Text

ATTACHMENT 1 I MED I ALMO 6 Operating Manual

7. Connector Pin Assignment 7.1. Device View INetwork in preparation Serial --

number 24V power I supply unit LCD contrast Connection for control traffic light / acoustic total alarm A+B Probe connections channel 1 to 6 Connection for traffic light / acoustic channel 1 to 6

[+Interfaces 7.2. Fuses 2.5 ATfuise Main Fuse Fuse total alarm B I Probes 4.5 and 6 AT 1 AT Fuse Fuse total alarm A I Probes 1.2 and 3 AT 1 AT Issue 05/2013 E, Subject to technical modifications without notice Page 59 MED Nuklear-Medizintechnik Dresden GmbH, Dornbluthstrasse 14 a, D-01277 Dresden

ATTACHMENT 1 M F -1)

ALMO 6 Operating Manual 7.3. Connector Pin Assignment Data Transmission A The interface function (configuration) can be set on the menu (see 4.9.4):

USB RS-232 RS-422 RS-485 Pin Signal Pin Signal Pin Signal Pin Signal 1 24 Volt 1 24 Volt 1 24 Volt 1 24 Volt 2 5 Volt - USB 2 2 2 3 3 RX 3 RX-B 3 4 4 TX 4 RX-A 4 5 USB-DM 5 5 TX-B 5 B 6 USB-DP 6 6 TX-A 6 A 7 0 Volt - 7 GND 7 GND 7 GND USB F-51

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ELI __z Socket type: Binder subminiature circular connector Series 712 09-0427-90-07 Cable connector: Series 712 coupler connector 99-0426-00-07 Connection cable: Three pair-wound shielded control line AWG 26 2P x AWG 26C Page 60 Issue 05/2012 E, Subject to technical modifications without notice MED Nuklear-Medizintechnik Dresden GmbH, Domblilthstrasse 14 a, D-01277 Dresden

ATTACHMENT 1 ALMO 6 Operating Manual lm_"" -

7.4. Connector Pin Assignment Data Transmission B The interface function (configuration) can be set on the menu (see 4.9.4):

RS-232 RS-422 RS-485 Pin Signal Pin Signal Pin Signal 1 24 Volt 1 24 Volt 1 24 Volt 2 5 Volt 2 5 Volt 2 5 Volt 3 RX 3 RX-B 3 4 TX 4 RX-A 4 5 5 TX-B 5 B 6 6 TX-A 6 A 7 GND 7 GND 7 GND F51 F-I F2_-

F, Socket type: Binder subminiature circular connector Series 712 09-0427-90-07 Cable connector: Series 712 coupler connector 99-0426-00-07 Connection cable: Three pair-wound shielded control line AWG 26 2P (3P) x AWG 26C Issue 05/2013 E, Subject to technical modifications without notice Page 61 MED Nuklear-Medizintechnik Dresden GmbH, Dornblilthstrasse 14 a, D-0 1277 Dresden

ATTACHMENT 1 iMEV I ALMO 6 Operating Manual 7.5. Connector Pin Assignment Alarm Output Channel 1 - 6 Pin Signal 1 LED light red 2 LED light yellow 3 LED light green 4 LED light common 5 Traffic light red 6 Traffic light yellow 7 Traffic light green 8 Traffic light common / GND *

• If the output is switched potential-free on the menu, the common of the relay is on pin 8.

If 24 Volt is switched at the traffic light outputs, then pin 8: OVolt (ground).

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EL E6 EL2E]

Socket type: Binder subminiature circular connector Series 712 flange type socket 09-0424-90-08 Cable connector: Series 712 coupler connector 99-0421-00-08 Connection cable: LiY 8 x 0.14 I

Page 62 Issue 05/2012 E, Subject to technical modifications without notice MED Nuklear-Medizintechnik Dresden GmbH, Dombltithstrasse 14 a, D-0 1277 Dresden

ATTACHMENT 1 IMED I ALMO 6 Operating Manual 7.6. Connector Pin Assignment Total Alarm Channel A and B Pin Signal 1 External quit button 2 External quit button 3 External acoustic 4 Power supply for Acoustic at potential-free 5 LED traffic light red 6 LED traffic light yellow 7 LED traffic light green 8 Traffic light common / GND *

• If the output is switched potential-free on the menu, the common of the relay is on pin 8.

If 24 Volt is switched at the traffic light outputs, then pin 8: OVolt (ground).

