt them, even if there            Unfortunately, attention is placed on the is no intention to export.                      front end of the electronics, the power          Wham Kimmel is a pn'ncipal with Kimme.

supply. With industrial controls, the prob-      Gerome   Associates. Ltd. The firm special.

The Basic Threats                              lem is the controlled elements. If the          i@ca in preventing and solving electromag.

The three basic threats to industrial      electronics is controlling line power, the      netic interference and compaabQity (E.Mh electronics are power disturbances, radio      disturbances sneak in the back end where          EMC) problems. Mr. Kimmei can frequency interference, and ESD.                little or no protection exists.                  reached at 3544 N Pascal, St. PauL .~i~

Power Disturbances. Power distur-              System ground, while not being specifl-      55108,   or telephone 612.330-3728.

Vcc                           line pouer I

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i suitcl.e I                                                          piouer F:g.'re '.. Amp'.'Ger detnodulanon.                                       Figu:e 2. Transient!eedback path.

:n   ~".nter. offer opportumty !or ESD.          en cour ters a noriinearity such as a semicon-      to heavy equipment. wtuch.s;itc. -.

Industnai environments. with the:r moving       ductor device. All such devices give rise to          hy heavy starting .'oads and inducnve .

eq ipment. are loaded with potenual ESD         a DC level shift when confronted with RF.            a<<wn of TyptcaUY the e!ectronic con:r sources: rubber rogers. belts, and produc-       ln a radio receiver they are called detec-          switch Une power using relays or;;.-.

uon ou'.put such as plasnc and paper roUs.     tors. Noniinearities are minimized in linear        This exposes the back end of the cont;=

all add up!o a real ESD th:eat. and t."is       devices, but:here is always enough to cause          to substantial line transients. which coi-r."meat is more likely to occur even m           problems. The upshot is that the ampli6er            back to the circuit power and ground

        ;elanvely moist environments. Look:o IEC         demodulates the RF. generates an errone-             disrupt the digital circuitry as shown 801.2 .'or ESD standards.                       ous signal. and passes this error on. This           Figure 2.

effec'. is shown in Figure 1. Output hnes are           It is mandatory that the transient:

Elec! ronics Design                              similarly affected, with capacitive couphng         rents be diverted or blocked. since Electronics:s generally the ultimate        back to the input.                                             system cannot withstand t.".e .-.~g'igital victim of:nterference. The hter.'erence              The soluuon is to prevent the RF from             tudes likely to occur with an inducuve k:i Gnds its way through various paths:o the        getting to the amplifier. either by shielding         unless special steps are taken.

electronics equipment itself. Let's concen-      or filtering. The most common path to the               Self jamniing can be Unuted by contrcli trate on w'rat can nappen to your electronics    amplifier is via an external signal ine from         when you switch !he Une. using ze from !he back door. that is. by direct          the sensor. but if the ekctronics is not             crossing devices. Of partic~ importan radiation into the electronics and by con-        shielded. direct radiation to the circuit board     is the mrn off. since dtat is when ducted:nterference through:he signal and          may also present a problem.                          inductive kick occurs.

cont:oi lines.                                        Assuming filtering is the sekcted method.           lf a6 power switching used zero crossu Sensors. Low level sensors. such as        use a high ~frequency Glter, designed to             devices. the transient levels in the facto ther...ocouples. pressure sensors. etc.. are    bkick signals up to 1 GHz or even more.               wouki be dramaticaily reduced. Unfor.

characterized by very low bandwidtbs and        Use femtes and high frequency capacitors,            nately, that goal is well off in the futu:

      !ow signal levels. A major Meat to these        Do not rely on your low frequency Glter to            Until then, expect that high voltage pow sensors is radio frequency interference.        take out RF.                                          transients wlloccur, and they must be de either from nearby hand held transmitters            At the op amp. you shouM also decouple          wldl.

or more distance land mobile or Gxed              your plus and minus power to ground at tbe                Optical couplers and relays do not provi transmitters.                                    chip. If your ground is carzying RF, you can        sufficient isolation by themselves. Tht But:hese are high l'requency, much          anticipate the same probkm mentioned                high capacitance provides an excegent hii above the bandpass of your amph6er. right?      above, since it will comtpt the reference            frequency path, and if they are stacked t Wrong! Low frequency amplifiers are              level.                                                in an array, tbe capacitance wi6 add up plagued by two,ybeaomena: out of band                Data Lines. Digital data lines wiU be            pass surprisingly low frequencies. The:

response and <<stso rectification. These          upset by the RF problem as in anakig, but            capocitances an't be elim'mated, but yc combine to provide false information on          tbe levels necessary to upset are higher.            can design yow control circuits to minimiz levels to the system.                            Instead. digital data lines are tnucb more            couphng paths and to maximize low impe<

All amplifiers have a normal bandpass,      susceptible to transient ghtches. All signal          ance alternate paths.

typi6ed by a 20 dB/decade roUof or more          lines should be 6ltered to pass only the                  Transient suppressors should be installe at the high end. But resonances due to stray      frequencies necessary for operation. If the          at tbe kiad, which is the source of the spih inductance and capacitance will give rise to    threat lies in the bandpass of tbe signal,            but they can be installed at the controUt amplifier response Gve orders of magnitude      then shielding or optical links will be              as weal.

or more above the nominal bandpass of the        needed.                                                    An interestmg effect occurs when con amplifier. This means an audio amplifier              Switched Power Lines. This refers                bining zero crossing SCR regulators wu will respond to signals in the hundreds of      specifically to the power being contro9ed            low level Mnsors which use line frequerc MHz.                                            by the controller device. Industrial control-        noise canceHng techniques. Very seftsitiv The second aspect occurs when RF            lers are commonly tasked to control power            sensors sometimes are sampled. for t JQIL"August a~!

      'f80                                                                   , burro u High Current                    Pouer VAC DC                    I PS               Electroni>>:s Fir're 3. Common industnai   powe. supply.                               Figure 4. awful:rple ground paths.

enure   power     yc!e to cancei the ine         l(ore or'.eh '.he problem is conducted.          eliminate RF of g.ound noise...at freq'ncy conipohent. If t..e   samp!e occurs     eirher 'aa power or graurd. The problem            work, but:hese problems can be rc.

co.","u;.ently wi:h ire power sw'.tching on     occurs due:o power and g.ound distur-                with an isolat:on rant(armer:o =".-..-

or oif.:he average :o rhe sensor will be         bances caused by the equipment. It is an all        neutral to ground noise and ~~rh "~II po;

    .pse'.. and an e.-.or ~4 "e recorded.            too common pracdce to draw controiier                linc Glters. So you may wan:;o try power f;om the same source as feeds the              inexpensive approach nrst.