F41 8 L6_

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Socket type: Binder subminiature circular connector Series 712 flange type socket 09-0424-90-08 Cable connector: Series 712 coupler connector 99-0421-00-08 Connection cable: LiY 8 x 0.14 Issue 05/2013 E, Subject to technical modifications without notice Page 63 MED Nuklear-Medizintechnik Dresden GmbH, Dornblithstrasse 14 a, D-0 1277 Dresden

ATTACHMENT 1 ALMO 6 Operating Manual 7.7. Connector Pin Assignment Pulse Input Pin Signal 1 VCC probe 2 Pulse input 3 Probe identification 4 AD identification 5 GND 2

1/2~LF51 Socket type: Binder subminiature circular connector Series 712 flange type socket 09-0428-90-05 Cable connector: Series 712 coupler connector 99-0425-00-05 Connection cable: Special probe cable pulse line shielded Page 64 Issue 05/2012 E, Subject to technical modifications without notice MED Nuklear-Medizintechnik Dresden GmbH, Domrbltthstrasse 14 a, D-01277 Dresden

ATTACHMENT 1 Iin1:1) 1 ALMO 6 Operating Manual 7.8. Connector Pin Assignment Power Supply Pin Signal 1 24 Volt 2 24 Volt 3 GND 4 GND i-]

M Socket type: 3inder subminiature circular connector

eries 712 flange type socket 09-0428-90-04 Cable connector

;eries 712 coupler connector 99-0425-00-04 Connection cable: Vall power supply 24 Volt = 2.3 A Issue 05/2013 E, Subject to technical modifications without notice Page 65 MED Nuklear-Medizintechnik Dresden GmbH, Dornblithstrasse 14 a, D-0 1277 Dresden

ATTACHMENT 1 IMIA) I ALMO 6 Operating Manual

8. Maintenance If used correctly, the instrument does not require any particular maintenance. The only maintenance of the ALMO 6 consists of frequent cleaning of all surfaces from dust and other deposits.

8.1. Accumulator (rechargeable batteries)

In order to check functioning of the rechargeable batteries, monitors with UPS (optional) should be disconnected from the mains once a month for one hour in order to operate with the batteries.

If the rechargeable batteries are unable to last for this time period, they have to be replaced.

In case of (rechargeable) battery operation, a battery symbol is displayed in the lowest line on the display. If the voltage is too low, it is indicated as selected in the menu under 'Error displaylUndervoltage' (see 4.9.5). The instrument is turned off automatically if the voltage is too low.

After max. 2 years, the rechargeable batteries (type AA) have to be replaced by new ones.

Attention! Never use non-rechargeable batteries. The monitor can be destroyed by leaking or boiling batteries.

In case of stocking the instrument for a long time, the rechargeable batteries have to be removed in order to avoid total discharge.

Page 66 Issue 05/2012 E, Subject to technical modifications without notice MED Nuklear-Medizintechnik Dresden GmbH, Dornblifthstrasse 14 a, D-0 1277 Dresden

ATTACHMENT 1 IM ED I ALMO 6 Operating Manual

9. Accessory The instrument is integrated in a plastic console housing. A desktop version and one for wall mounting are available.

As a build-in version, the instrument is supplied in a stainless steel housing.

For installation in a laboratory area with clean room conditions the electronics and the LCD are integrated in an aluminium die-cast housing.

The desired version has to be specified in the order.

Emereency power supply A battery pack for stand-alone power supply is integrated in the housing. The rechargeable batteries (included) are charged during mains operation by intelligent charge control. If you would like to get this version, please indicate this in your order.

Detectors See also chapter 6.2 'Technical Data Probes'.

- Geiger-Muiller counter tubes o Type 18545 CE measuring range 150 nSv/h - 200 gSv/h o Type 18550 CE measuring range 10 pSv/h - 20 mSv/h o Type 18509 CE measuring range 50 pSv/h - 1 Sv/h o Type 18529 CE measuring range 500 pSv/h - 10 Sv/h o Type 18526 D counts during radial radiation approx. 4 cps/ýSv/h

- Nal scintillation detector o 1 x 1.5" Nal scintillation detector; type 25B38 Measuring range BG - 200 gtSv/h o 1.5 x 2" Nal scintillation detector, type 38B51 Measuring range BG - 100 gSv/h o 3 x 3" Nal scintillation detector, type 76B76 (Measured value display in cps)

- Detector holders:

o simple wall holder (plastic element) o secure wall holder with terminal compartment

- Probe cable; length manufactured according to customer specifications.

Issue 05/2013 E, Subject to technical modifications without notice Page 67 MED Nuklear-Medizintechnik Dresden GmbH, Dornbltithstrasse 14 a, D-01277 Dresden

ATTACHMENT 1 IMF1) 1 ALMO 6 Operating Manual Signal tower The signal tower (0 70; IP 54) comes with a maximum of 4 modules.

- Siren element Siren element, 105 dB optional: Volume adjustable, acknowledgeable

- Signal element LED continuous light possible colors: Green Yellow Red Blue The maximum number of controllable color modules is three. You can choose any color combinations and the signal elements can be designed as a flashlight.

The signal tower can be mounted using a wall holder or a table stand.

The dimensions vary depending on the configuration.

Example: Signal light with acoustic module, 3 color modules and wall holder 70 x 310 x 100 mm3 (width x height x depth)

Several signal towers can be operated in parallel.

Signal tower for clean rooms LED signal tower for use in clean rooms (Fraunhofer IPA approval, IP67/69K) and food applications (EHEDG approval); different colors and additional lighting effects adjustable, with integrated, high output buzzer (85 dB)

- Angle or floor or ceiling mounting on plates/devices possible

- A mounting plate is available for installation on ceilings or walls.