System Design and Installation                   power eqtupmcnt. T."is power may provide                Data I.inks. Data links are su.~ng Once >e elect:onics is designed. it           :he recessary energy to drive the equip-            over the er'.tire!acirty. exposing ther.:

becomes a p.oblem of!he system integratar         ment. but it is not suitable to power the            two principle e((ects. ground raise are and installer:o ersure that thc electranics       electroiucs lFigurc 3).                              pickup. Ground nois>>; will cause data er.-

is cravided wuh the environment far which           Hopefully, all indusuial equipment wiU            unless the electronics has been designe" it was des;gned. Most of thc umc. this           have electronics powered from a separate            accornmodatc potential differences of ->>

work is performed by power experts and           low power 120 volt circuit. It solves several        eral volts or more. This is accampbs; clectricians. and they are not always aware       problems. First. it separates the electron-          with dif(crential drivers and receivers:f =.

of:he intcrfererce probkm. Often, on site.       ics power from the probably very noisy                must be direct coupled. Optical 'hnks-rhe power quality is blamed for thc equip.      indusu@ grade power, prevendng the                    eventually take over these links.

rrent anomalies. But the problem can often       switching transients and startup sags from              The other aspect is RF pickup. Inexpe be avoided by following a (ew basic prina-       genug to the electronics. Second, if it is          sive shielded cable is suitable ples.                                            necessary to condition the electronics po~er                    Ground borh ends! Do not app (ar:.'urpose.

The industrial conuol device is either       from an extet".A problem, it is tar cheaper          single point ground techniques to RF. i!

integrated into a system at!he factory or         to condiuon the watts necdcd (or electronics        Iaw frequency ground loop problem:s instaL'ed separately on site. Controllers         power than it is to condition thc kilowans          threat. then onc end can be capaciuve handle a varicty of devices such as motor         required by the system.

speed controls. positioning devices. weld-           If power cannot be separated. then it is ers, etc. fnterferencc presented to the           necessary to provide a bu!letproaf power            Summary electronics can be signiGcandy reduced by         supply. preferably incbrding an isolation                Industrial electronics are subjected rc appropriate measures outside of the elec-         transformer, to separate the entire power            harsh environment. Good design and inst.

uonics box.                                       supply from the electrical equipment.                !ation techniques will minimiae problems There is no way to accurately assess die           Ground Noise. Ground noise, inevita-            thc Geld. Adhcrencc to the Europe; rhreat without test data. But rcgardlcss of       ble in industrial environments. must be              standards, IEC 801.x is a good start, ev>>

the br(oration avai!ab!c. much can be           diverted from the electronics modu!c.                if you are only markeung in thc USA.

accomplished by correct instagation, and it       Multiple grounds in a system wiG often doesn't cost much if done at the start.           result in ground curt ents circu!sting through        Bibliography RetroGts become cosdy. especially if ac-         the cquiprnent. and ground noise circuhting          FIPS PUB 94, Guideline on Elec'ac:

companied with factory down time.                 through thc electronics path will cause              Power for ADP Installauons. Scptcmber Let's consider dsc same prob!cms from         rnalfuncuon. Figure 4 shows some typical              1983, a system standpat. Your goal is to limit           ground loop situations.                               IEC 801-2. Electromagnetic compatibilit.

the interference wfskh must be handled by             A common approach is to demand a super            (or industrial. process measurement an<

the electronics.                                   ~arth ground. This is good, but it is not a           control equipmcnt, Elcctrostauc dischargr Direct radiation to the electronics is not    cure all. and often a super ground cannot           requirements, 1984.

often a problem in an industrial environ-          be achieved, no matter how you uy. How               (EC 801-3. Electromagnetic compatibi!it!

ment, but it does occur, and most often with      do you get a super ground from the third             (ar industrial. process measurement anI a plasuc enclosure.        The NEiMA type        4oor? The real need is to gct'a stable ground       control equipment, Radiated electromag enclosures provide enough shielding for            reference to all interconnected equipments.          cetic Geld requirements, 1984.

most mdusuial needs. If you don't want to          If this equipment is closely located, then a         IEC 8014, Electromagnetic compatrbilit:

use a metal enclosure, be sure !o get              very low impedance interconnect is feasi-            (or industrial-process measuremcnt ar.:

elecuonics which will withstand the RF            ble.                                                control cquipmcnt. Electrical fast:ransreht which will occur.                                      Power conditioners are o(ten tasked to          burst requirements. 1984.

EMC Test       8c De .<n

e industrial Fquipment Equipment Ground Bondlng-Designing for Performance and Life A Discussion of Ground Connection Fundamentals to Control EMl By D.B.L. Durham Dytecna Ltd, UK The problem of achieving satisfactory earth     eqtdpment to a stable ground point. achiev. inductance. At very high ~equencies:r bonds or ground connecuons has plagued         ing adequate levels of cabk shiekhng and for    stray capacitance across the strap EMC engineers for many years, not only         many other reasons. Many designers un-          donunate. This means that the volt "-:

because the bonds are often vital for the       derstand the requirement for short. fat bond    across a bond is generaily a funcuon achievement of satisfactory equipment pei-       leads to minimiac ground inductance, but        inductance and frequency. Based on Ohr.".

formance but because they affect the long       few appreciate that a critical aspect is the    Law this volt drop is shown in Equador. ~

term performance of equipment after it has     connection resistance with which the bond        For transients the voltage drop is giver..

been introduced into service.                    strap is attached to the equipment ground      Equation 5.

Recommendations on bonding have ex-         point. Thc basic requirement of any bond isted in the form of military speciBcations,                                                     Z      Rt + cutLS is that it should have as low an impedance such as Mil Std 1310. Mil 188-124A and         as possible (uille55 it is a dchbcratc induc-Mil-B.5081 (ASG) for some years and these       tive bond to limit ground currents). Tbe        V    IZ ~ jauU have generally proved satisfactory for most     impedance is a combination of the resistive new builds. However. these speci6cations       and the inductive components. Thc resis-                  d1 (5

have certain limitations in that they gener-     tive element is a funcnon of thc bond strap                dt ally do not spectfy consistently low levels     resistivity, cross sectional area and length. where Z ~ strap impedance. cu ~ tacoma of bond impedance. nor a suitable test           see Equation 1. whiht the inductive compo-      frequency, V ~ voltage, and 1 ~ current.

method. The introduction of ncw EMC             nent is a more complex function of thc bond        From this. the higher thc inductance th speciGcations in Europe with the EEC             strap characteristics as shown in Equation 2. more isolated the circuit or box become Directive on EMC and the requirements for                                                       from ground. Ths can have sigru6can R~-    qf                                  0 j'f iong tenn stability in EMC characteristics                                                       effects oa equipment. inchding enhance has directed the UK nuTitary to review                   A                                      ment of noise injecbon onto arcuits, reduc=

cidsutlg spcciEcaQons and Introduce a ncw Defence Standard to tighten up perfonn-

ance requirements for nurttary equipment.

Dcf Stan         (Part 1)/1 has been intro-L    iZ, 2ic L

                                                              ~

ln b~c

                                                                          + 05+ 02235   j b+ c" 2f J non of Ster performance, and loss oi coaunlmication range. From a TEMPEST standpoint it may result in more radiation from emanent. lt would seem from this (2) ducal to address thia area as far as mob9e                                                        that the cntcria tor any bond is the and transpottablc canmunications installa-      where R        resistance, g ~ resistivity, f>  inchlctancc and hence thc choice of short fat tions are conccnteia. but the requirements                    ~

length. A area, p, pcrmeabiEty of free shoukl have implications in industrial apph-    space, L ~ inductance. p ~ feLttivc            David Dugan served for 21 yean itt the cations and over the wlxHe ekctronics            permcabiTity, b strap width, and c stttp        Brrtiab Anny, where hc gained his Chgree market if long term product performance is        thickness.                                      ia dectricaf cnginceting. After service in a to be guaranteed.                                    The frequency at which the inductive        variety of appointments hc retired to join ekment dominates the impedance expres-          the Recalls'ES company as the Techmca/

Bond Degradation                                  sion when calcu!ating thc total inductance      Mtnsgcr rcspottsiblc /or the cfes/gn and Earth or ground bonds are generaHy          is, from Equation 3, typically 1 kHs. lt wgl    devclopnsettt of commctttication systems.

considered essenual not only for safety          be seen therefore that to al intents and        fn 198$ he jainef Dytecna as the iManager reasons. but as a mean of diverting EM          "

purposes thc bond except at DC and power        of the &ginecnttg Division. and now ts currents, "locking" circuit boards and            frequencies, may be assumed to be an            currcntfy Tchtaica/ Marftcting Manage..

38                                                                                                                            JulytAugust !991

sc';o rc(c gq(r     rri.

                                    ~~~cwc   "-av     ~

                                    ~l-   l 'sis~fN f           $ Qsk                                               gRrrf NT 'N,ff 'Srn ryort:4i   csi r:i.rrenl

                                                                                                                                                ',:!0 iQ A. os JVA5Hf5 rrllt fR scarc 5 err VOUAGE     &ifASI 'REhlENT Figure!. Bond resisurce.                                                     Figure 2. Four wire bridge method.

bond straps. However. an anaiys's of:he             progressive degradation nt bonds, whilst                  current thc layers heat up and are vapo-bondinductancf shows Jiat I'or a bond strap         the latter can reduce the ef'ciency of the                rised. After the current is removed t.".e Sm of 100 mm!or g, 15 mm ~~de and 2 mm Ihck             bond f;om the moment it is installed. It is              can return. Thus high currert techmques the impedance at 1 MHa will be 3.8 Ohms.             particuiariy important in communications                  are not recommended ror:esang EMI It sounds extremely sin:pie. but work               systems, where 6lters are insuiied and                    bonds. The new Defence Standard in the performed in '.he USA'nd I:K shows that             shielded cable ternunations are made Jiat                UK speci6es a maximum probe voitage oi if an etrot is made 'in the way the strap is         the bords are of ',ow resistance and reuin                100 mictovolts. This reprcsenu typically a ternunated then a progressive increase in           their perfonnance.                                        probe current ol 50 milliamps under shor

:he resisunce of the bond strap to box                                                                         citciit (< 1 mQ) condiuons. This -:s juncnon can occur as the equipment ages.             Bond Performance and                                      insuf6cient to destroy surface 5lms. The Eventuaily the resisunce will begin to               Mtaalaremcnt                                              chssic method for measuring low resisunce exceed hundreds of ohms and may eventu-                 Experience has shown over a number of                has been to use a four:erminal bndge as ally go open c cuit. This can negate thc             years that for long tenn consistent bond                  shown in Figure 2. In this case'the current effect of the bond strap completely as part           performance a low value of resistance must                is driven between two points and Ae of the E!rII protecdon.

tVhat happens with bonds to cause this change! Essentially a ground connecuon is In Def Stan    ~

be achieved. This is typically 1-5 milhohms.

(Part 1)/1 the vahie has been set at a maximum ol 2 miUiohms. This VOltage aCtOSS the Sample iS meaSured witN a high resisunce probe. This removes Jie cfccts ot thc ptobe contact resistance and a series of irrpedances      from thc strap          level is measured through the individual                  lead resistance. This is generally consid-through to the grourd material, as shown            bonds. Thc logic behind this level is                      ered to be a laboratory method as the use in Figure 1. Each point of contact contrib-          twoloid. Firstly. experienc has shown that                of four contacts can be awkward. If the lead utes to the total bond per'.onnancc;. As a          with communicaions equipment in particu-                  resistance can be removed by a calibrauon result. a change in any contact condition can        lar this value ol bond resisunce is required              teclniquc then thc four terminals may be result in a change in the total bond                if consistent performance is to be achieved              replaced with a two terminal system.

resistance. As is weil appreciated, the"            in terms of reception ef6ciency and trans-                    h further possible re6ncment to the contact resistance between two metal sur-            mission characteristic. This is particularty              tecluique is to use a frequency that is not faces is a hnction of the pressure. The              so for TEMPEST protected equipments.                      DC or 50/60/iOOHx. In this case 10.4 Ha pressure exerted by the tip of a drawing pin        Tbe second point is that if the bond has a                haa been chosen. If an active 6lter is used is vastly greater than that from the thumb          higher resistance then there is a signi8cant              to Ster out a9 other electrica noise, then pressing by itself. Thus the contact from a          likelihood that progressive degradation will              it is posgblc to use the bond resistance sharp poult gives a tsoch higher prcssure            occur and the bond resistance wig increase                meter on powered up systems. It is worth t.'un a Oat point and 4gtiforc lower contact        in value. There will then be a progressive                noting that at this frequency the impedance resisuncc. Measutetata have shown that              loss in perfonnance.                                        ia stol htgcly represented by resistance sharp points enable Contact rcsisuncc of a                The main problem with measuring bond                  rather than inductance. The two termmal few nicroohm to be achieved whilst similar          resistances is that it should bc measured                  method is shown in Figure 3.