Dimensions example:

Angle mounting with mounting plate Angle mounting Floor or ceiling 140 x 500 x 140 mm3 (width x height x depth) mounting Page 68 Issue 05/2012 E, Subject to technical modifications without notice MED Nuklear-Medizintechnik Dresden GmbH, DornblOthstrasse 14 a, D-01277 Dresden

ATTACHMENT 1 IMV,1) 1 ALMO 6 Operating Manual Flashliaht The flashlight LED is available with or without sound.

- Flashlight with sound Dimensions 0 90 mnn, height 80 mm

- Flashlight without sound Dimensions 0 100 mm, height 80 mm Cable to connect the alarm units The length of the connection cable for flashlight and signal towers is manufactured according to customer specifications.

Adapter for network solutions The order, the number of individual devices and the interface types can be mixed as needed. The maximum number of devices (including ALMO 3/6) is 16 and up to 48 probes will be supported.

No adapter is needed to transmit the data via USB and RS-232. However, the maximum length of each RS-232 connection is lOim and that of the USB connection 5m.

The length of the USB connection can be increased by connecting USB repeaters or USB hubs.

- Adapter RS-232 to RS-485 and distributor Since each ALMO has only one interface connect the RS-485 cable must be wired in external cases. The interface is then set to RS-485 (see 4.9.4). The distributor must be in the vicinity of the respective ALMO. The total length of the RS-485 connections should not exceed 500m.

Adapter RS-232 to RS-485

- Adapter RS-232 to RS-422 w Il  !* I No external adapters are needed when using a 5 multiple RS-422 card in the PC. In this case, the ____

interface is set to RS-422 (see 4.9.4). The length of the RS-422 connections may be 500m each.

Issue 05/2013 E, Subject to technical modifications without notice Page 69 MED Nuklear-Medizintechnik Dresden GmbH, Dornbltithstrasse 14 a, D-01277 Dresden

ATTACHMENT 1

[Ul E D ALMO 6 Operating Manual Software

- Software ALMO Connecting several ALMO systems to one central computer system.

A maximum of 48 detectors can be connected to the ALMO systems. The software processes the data centrally and displays them. The software is used for data storage and threshold monitoring. Software on Windows basis including 5 m connection cable (ALMO-PC system). Optionally, the software can be installed and introduction into the software will be provided.

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Page 70 Issue 05/2012 E, Subject to technical modifications without notice MED Nuklear-Medizintechnik Dresden GmbH, Dornblilthstrasse 14 a, D-01277 Dresden

ATTACHMENT 1 ALMO 6 Operating Manual Additional Display ALMO AD 1 The device ALMO AD 1 can be connected as an addition display to an ALMO 6 or ALMO 3. Several ALMO AD 1 can be connected in series. The measured data are supplied by ALMO 6 or ALMO 3. The alarm thresholds are defined in ALMO 6 or ALMO 3.

The setting for the device configuration and alarm assignment for exceeding of the alarm threshold or malfunctions takes place on the menu level. Visual and acoustic warnings are enabled when alarm thresholds are exceeded or if a malfunction occurs. Measuring electronics and display unit are integrated in a plastic housing.

A large LC display is incorporated into the front panel of the housing. The value currently measured by the connected detector is displayed on this LC display.

Additional Probe Display ALMO ZSA The ALMO ZSA system, in connection with the ALMO 6, allows you to display the local dose rate of up to 6 detectors, for example, Geiger-Muiller or Nal detectors. The ALMO ZSA is an additional display unit for the probe measurement values. The ALMO 6 sends the probe data via an interface. Several ALMO ZSA can be operated in connection with the ALMO 6.

Two freely definable alarm thresholds can be defined in the ALMO 6 for each probe. This setting is done on the menu level of the ALMO 6. A visual / acoustic alarm is triggered whenever an alarm threshold is exceeded.

Optionally the device can be equipped with an emergency power supply.

Depending on the connected components (LED traffic light), the ALMO ZSA will continue to work for up to 3 hours3.472222e-5 days <br />8.333333e-4 hours <br />4.960317e-6 weeks <br />1.1415e-6 months <br /> after power failure.

Issue 05/2013 E, Subject to technical modifications without notice Page 71 MED Nuklear-Medizintechnik Dresden GmbH, Domblilthstrasse 14 a, D-01277 Dresden

ATTACHMENT 1 ALMO 6 Operating Manual

10. Service/Customer Service Please call us if you have any questions about the device. We will be happy to assist you.

In case your device is damaged, please return it adequately and safely packed for repair/service to the following address:

MED Nuklear-Medizintechnik Dresden GmbH Service dept. Dtilmen Ostdamm 139 48249 Dflmen Phone: +49 (0)2594-9424-35 Fax: +49 (0)2594-9424-45 E-mail: service@nuklear-medizintechnik.de Homepage: http ://www.nuklear-medizintechnik.de Page 72 Issue 05/2012 E, Subject to technical modifications without notice MED Nuklear-Medizintechnik Dresden GmbH, Dornblilthstrasse 14 a, D-01277 Dresden

ATTACHMENT 1 IM1:D I ALMO 6 Operating Manual

11. EC Declaration of Conformity This is to certify that the following product:

ALMO6 Stationary dose rate meter with the option to connect 6 probes complies with the essential protection requirements as defined in the Council Directive on the approximation of the laws of the Member States with regard to electromagnetic compatibility (89/336/EEC).

The following standards were used to assess the product:

Electrostatic discharge immunity test Base standard: DIN EN 61000-4-2 (12.2001)

DIN EN 61326-1; table A. 1 (10.2006)

- Electromagnetic field immunity test Base standard: DIN EN 61000-4-3 (12.2006)

DIN EN 61326-1; table A. 1 (10.2006)

- Power frequency magnetic field immunity testing Base standard: DIN EN 61000-4-8 (12.2001)

DIN EN 61326-1; table 2 (10.2006)

Radiated disturbance measurements Base standard: DIN EN 55016-2-3 (08.2007)

DIN EN 55011 clase B group 1 (11.2007)

This declaration has been submitted by the manufacturer MED Nuklear-Medizintechnik Dresden GmbH Dornbliithstrasse 14 a D 01277 Dresden Dresden, October 08, 2012 Issue 05/2013 E, Subject to technical modifications without notice Page 73 MED Nuklear-Medizintechnik Dresden GmbH, Dornblitthstrasse 14 a, D-01277 Dresden

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0 ACTIVATED CARBON FILTERS 0130 E

LU

=

Applications: Radioiodines trapping or other toxic gases.

=

Type: Filters for glove boxes and sealed enclosures.

Media: Activated carbon with specific impregnation depending on type of gas to be trapped.

Carbon bed: Layer thickness 36 or 50 mm depending on model, kept settled by compression mattress eliminating any risk of leak.

Case: Stainless steel sheet metal Z2CN18-10.

Gasket: Viton.

C Handle: 1.

.0 Temperature: 80°C maximum in continuous service.

Control: Filter weighing at 100%

Assembly: Filters to be screwed into stainless steel casings.

Unit i asor vapours Actived CarbonThrea volume Dimensins voue tota M3 10x)160 3603.30.00 20 m'/h activated carbon filter 1.1 Radioiedes CA102-02 KIand TEDA 20/200 M62 Viton R35 1 1.2 0.003 1 2 5 thread M62 3.3 RadwjsC A102-02and TEA 50/ 300 YlonR35 E

1.1 Acids WH, HOl, CEXOO02A3 20/130 M62 R35 1.2 3603.30.02 20 m'/h activated carbon filter 130x160 KOHl 2.5thread Viton 0.003 E 360-4.404 50m nh t a vadca boit KOH Viton R3 3.8 J 0/200 M2.

S organic M62 3603.30.04 20m'Ai activated carbon fifter 130x160 LGS048 none 20/102.5thread Viton R35 1.2 0.003 3603.40.06 50m/ ciaedcro i 1- compound,8 7V i2.t;e V~rloioR35 3.8 0.007 C

E Ia.9

-qwcamifi1 CAMFIL FARR - 77/81, boulevard de la R13publique - 92257 La Garenne Colombes Cedex - France Tel. +33 (0)1 46 52 48 00 - Fax +33 (0)1 47 60 17 81 - www.camfilfarr.com a ]

ADSORPTION ATTACHMENT 7 Data Sheet Reference Index Page 3 1 GLOVE BOX FILTER 50 m .h for iodine trapping FP.A.01 53 D 1/1 Article Carbon Airflow/Ap Mounting Gasket Shipping data number volume m 3.h'/Pa 3 L In kg 50/300 3603.40.03 3,3 40/240 Thread M62 x 2,5 Viton R35 0,007 3,8 30/180 Spicifications :

Type : Filters for glove boxes and isolation chambers with hand.

Media: KI + TEDA impregnated carbon for iodine trapping.

Grid: Stainless stell perfored X2CrNi 18-9.

Gasket: Viton R35.

Temperature: 80'C maximum continuous operation.

Control: Weighing Marking: 3 sheets label on the tight plastic bag.

Documentation : Certification from the IRSN institute with charbon efficiency (Epurating ratio >80%

for a relative humidity of 90%)

Applications: Trapping of radio-iodes in the nuclear industry (molecular iodine and methyl-iodine).

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,IaA ,J. CAMFIL T61l. 01.46.52.48.00 [a R6publique-77/81 Bd de- Fax 92257 LA GARENNE COLOMBES CEDEX France

01.47.60.17.81 FPA0153-D

HEGA Filters Disposable,Replaceableor Refillable Adsorbers for the Controlof DangerousGaseous Contaminants A Wholly Owned Subsidiary of Flanders Corporation

ATTACHMENT 8 HE A Fites Tabl ofCnet)

Quality Assurance ................................................ 2 Im portant Message ............................................... 3 Introduction ...................................................... 4 What is a HEGA?

Where are HEGA's Used?

How Does a HEGA Work?