pressures on Oat surfaces result in mil-            using a low voltage/curtent tcchtilquc,                        The introduction of new EMC/EMI liohms of conuct resistance. It might be            Moat techniques to date for assessing                      spcci6cations in Europe has made it more felt that there is little or no difference                        driving a large current through the safety'nvolves important that once made the bonds have between these values, but in reality there          bond. This checks the bond's abiRty to                      coils latent long 'tcrlil performance. Ths is. An essennai aspect of a good bond is            carry current but does not necessarily check                means measurin on periodic inspecnon ard that it should remain so after the equipment        its EMI protection perfonnance. The rea-                    aRct maintenance. It is an essential aspect has entered usc. High pressures also have            son is that many bonds may when in normal                  of insutmg consistent perfonnance. It has the effect ol squeesing out corrosive materi-        use have a high resistance due to oxide and                been shown that within months apparen Jy als and insulating 6lms. The former causes          greasy 6lms. but when subjected to a high                  good bonds can deteriorate to .-igh resis.

tance. Ther.io.e t.'i vces ii       '-. ~

AAeqT                                              suo)ect to testing and .xa.-..;.-.a:.cn-as a ma:ntenance tas~.

                                ~      ic'oK ue45uI>eNr                                      L K ~military Experience There have oeen '.wo ~ lcr -.::

caused by poor bonus expenence eiieo otsis ascg          0                        degradauon .n ericrmance ~ready-uoned in:tus a.-.icle. The:oss i;cir, cation range. poor EMl pe.",'ormance other eifects aL'onrnbu'.e to a cons:dert reduction m equi".-..ent Nc:ency ann a.

ability. The secord ei;ect wnich is .

difficult to denufy:s:hat ai No Fault F.

(NFF) problems. An analysis of reN'."

failures from military reiiaLiity data .

shown that NFF inc:dents can ae extre..

FIXED RKSlSTANCE LEAOS                                      has been partially confirtned by reports .':

increase in availability of equipmen: .;.

clunate. Many fau!ts are due to "     'rier electrica contacts in connectors. bu: a lar number have been idenufied as excess:

Figure 3. Two termmal bridge method.                                                      EMI induced through poor ground onnc This may be caused by either a loose groi strap or connector terminauon to:he ':c A significant improvement In equipme 4            4                              availability and perfonnance is expec:e y                                    when more recent statisucs are analysed.

service of Ae Dyteaa Bond Resistanc I                c<~~  4c    c>~  ~~c Test Set DT l09 has enabled the L":

nal bridge method and an accurate miiliohm calibration star. dard. This meas urement procedure and equipment is als in use by other NATO nations and e!se where by iniTitary and naval forces wro hav recognized the same problem.

ment. This coupled with an increasing reed CUSTOMQAG Ti                4.++++"          9t  ~o'4+      a  ~~>      t iQN        to achieve higher and higher leveh of KMf CQMNC Rf AC.                0 odgot          tc~ 'e+  b~+.=nuators,            protectiwt has lead to an increased emphasis beng placed on the effectiveness of all types Coaxial Term.        %/@

                                                  <  y<c    <4~ connectors, of systettt grounds. These. further com-bined with a requirement to ensure the long Cata        ~pc+ q4      .attest                            life of systems once in service. have resulted in the assessment that bonds and lE                                                    terminations are one of the primary causes of EM faBures in systems. The require-11?0-1? bnCOln Avenue. FOlbrOOk.;4Y 11741                            ment to test these is clear. however the (S16) ~85.)4tX1 FAX i16.~BR >l14                              means to do so have not always been available to engineers.

INFO/CARO 29 40                                                                                                                        July.Aug.st '.9o'.

Panel SessIon PES Summer Meeting, July lQ, 1988 Long Beach, CaHfornia John G. Kappenman, Chairman Power System Susceptibility To                                 Induced. currents in the system, 2) the interconnected sys-tems tend to be more stressed by large region-to.region Geomagnetic Disturbances:                                        transfers. combined with GIC which will simultaneously turn every transformer in the bulk system into a large reactive Present And Future Concerns                                      power consumer and harmonic current generator and 3) in general, large FHV transformers, static var compensstors and relay systems are more susceptible to adverse influence and microperation due to QIC.

John C. Kappenman, Minnesota Power The effects of Solar. Geomagnetic Olaturbancea have been        TRhNSFORMER OPERhTION observed for decades. on power systems. However, the pro-found impact of the March 13, 1989 geomagnetic distur-          The primary concern with Geomagnetlcally-Induced Cur-bance has created a much greater level of concern about the    rents la the effect that they have upon the operation of large phenomena in the power industry.                                power transformers. The three major effects produced by GIC in transformers Ia 1) the Increased var consumption ot the Several man.made systems have suffered d)eruptions to their      effected transformer, 2l the increased even and odd harmon-normal operation d)aa to the occurrence of geomagnetic phe-      Ica generated by the half. cycle saturation, and 3) the possi-nomena. Moat of the man~e systems, such aa commu-                bilities of equipment damaging stray f)ux heating. As is weil nications, have brett made less susceptible to the phenom-        documented, the presence of even a small amount of GIC ena through technological evolution (microwave and fiber-        I20 empa or less) wN cause a large power transformer to optlc have replaced metall)c wire systems). However, the          half-cycle saturate. The haif~c)e saturation distorted excit-bulk transmission system, If anything, is more susceptibl ~      ing current ls rich ln even and odd harmonica which become today than ever before to geomagnetic disturbance events.        introduced to the power system. The distortion of the excit-And lf the present trends continue, it la likely the bulk trans-  ing current also determ)nes the real and reactive power re-mission network will become more susceptible In the future.      quirernents of the transformer. The saturation of the core Some of the most concerning trends are: 1) Th>> transmission      steel, under haif~c) ~ saturation, can cause stray flux to en-systems of today span greater distances of earth-surface-        ter structural tank members or currant wlndlngs which has potential which result In the flow of larger geomagneticaily-    the potential to produce severe transformer heat)no.