HEGA Selection Desig n ........................................................... 5 Design Considerations Diagram:V-Bed AdsorberApplications V-Bed Adsorbers ................................................. 6 Carbon Adsorbers Residence Time Applications Adsorber Deisgn and Performance Stainless Steel Frame Adsorbers .................................. 7 DMMP -Qualified Adsorbers Adsorber Housings Type IV(V-Bed) Stainless Steel Frame Adsorbers Suggested Specifications Type IVStainless Steel Adsorbers ........ 8 Ordering Information Diagram:Model Number Breakdown Ordering Inform ation .............................................. 9 Type IV (V-Bed) Stainless Steel Adsorbers Chart: Full-Size Gel Seal Adsorbers Chart: Full-Size Gasket Seal Adsorbers Type IV (V-Bed) Stainless Steel Adsorbers - Small Size Chart: Small Size Stainless Steel Gel Seal Adsorbers - Activated Carbon Chart: Small Size Stainless Steel Gasket Seal Adsorbers - Activated Carbon Chart:Small Size Stainless Steel Gel Seal Adsorbers - Nuclear Grade Carbon Chart:Small Size Stainless Steel Gasket Seal Adsorbers - Nuclear Grade Carbon Chart:Small Size Stainless Steel Gel Seal Adsorbers - Whetlerized Carbon Chart:Small Size Stainless Steel Gasket Seal Adsorbers - Whetlerized Carbon Cinersorb ........................................................ 13 Suggested Specifications and Ordering Info for Cinersorb ........... 14 Diagram: Model Number Breakdown Chart: Gel Seal Housings Chart: Gasket Seal Housings Type IITray Carbon Adsorbers ..................................... 17 Type II Tray Carbon Adsorbers Application Suggested Specifications Diagram: Model Number Breakdown Ordering Information for Type IITray Carbon Adsorbers .............. 18 Diagram: Type II Carbon Tray Adsorber Chart: Flanders/CSCType II Tray Adsorber Carbon Sampling Systems ........................................ 19 Carbon Sampling Canisters Radioactive Iodine Performance Test Types of Adsorption Efficiency vs. Penetration Residence Time Capacity Decontamination Factor Design Principles for Filtering Dangerous Chemical Contaminants

ATTACHMENT 8 HE A Fitr NOTICE ... Compliance with installation and operation standards must be met to ensure quality performance.

HEGA filters are factory tested to meet Flanders/CSC does not guarantee that the requirements of IES RP-CC-008- its equipment will operate at 84, "Recommended Practice for Gas the performance levels given on Phase Adsorber Cells." the identification labels or in the HEPA filters are factory tested to meet catalog specifications under all the requirements of IES RP-CCOO1.3 conditions of installation and use, nor for Type A, B, C, D or E filters: does Flanders/CSC guarantee the suitability of its product for the

• Industrial Grade particular end use which may be C'

• Nuclear Grade Laminar Flow Grade Bio/Hazard Grade HEPA contemplated by the buyer.

For best results, it is recommended

• VLSI that the buyer supply complete

• ULPA information about the operating 0 Test results appear on both the filter label and upon the filter carton label.

conditions of the ventilation system to Flanders/CSC for evaluation.

When the system components are An additional quality assurance test report is kept on file and is available on supplied to the buyer or his agent request. for final installation and assembly in the field, it should be under Flanders/CSC recommends that all the supervision of factory trained HEGA and HEPA filters be tested in personnel.

place by qualified personnel to ensure that the Failure to adhere to this recommenda-filters have been correctly installed in tion or failure of the buyer to have the containment housing. filters timely retested and serviced will E2 Flanders/CSC service personnel are available for installations, supervision of installation, testing nullify or limit any warranties which might otherwise apply and may result in a compromised installation.

and certification of compliance to industry and government standards and instruction of the owner's personnel in testing and maintenance procedures.

2

ATTACHMENT 8 Ffwn /E Quality Assurance Any industry that has dangerous process or The Quality Assurance Program at Flanders/

exhaust gases and/or particulates has a vital CSC Corporation has been audited and approved concern for the health and safety of personnel. several times by the Nuclear Utilities Procurement In addition to corporate concern, the United and Inspection Committee, NUPIC. This States Government has dictated that safety committee was established by nuclear electric equipment meet minimum safety standards. Any utilities to ensure that suppliers of goods and equipment sold to meetthese minimum standards services can meet all applicable regulatory and has to be manufactured using accepted Quality quality requirements.

Control procedures.

Flanders/CSC Corporation has developed a Quality Assurance program to assure that the product or service provided meets these Notes:

standards. This program addresses the entire 1 As part of our continuing program to range of Flanders/CSC involvement, including improve the design and quality of all the purchase of raw materials, the shortage of our products, we reserve the right to these raw materials, incorporation of these make such changes without notice or materials into a product or service, testing this obligation.

product or service, and then shipping it to its destination.

2 Flanders/CSC, through its limited warranty, guarantees that the products The program of Flanders/CSC has been audited described herein will meet all many times, and each time the program has specifications agreed to by the buyer been acceptable. An uncontrolled copy of the and the seller.

program manual is available with each request for Quality Assurance information. Like any 3 ASME N509 Nuclear Power Plant Air-dynamic document, the program is continually Cleaning Units and Components.

being revised to include recent issues of standards and specifications in order that 4 ASME N510 Testing of Nuclear Air Flanders/CSC may use the latest state-of-the-Treatment Systems.

art methods inproviding its products and services.