IEEE Power Ealineeciag Review, October 1989                                                                                  15

tr:rscs'rr ei     '- ry es. -e 'io:est 'esul!S trct   ~

de~~"      ~

    .;nree onase units.."ese:.ansformers         produce higher mag.       SUNSPOT CYCLES hND GEOMAGNETIC nnuces of harn onics and "or sume!arger amounts of rese-               DISTLRBhNCE CYCLES

      !rve power when comPareO with three phase deslgnS.                     On the average, solar             activity. as measured by t."e nur oer ".

monthly sunspots. follows an 11 year cvcl'e. he "esen!

ItELhy      HAND  PROTECTIVE SYSTEMS                                  sunsoot cycle 22 had its minimum tn Seoten.oer 1986. a."c is exoected to oeak in 1990-1991. Geomagnetic 'ela o 5                                     ~

      >here are    three ba5ic faitire modes of relay and protective        tvrbance cycles do not have the same shaoe as:ne sunscot Svs!ems:nat can oe attr:buteo to ggeomaghetic distur-                  number cycles. even thOugh they are cyclical. F Sure snows                     1 bances:                                                                the nature of the sunspot numbers and geomagnetic 3C!i"".v r

          ~ . alse Operation of:."e protection system. such as hav-ing OCCurreO rOr SVC. CabaCitar and line relay Opera-           SurtsIre4                            i 431 ~ 1444                              4uit'ocr or tions where:t e!tow of harmonic currents are misin-                                                                                             C(rtworts

:erpreter2 OV the reiaV aS a rault Or OVerlOad COnditicn.                     Cycle i7 Cycle la Cycle ia Cyote 20 Cyci ~ 21 Cctrs  rrrr apr25 This is the most common failure mode.                                                               i            I l        irumoer el                                                r i Olslureetd OdyVyear              Suitspoi Humber                  ~

        ~  Failure to Operate when an operation is desirable, this has shown to be a problem for transformer differential               150 t

                                                                                                                                                          ;    120 protection schemes and for situations in which;he                         I

00 output of the current transformer is distorted.                                           I                                                  I l00  j            ii                                        ~        ~   d0

        ~  Slower than Desired Operation. the presence of GlC                                       Ii                                                  I can easily build up high levels of offset or remanent                                                                                       i  de i

ttux in a current transformer. The high GIC induced off-             50  j,  I r

i 40 set can significantly reduce the CT time.to.saturation                                                           I                          I

for offset fault currents.                                                                                                                   ~   20 1

Most of the relay and protective system misoperations that                                                                              ~     ~ . ~   0

                                                                                    !400 35       ee     cS   50  55    40    45  70 75  40  45    40 are attributed to GIC are directly caused by some malfunc-tion oue to the harsh harmonic environment resulting from               Figure 1. Vaitstfons of the Yearty-Averaeed Sunspot Number enid large power transformer half-cycle saturation. Current trans-           Qetsmaenettealty Olsturbed Oays from '1 932-1SBB.

former response errors are more difficult to directly associate with the GIC event. For exampfe in the case ot CT remen-encc. the CT response error may not occur until several days           cycles from 1932 to 1988 i2, 3l. Note that the geomagnetic after the GlC event that produced the remanence. Therefore.            dleturbanCe CyClee Can haVe a dOuble peak, One Of WhiCh Can these types of faitures are more difficult to substantiate.            lag the sunspot cycle peak. While geomagnetic activity in the present cycle is expected to maximize in approximately 1993-1994, severe geomagnetic storms can occur at any CONCLUSIONS                                                            time during the cycle; the K-9 storm of March 13, 1989 was As evident by the March 13th blackout in the Hydro Quebec               a striking example.

system and transformer heating failures in the eastern US, the power industry is facing an immediate and serious chal-           EhRTHQURFhCE.POTENTIhL hND lenge. The power industry is more susceptible than ever to the influence of geomagnetic disturbances. And the industry             GEOMhGNETIChLLY.INDUCEDWURREVTS will continue to become more susceptible to this phenome-               The auroral electrojete produce transient fluctuations in the non untess concened efforts are made to develop mitigation               eanh'5 magnettc field during magnetic storms. The earth is techniques.                                                            a conducting sphere and portions of ft experience this time-varying magnetic field, resulting in an induced earth-surface-potentlal lfSP) that can have vetuee of 1.2 to 8 volta/km t2 Geomagnetic Disturbance Causes                                          to 10 volte/mile) during severe geomagnetfc storms in re-gions of low earth conductivity l4),

And Power System EEects flectric power systems become exposed to the 8 SP through the grounded neutrals of wye-connected transformers at the Vernon D. Albettsw2                                                    opposite ends of long transmission lines, ae shown in Figure University of iiIJnaaota                                                2. The fSP acta ae an tdeal voltage source impressed be.

SOLhR ORIGINS OP GEOMhGNETIC STORMS are then determined by dividing the ESP by the equivalent dc The solar wind ie s rsrffied plasma of protons and electrons           resistance of the paralleled transformer windings and line emitted from the sun. The solar wind fs affected by solar               conductors. The GIC ls s ques%tract current, and values in flares, coronal holes, and disappearing filaments, and the so-           excsee of 100 emperse have been rrNaeured in transformer lar wind paniclee interact with the eenh'e magnetic field to             neutrals, produce auroral currents, or auroral etectrojste, that foltow generally circular paths around the geomagnetic pate! at al-titudee of 100 kilometers or more l1). The aurora borealis ie           POWER SYSTEM EFFECTS OF GIC visual evidence of the auroral electrojets in the northern               The psr.phses GlC in power transformer windings can be l6                                                                                                 IEEE Power Engineering Review. October 1989

1 ~

44 Ina ia.sat~tat.ah

                                                                                            ~                    n rich I:.tars gr~ers ause   clay misoperat on tet REF EHENCES

                      ~ 44                                             I

Al              =.sr~ ti.RFACS                     9           Mageziht. May 1989. pp. 90 97 T   SARvii-SuRFACS     <T5hti41. ~

: 2. Jactlyh. J. A.. "Reel-Time Ptedicuch ot Gfcbal Goon agr ti Activny, Saltr Wind Magnetosphere Cauphi'g, "p.

141. Tarrt Sciehuflc Publishing Company. oxvo. '986.

htticaliy Induced Cunehis IQICI in Power Sytttmt.                          3 Thompsah. R. J., "The Amplitude at Saiar C.cie 22, Riidia ehd Space Sewiciis TtchhiCal Report TR 87 03, ctc bti 1987.

4 V. O. Albertgan ehd J. A. Vth Batten, "Utcuic phd hlaghe.;i many times larger than:he RMS ac magnetizing current, re-                      Fields at tht Stnh's Surface dut io Aurartl Cunenls." i55i sulting in a dc bias af transformer core flux, as in Figure 3.                TcahaaCIiohs ah Power Apparatus and Systems. Val. PAS 39 hia. 2. April 1970. pp. 578-584.

: 5. J. Q. Kappehmtn, V. O. Albtrtaon. 9. Mohan. "Curser Trahatarmtr ahd Relay PtrtolmtnCt ih the Presence ot Gtc magnetically Induced Currents." ISEE Triiheactians ah Paw e~

Apparatus ahd Systems, Vai. PAS.100. No. 3, pp. 1078-1088. March 1981.

I  I lo,pl              I~            The Hydro-Quebec System Blackout Of March 31, l989 io.ai

                                      <<ICI<<r~                             Daniel Saulier, Hydro-Quebec On March 13. 1989. an exceptionally intense magnetic storm caused seven Static Var Carnpensators ISYC) on the 735-kY Rgurt 3. OC Btt! af Trtntfarmtr Cart      Rulc Out to QIC.          network to trip or shut down. These compensetors are es-sential for voltage control and system stability. With their loss. voltage dropped and frequency increased. This ted to systartt instability and the tripping of all the La Grande trans-The half.cycle saturation of transformers on e power system              mission lines thereby depriving the HQ system of 9500 MW is the source of nearly all operating and equipment problems            of generation. Tho remaining power system callapsed within caused by GIC's during magnetic storms. The direct conse-                seconds of tho loss of the La Grande network. The system quences af the half-cycle transformer saturation ere:                    blackout affected ~ it but a few substations isolated anto lo-

      ~    The transformer becomes a rich source of even and              cal gene~sting stations.

odd harmonics                                                  Pawer was gradually restored over a nine hours period. Oe-

      ~  A great increase in inducttve vers drawn by the trans-        leya in restoring power wore encounterea because of dam-former                                                        aged equipment on tho La Grande n>>twark and problems with

      ~    Possible drastic stray leakage fiux effects in the trans-      caid load pickup.

There are a number of effects duo ta tho generation of high              SYSTEM CONDITION PRIOR TO THE EVENTS levels of harmonics by syatim power transformers. includ-                Tatal system goneratfon prior to the events was 21500 MW.

ing,                                                                    mast of it coming from remote power-generating stations at La Grande, Mantcouagon and Churchf8 Felts. Exports to Overloading ot capacitor banda

      ~  Possible rntsaperottan of relays                                neighboring Systems totalled 1848 MW of which 1352 MW were on OC interconnections. The 735-kV transmission net-

    ~    Sustained overvoltogos on lang. line energizattan wark was laded at 90% of tts stability limft.

    ~    Higher cfratffC Maker recovery voltage                          SEQUENCE OF EVENTS

    ~    Ovorlaadtno of harmonic fttfyrs of HVOC converter ter-          At 2:45 o,m. on March 13, a very intense magnetic storm minals, and dtotantan in tfio ac voltage wave shape            ted to the conaequortttal trt p or shut down of seven SVC's, that may result in loss ot dc power transmission.              Contafnlng tho impact of tho event through oporatar inter-The increased tnductfvo vora drawn by system transformers                yention was impassible att SVC'a having tripped at caaaod to during halfwycl~ soturat)an are sufficient to cause intoler-              function within o ano minute period.

abto system voltage depression, unusual swings in MW and                  A fow seconds l8-8 s.) after tho loss af tho last SVC, ~ II five MVAR flow on transmission linea. and problems with gener-                735.kV lines of the Lo Grande transmission netwark tripped ator var limits in some instances.                                        duo to an out of step condition. These Itne trips deprived the In addition to the halt-cyclo saturation ot power trans-                  system ot 9500 MW ot generation and subsequently ted to a formers, high levels of GIC can produce a dlstarted response              campteto system cat tapao.

17 IEEE Power Engiaeerintf Review, October f989

  \

Order          at .35  ky    TCA Bracche          TSC Brasche    This discussion addresses the effects of geomagnet:c cistii" oances on power transformers. The primarv effect:s cue tc 100'"o          '&#xc3;"                    I00~o      core saturation resulting!rom geomagneticaltv incucea c r     ~

r Ocl lr lent vendor Destgn Ocf tcfency         aafma1 UPS haS               Vendor no battery             naINIa1 test             na  int enanc e CI I'CUI t      sect loA docs AOI QCAt I OA batteries.

Battefies have not been       Design Deficiency replaced in Design Deficiency       6 ycafs k.S relay Back up      charactertst-                     Breaker batteries      ICS PfCveAtS                     ffcIct ion AC          degraded or        transfer to                   per design input to            dead            inverter logic poucr                          output.

salty is naihtchahcc preferred Ground           Vol tagc              AC pouer to                        logic trips                    Breakers      ups loads fault occurs on   traflicnt            logic nodule                          OA  poucr    2VSS UPStA,S,    CS-I,2  3    do hot auto loss of all phase of aain   oA   stat lofl       for UPStA.D,G     out pu'I             SISIPty     C,O,G trip   open; Ch-C     transfer to loads on B

transfofncr      AC  pouer            cspcrIchccs      voltage            failure.                      does not        mint.      UPS1A D,ri steeply            the transient    goes tou                                              close        supply Pernisstves Faul t                                                                             prohibIt    CS C 1$   clcafcd                                                                           breaker froze in 6 cycles;                                                                                 clo>Ing transfer cocptetcd in 12 cycles CS'4 ncsvh<

to If unsfer na Int sullpl y to lnvcl tcf out put

Static testing is performed with fixed voltage settings. The testing was performed on the 4049, 4011, 4044 and 4068 devices.

D. Power supply overvoltage. Vss>>Vdd The testing revealed that permanent physical damage was induced by tests C and D. Test B did not induce latch-up but test A consistently induced latch-up on the 4049 and at higher voltage differentials on the other devices- The 4049 was quite sensitive to this test.

A "breadboard" test circuit was fabricated to simulate a typical circuit path, i.e. a 4044 latch driving a 4049 invertor driving a 4068 gate driving a 4011 gate driving an MC1615 lamp driver.