© Copyright 2003 Flanders/CSC Corporation 7013 Hwy 92E - PO Box 3 Bath, NC 27808 3

ATTACHMENT 8 HEA Fites Inroucio What is a HEGA?

To be called a High Efficiency Gas Adsorber " Nuclear Power Plants (HEGA), the adsorber must exhibit a minimum " Cancer Research Laboratories mechanical efficiency of 99.9% when tested in accordance with the Institute of Environmental " Toxicology Laboratories Sciences designation: IES-RP-CC-008-84, " Animal Disease Research Facilities "Recommended Practice for Gas Phase " Chemical Agent Research Facilities Adsorber Cell." In addition, the adsorber must

" Bomb Shelters (CBR) be designed, built, filled and packaged in accordance with the intent of this standard. " Radiopharmaceutical Plants Since HEGA filters are manufactured in several " HVAC Systems different sizes and of several different " Laboratories Using Chemical materials, this standard is not always followed Carcinogens to the letter. It is the intent of the standard and the resulting performance of these adsorbers " Chemical Agent Munitions Disposal that is important. This type of adsorber is not Facilities intended to be used in odor control systems. " Hospital Isolation Suites However, ifthe user needs a very efficient odor " Pharmacological Facilities control system and can justify the higher

• Chemical Process Facilities initial and operating costs, then this type of adsorber will do an excellent job. The following " Military Facilities comparison between an odor control type

• Biological Research Facilities adsorber vs. a HEGA may help:

• Department of Energy Facilities An odor control type adsorber compared to a HEGA is like comparing an ASHRAE type How Does a HEGAWork?

particulate filter to a HEPA. The odor control A High Efficiency Gas Adsorber (HEGA) filters type adsorber (like the ASHRAE type gaseous contaminants from an airstream by particulate filter) has a low efficiency, low adsorbing the contaminants (See Page 19, pressure drop and low cost. On the other "Types of Adsorption"). With a properly designed hand, the HEGA (like the HEPA) has a higher system that includes proper adsorber selection, efficiency, higher pressure drop and higher adsorbent and resident time, any adsorbable cost. Both adsorbers have their place in contaminant can be filtered and contained. (See industry, but because of these major Page 6 for "Adsorber Design and Performance.'

differences they are not usually interchange- Page 20, "Residence Time").

able.

HEGA Selection Where are HEGA's Used?

When designing a system requiring HEGAs, HEGA's are most often used in "containment" consider:

air filtration systems. Containment air filtration systems are very high efficiency systems, used 1. Type: "Cinersorb" (p. 13), Type IV to filter and contain dangerous particulate and/ (V-Bed) (p. 7), or Type II Tray? (p. 17) or gaseous contaminants. Containment systems 2. Type of carbon needed? (p. 6 & 7) are most often designed to treat exhaust air from 3. Residence Time: (See pp. 6 & 20) contaminated spaces, but occasionally are used 4. Need for sample canisters? (See p. 19) in supply and recirculated air systems. Examples of facilities using these systems are:

4

ATTACHMENT 8 HEA Fites Deig Conidraton Design Considerations The following should be considered when 5. An in-place test of both adsorbers and designing a filtration system: HEPA filters is recommended for

1. Any system that filters dangerous nuclear containment systems and is contaminants should incorporate bag-in/ becoming a more frequent requirement bag-out housings to contain the for many critical applications. The contaminated filters and protect purpose of this in-place testing is to "validate" the installed system. The in-maintenance personnel during filter change-out. place test, if required, should be discussed with a Flanders/CSC factory

2. Particulate filtration must be provided representative prior to the selection of upstream of HEGA filters to prevent equipment so the system will be the adsorber from trapping particulates correctly designed to facilitate the test.

and thereby increasing the adsorber's In-place test equipment and service pressure drop. personnel are available from Flanders/

3. Some applications require high CSC to assist in the original installation efficiency or HEPA filters located down- and testing.

stream of the adsorber to collect any fines 6. The filtration system should be (dust which might be contaminated) manufactured under a good quality released from the adsorbent material and assurance program such as one that to act as a backup in case the first addresses all of the basic requirements particulate filter should fail. of ASME NQA-1, "Quality Assurance

4. Filter trains can be easily constructed Program Requirements for Nuclear with any combination of roughing filters, Facilities."

high efficiency filters, HEPA filters and adsorbers (See illustration below).

V-Bed Adsorber Applications From left to right: prefilter, upstream in-place test section, HEPA filter, V-bed adsorber, in-place combination test section, V-bed adsorber, HEPA filter, downstream in-place test section.