Slow   rate dropout testing of the test circuit did not result in latch-up or other anomalous behavior.

: 3. Board   level testing has been performed on the A13A21 cards f'rom UPS units A, B and G. A stock card has also been tested. A test fixture was fabricated to hold the cards and supply paver and input selection and output monitoring. An MC 1615 lamp driver chip with LED's (light emitting diodes) was connected to the card outputs.

Static boaef testing revealed no anomalies on the A card, a damaged U10 4049 oN the B card, No anomalies on the C card and a failure to set, any of the 4044 latches on the G card.   (Note that latching of the 4044 chips is normal while latch-up is an abnormal condition.)

illuminated, has       been   duplicated by setting the PSF-not latch, lowering the       DC   voltage to approximately 4 VDC and lifting (floating) the     DC ground for several seconds.     If the DC voltage remains low after the ground fault the lamps on the board will reset and the external lamps (UPS fail, Logic fail and the SSTR lines) will remain illuminated. The simulation conditions are unlikely to be those of the failure event, however,           it demonstrated that the board can operate in an this illogical state.

has been A more complicated failure simulation (approximating the actual event) may produce the same results.

: 4. High Speed transient. testing on the power lines is planned and delayed pending laboratory analysis of the degraded samples discussed     in the following section.

M       C         0 A. NEGATIVE VOLTAGE ON THE OUTPUT OF THE 4049 MILL INVARIABLY CAUSE LATCH-UP-         INJECTING NEGATIVE VOLTAGE INTO THE OUTPUT IS IDENTICAL TO RAISING THE GROUND Vss ABOVE THE OUTPUT.

B. THE INITIALFAILURE CONDITION IN TERMS OF THE LAMP SETTINGS CAN BE DUPLICATED UNDER UNLIKELY CONDITIONS AND MAY BE POSSIBLE UNDER MORE   PLAUSIBLE CIRCUIT CONDITIONS.

The   following samples have     been submitted for laboratory analysis:

: 1. One   battery pack. Battery pack 1 from UPS 1C.

(2) integrated circuits from a failed A20 card.

Two                                                         A 4049 and a   4011.

: 3. A   failed   U10 4049   from the A13121, UPS B card.

: 4. The U10 4049 from the A13A21 cards from UPS's A and           G

: 5. The   UPS 6 Kl relay and   SWl switch.

The   following results have been obtained.

: 1. Two (2) of the Three (3) batteries from UPS 1C were dried out.

: 2. The 4011 from the A20 card is electrically good. Internal

    ~ ~

          . inspection of the Die revealed no anomalies.             The 4049 is lj

              'electrically   bad. A catastrophic failure. Internal inspection of the die revealed severe damage centered on the Vss and Vdd power lines and several input/outputs.       The initiating overstress was introduced on the Vdd or Vss lines as indicated by arc-over damage acoss the oxide between the two power lines.

: 3. Electrical testing of the U10 4049 from A13A21, UPS B revealed that it was not functional.         Internal inspection of the die revealed a fused aluminum metallization line to one part of the internal circuitry. Probing revealed no )unction damage on either side of the fuse site. This damage is characteristic of classic SCR latch-up.

: 4. Electrical testing of the two (2) additional 4049's was performed during circuit board test. The devices were functional.

: 5. Electrical testing of the A13A21 circuit board from UPS G revealed that SW1 was intermittently open circuited in the normally closed position. This condition would provide continuous reset signals to the 4044 latches through the K1 relay. The switch was isolated and a good switch was placed across the Kl relay. The circuit board inputs still would no latch the lamps. The Kl relay was removed and testing revealed that   it was electrically good. The findings reveal that either the Kl relay is either intermittently bad or there are other problem components on the circuit board.

R   0   U 0 A. THE DAMAGE NOTED ON THE 4049 FAILED INTEGRATED CIRCUIT FROM UPS B WAS INDUCED ON THE Vss (GROUND) SIDE AND SUGGESTS A GROUND TRANSIENT MAY HAVE OCCURRED. THE DAMAGE ON THE 4049 FROM THE A20

            . BOARD INDICATES THAT THE DAMAGE WAS INITIATED BY A TRANSIENT ON EITHER THE Vdd OR Vss LINE, BUT IT MAY ALSO HAVE BEEN INITIATED BY LATCH"UP.

B. AT LEAST ONE OF THE BATTERIES FAILED DUE TO OLD AGE WEAROUT.

C. THE CAQNE OF THE FAILURE OF THE UPS     G TO SET THE LATCHES ZS UNKNOWN AT   THIS TIME. THE SW SWITCH HAS BEEN FOUND TO BE DEFECTIVE AND ANALYST'S WILL DETERMINE IF THE COMPONENT IS RELIABILITY RISK.

                        -UPS lA   1B 1G TEST  

To prove   that the DC logic power for the Exide UPS is powered from the B-phase maintenance supply. The K-5 pickup and drop out voltages and the DC trip-point o=

the DC logic will be recorded for UPSlA, not for UPS13 and UPS1G. The internal batteries will be tested and replaced.

1.)   On UPS1A, logic UPS1B and UPS1G,   it was verified that the power supplies are fed from the B-phase DC maintenance   supply.

2.)   The K-5   relay drop out and pick up voltages were recorded   for UPS1A and they were found to be below the trip   point of the DC logic power.

3.)   On UPS1A,   UPS1B,   UPS1G, the maintenance supply was opened with the     UPS feeding the loads and no UPS trips occuzredo 4.)   On UPSlA, UPS1B and UPS1G,     the batteries were replaced.

CONC U This test proves that the DC logic power is fed by the B yhaae maintenance power.       It proves that the internal it proves that batCOries were effectively dead. For UPS1A on a slow transient that. the DC logic power will drop out before the K-5 relay will transfer to UPS power.

page 2 Numerical Results:

1.) The UPS1A DC logic trips at <16.7 VDC. (with.75.6 VAC on input) .

: 2. ) UPS1A:     K-5 relay drop out 47 VDC K-5 relay pick up - 52   VDC 4.) The internal battery voltage   was measured:

UPS1A:     Positive-Negative-UPS1B:    Positive-       0.54 Negative-      6.2 UPS 16:    Positive-      18.3 Negative-      0.69

) J 2VBB-UPS1C TEST  

 

page   1

To prove that the DC logic power for the Exide UPS is powered from the B-phase maintenance supply and that a transient occurs on the maintenance supply     it can if effect the DC logic such that   it will trip the unit.