5

ATTACHMENT 8 HEA Fites  :-Be Adsorber Carbon Adsorbers Applications Carbon adsorbers use activated or impregnated Type IV (V-Bed) adsorbers are designed for use

/activated carbon as a filtering medium to in Flanders/CSC BF-Series and BG-Series bag-remove gaseous emissions from nuclear, in/bag-out housings for KF-Series and KG-biological and/or chemical process exhaust Series high efficiency side-service housings.

air. Due to the potentially hazardous nature Occasionally they are used in large "front and of their end use, the customer should consult rear loading" built-up banks inside walk-in with Flanders/CSC technical representatives as plenums, but the Type II Tray adsorber is early as possible during the design phase of a usually best suited for that system design.

project to assure proper specifications for the adsorbers and the filtration system. Flanders/ Adsorber Design and Performance CSC personnel have many years experience All units are made with beds of carbon mounted with gas-phase and HEPA filtration systems in a "V" configuration at various depths and and can provide assistance in adsorbent residence times at rated airflow depending upon selection, residence time calculations, and customer requirements. Various grades of system configuration. carbon are available to meet specific removal All units are manufactured in accordance requirements:

with Flanders/CSC's quality assurance Designation A = Activated 8 x 16 mesh program, which meets the requirements of carbon is used to adsorb heavy solvents, ASME-NQA-1, "Quality Assurance Program elemental iodine and most odors. This carbon Requirements for Nuclear Facilities." Flanders/ is specified as follows:

CSC tests each adsorber to insure a minimum The activated carbon shall be coconut shell mechanical efficiency (the percentage of air that base, 8 x 16 mesh and shall have a minimum actually contacts the activated carbon in a carbon tetrachlorideactivity of 60% when tested system without penetrating voids or cracks) of in accordance with ASTM D3467. The carbon 99.9% per IES-RP-CC-008-84, "Recommended shall meet the "base"carbon requirements for Practice for Gas-Phase Adsorber Cells." This nuclear grade carbon.

test of the adsorber's efficiency on test agents is used to determine if the adsorber is properly Designation N = Nuclear grade 8 x 16 mesh manufactured and filled, but not whether it is carbon is specially impregnated activated suitable for a given application. carbon used to adsorb organic radioiodides.

This carbon is specified as follows:

Residence Time The nucleargrade carbon shall be coconut shell Under actual operating conditions, the removal base, 8 x 16 mesh that meets the requirements efficiency (the percentage of containment of *ASMEN509-1996 "Reaffirmed,"Section 5.2.

actually removed by the activated carbon Designation W = Whetlerized 12 x 30 mesh during operation) of an adsorber is determined carbon is specially impregnated activated by the type and amount of contaminant in the carbon used to adsorb toxic warfare gases. This gas stream, the type and amount of adsorbent, carbon is specified as follows:

and the residence time (the time that the gas The activated carbon shall be specially stream is in contact with the carbon). In most impregnated coal base that meets the require-applications, a residence time of 0.125 second ments of Military Standard MIL-C-0013724D.

is sufficient. In other cases, residence time is a critical factor that must be calculated for the specific contaminant. (See p. 20.)

6

ATTACHMENT 8 HE A Fitr:Stils Stee Frm -A. *brs Designation T = ASZM-TEDA (Cooperite) Type IV (V-Bed) Stainless Steel 12 x 30 mesh carbon used to adsorb toxic Frame Adsorbers warfare gases. Performs similar to Whetlerite.

Impregnants do not include chromium. Description The activated carbon shall be specially The Flanders/CSC Type IV (V-Bed) adsorber is impregnated coal base that meets the designed with either 1-inch, 1 3/8-inch or 2-inch requirements of EA-DTL-1704A. thick beds arranged in a V-Bank configuration.

This design allows a high airflow at a relatively Other media available to meet design low pressure drop. Adsorber frames are requirements.

constructed of T-304 stainless steel with T-304 Note: Carbon adsorbers can be "poisoned" by stainless steel perforated screens.

paint fumes and other gases commonly found These adsorbers are designed for use in in many facilities and must be carefully protected Flanders/CSC G-Series, BF-Series and when stored. The customer should consult BG-Series bag-in/bag-out housings, KF-Series the factory representative regarding storage and KG-Series efficiency side-serving housings.

precautions.

These adsorbers are manufactured under DMMP - Qualified Adsorbers stringent quality control procedures. Each Flanders/CSC model numbers adsorber is filled, tested and packaged in

• AF-GG16-62-WSD accordance with IES Designation: RP-8 (IES-RP-CC-008, "Recommended Practice for

• AF-GG1 6-62-TSD Gas Phase Adsorber Cells"). Before shipping,

• AG-GG16-62-WSD each adsorber is tested in accordance with this standard to assure a minimum mechanical

• AG-GG16-62-TSD efficiency of 99.9%.

have been tested and certified for DMMP Qualification at the U.S. Army Armament Munitions and Chemical Command, Aberdeen Proving Grounds.

Adsorber Housings V-Bed carbon adsorbers are manufactured in standard sizes for use in bag-in/bag-out and side-load housings, and are available in both gel seal and gasket seal designs. Flanders/CSC manufactures a complete line of housings for adsorbers and HEPA filters. Contact the factory or your Flanders/CSC representative for complete information on adsorbers and HEPA Type IV Stainless Steel FrameAdsorber filter housings.

Features

- Minimum mechanical efficiency of 99.9%

when tested in accordance with IES Designation: RP-8 (IES-RP-CC-008, "Recommended Practices for Gas-Phase Adsorber Cells"). Higher efficiencies available when required.