This test is done with the old internal logic batteries and then repeated with new ones. Each of the inverter trips will be tested to verify that each circuit is still   intact except DCOV., An AC input transient to UPS will be simulated to verify that the unit can "ride out" a normal AC input transient without tripping. The K-5 relay pick up and drop out voltages and the DC trip-point of the   DC logic will be recorded.

1.)   Zt was verified that the DC logic power supplies are fed from the B-phase maintenance supply.

2.)   A rapid open and closing of the upstream normal AC input breaker to the UPS was done and the unit did not trip or go on battery. No noticeable effect was seen on the UPS output.

3.)   Each inverter trip circuit except DCOV was   tested and each functioned as designed.

4.)   Fast transient tests:

With the old batteries   still installed a voltage interruption of 100 - 150 msec duration was given to the AC input to the DC logic of UPS1C. The DC logic was initially at 19.86 VDC. The unit tripped 3 out of 4 times. This was done first with the loads on

        . xaintenance supply and then also with the loads on       UPS power ~

With the new batteries installed there was no trip when the fast transient test was performed 25 successive times. There were no trips but a repeated SCR short alarm occurred which is indicative of noise spikes within the unit.

page 2 5.)   The K-5   relay drop out was recorded and was found to be below the   trip point of the DC logic power.

6.)   Normal transfers were done, UPS to maintenance and maintenance to UPS, with dead batteries and there were no trips of the UPS. The maintenance supply was opened with the UPS feeding the loads and no UPS trips occurred.

CONCLUSZON This test proves that the   DC logic power is fed by the B phase maintenance   power and that it is susceptible to voltage transients on the maintenance supply. Zt may be susceptible to other transients as well because it is directly tied to maintenance supply. The test DOES NOT prove the level of susceptibility, that is, it does not prove that the transient was of any set voltage or duration.

The test implies that the batteries may have mitigated the trip but is not conclusive.

Each trip circuit was tested successfully so no     failure to any of these occurred that caused the trip.

The fast open/close of the normal AC input breaker proves   that the unit would withstand an AC input transient without failure or without going on battery power.

'5 ~

page  3 Numerical Results:

1.) Fast Transient Tests a.)   W't existin     batteries 1.) With loads on maintenance:

At 19.86 VDC (90.0 VAC) - ~tri           (150 msec.)

At 19.86 VDC (120 VAC) - ~t           '150     msec.)

2.) With loads on     UPS   power:

2 Tries,   1 ~t i   (200 msec.)

b.)   W't new batter'es-1.) Approx. 20.0     VDC - 25   times,

                                                ~no   tri .  (100 msec.   )

2.) The   DC logic trips at   < 16.9 VDC. (with 84.59       VAC   on input).

3.) K-5   relay drop out --  45 VAC K-5   relay pick up         ** not recorded 4.) The   following trips tests     were done:

a.)   OV/UV b.)   ACUV c.)   ACOV d.)   DCUV e.)   Frequency  fail f.)   Logic Failure g )   Power supply failure

: h. ). Clock failure 5.) The   internal battery voltage       was measured:

Positive - +0.6 Negative -   +0.04

4 l ~

5

page  4 5.) Xndividual cell voltages:

Batte  Volta  e New Batte  Volta  e 1.)       1. 19                    6.10 2.)       2.48                      6.07 3.)       2.24                      6.10

: 4. )      0.17                     6.09 5.)      0.79                      6.10 6.)      1.78                      6.12

V -UP   D   S   S page

To prove that the DC logic power for the Exide UPS is powered from the B-phase maintenance supply and that a transient occurs on the maintenance supply   it can if effect the DC logic such that   it will trip the unit.

This test is done with the old internal logic batteries and then repeated with new ones. The K-5 pickup and drop out voltages and the DC trip-point of the DC logic will be recorded.

1.)   It was verified that fed from the B-phase the'C logic maintenance power supplies are supply.

2.)   Fast transient tests; With the old batteries   still installed a voltage interruption of 100 - 150 msec duration was given to the AC input to the DC logic of UPS1D. The DC logic was at 20.9 VDC. The unit would not trip. The AC input voltage to the DC logic was then reduced such that the DC logic was at 20.0 volts. When the test was performed with the DC logic power at 20.0 VDC the unit tripped. This was done first with the loads on maintenance supply and then also with the loads on   UPS power.

With the new batteries installed there was no trip when the fast transient test was performed though there was significant hits shown on the DC logic power bus as seen by the oscilloscope.

3.)   The K-5 relay drop out and pick up voltages were recorded and they were found to be below the trip point

        . of the DC logic power.

4.)   Normal transfers were done, UPS to maintenance and maintenance to UPS, with dead batteries and there were no trips of the UPS. The maintenance supply was opened with the UPS feeding the loads and no UPS trips occurred.

pl lt i1 4i     V

      , ~

page 2 CONC This test proves that the DC logic power is fed by the B phase maintenance power and that it is susceptible to voltage transients on the maintenance supply. It may be susceptible to other transients as well because   it is directly tied to maintenance supply. The test DOES NOT prove the level of susceptibility, that is, it does not, prove that the transient was of any set voltage or duration.

page  3 Numerical Results:

1.) Fast Transient Tests a.) W't e istin       batteries With loads on maintenance:

At 20.9 VDC five tries, no trips.

At 20.7 VDC - one try, one ~tri .          (150 msec.)

2.) With loads on UPS power:

At 20.06 VDC - one ~t '      (100 msec.)

b.)   W't   new batteries 1.) At 20.05   VDC - Five tries, hit

                                                    ~so tri s.

noticeable   DC     on each     transient.

2.) The DC logic trips at   <17.3 VDC. (with 84.5     VAC on   input).

3.) K-5 relay drop out --  42 VDC K-5 relay pick up       55 VDC 4.) The internal battery voltage     was measured:

Positive-       +0.6 Negative-      +0.14         (the negative battery set       was actually slightly positive).

5.) individual cell voltages:

t   V   tae               w Batte       Vo ta e

                .254                                    6 '0 2.)         .570                                    6 '6 3.)       1.03                                       6 ~ 10 4~)          .07                                      6 '0 5.)        1 ~ 17                                    6 '3

6.) 1.39 6 '9

1 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 hour battery pack were available in these a'reas during this event.

The stairwells are provided with essential lighting only except where 8 hour battery pack lighting is added for Appendix R compliance. Illumination to these stairwells was not available due to loss of normal UPS.