7

ATTACHMENT 8 r.HEA Fites Sugete Spcfcain Typ IV StilesSte A. *b

" Designed, manufactured and tested under number . Adsorber frame shall be a Quality Assurance Program that meets the constructed of 14-gauge T-304 stainless steel basic requirements of ASME NQA-1, and have beds that are deep, "Quality Assurance Program Requirements arranged in a V-bank configuration. The filter for Nuclear Facilities:" frame shall be size: " high x " wide

" Available in several standard sizes allowing x " deep, and have a ____(gel/gasket) seal on one side. The rated flow shall be use in standard filter housings.

CFM at approximately _ " w.g.

" Corrosion resistant. pressure drop and second residence

" Can be filled with appropriate adsorbent to time. Adsorber screens shall be perforated 26 capture any adsorbable contaminant. gauge T-304 stainless steel supported by external spacers to prevent distortion during

• Many applications: Treat exhaust air from filling with carbon. Adsorber shall exhibit a safety cabinets, glove boxes and fume minimum mechanical efficiency of 99.9% when hoods, supply air to inhalation labs, etc. tested in accordance with IES-RP-CC-008-84, Suggested Specifications Type IV "Recommended Practice for Gas-Phase Stainless Steel Adsorbers Adsorber Cells." Units shall be designed, manufactured, and tested under a Quality From the tables on Pages 9 - 11, fill in the Assurance Program that meets the requirements blanks for adsorberrequirements. of ASME NQA-1, "Quality Assurance Program Adsorber shall be Flanders/CSC model Requirements for Nuclear Facilities."

Ordering Information: Type IV (V-Bed) Stainless Steel Adsorber Model Number Breakdown (Example)

Adsorber IDMMP Qualified G= Gasket Seal (Leave blank if not required)

F= Gel Seal [Frame Material A

AA -,...... *__* 1 ____... S=Stainless Steelý

/UoUIl I &W.I%llwillll"alI High Wide Deep w ..... -

Adsorbent Material CC6 = 12"x 12"x 5 Tle" I A = Activated Carbon (8 x 16 Mesh)

CC12 = 12"x 12"x 11 Yh" N = Nuclear Grade Carbon (8 x 16 Mesh)

CG12 = 12"x 24"x 11 Yh" W = Whetlerized Carbon (12 x 30 Mesh)

CG16 = 12"x 24"x 16" T = ASZM-TEDA Carbon (12 x 30 Mesh)

GC16 = 24"x 12"x 16" 1=-

GC12 = 24"x 12"x 11 1/2" GG12 = 24"x 24"x 11 '/2" Bed Thickness GG16 = 24"x 24"x 16" 1 = 1" Bed Thickness 1 3/a = I XIs" Bed Thickness GG18 = 24"x 24"x 18" 2 = 2" Bed Thickness Notes:

_n,___ _'_ _....._ -,i I - .. 1 Number of Beds Per Cell 3 = 3 Beds per Cell

1. In the charts on the following pages, pressure drop and weight will vary 4 = 4 Beds per Cell slightly due to variations in carbon particle size distribution and packing 8 = 8 Beds per Cell density. 10 = 10 Beds per Cell

2. Not all model number combinations above are available.

8

ATTACHMENT 8 HE A Fites Orern Inorato Ordering Information: Type IV (V-Bed) Stainless Steel Adsorber Note: A P may vary by +/- 20% due to physical characteristics of the carton. These variations must Full Size Gel Seal Adsorbers be considered when sizing fans.

Model Size Rated Approx. Res. No. of Bed Max. Approx. Approx.

Nummbr HxWxD Flow AP Time Beds Depth Temp. Carbon Ship W w/Gel Seal Channel Net Wt.I

_______ (inches) (CFM) (In. WG-) (sec.) (inches) (Ibs.) (lbs.)

AF-GC12-101-AS 24x12x12114 500 0.90 0.083 10 1 200F 29 92 1

AF-GC12-101-NS 24x12x12 (4 500 0.90 0.083 10 1 2007 32 95 1

AF-GC12-101-WS 24x12x12 /4 500 2.00 0.083 10 1 200F 35 98 1

AF-GC12-101-TS 24x12x12 /4 500 2.00 0.083 10 1 200'F 35 98 AF-GG12-101-AS 24x2412 1 4 1000 0.90 0.083 10 1 200°F 58 153 1

AF-GG12-101-NS 24x24x12 /4 1000 0.90 0.083 10 1 2007F 64 159 1

AF-GG12-101-WS 24x24x12 /4 1000 2.00 0.083 10 1 200"F 70 165 1

AF-GG12-101-TS 24x24x12 /4 1000 2.00 0.083 10 1 200F 70 165 3 3 AF-GG16-81 /8-AS 24x24x16 /4 1000 0.85 0.125 8 13/8 200"F 75 210 3 3 AF-GG16-81 /-NS 24x24x16 /4 1000 0.85 0.125 8 13/8 200"F 80 215 AF-GG16-813/e-WS 24x24x16 3/4 1000 2.10 0.125 8 13/8 200'F 90 225 AF-GG16-813/8-TS 24x24x16 /43 1000 2.10 0.125 8 13/8 200"F 90 225 1

AF-GG12-62-AS 24x24x12 /4 700 1.75 0.125 6 2 200'F 59 162 1

AF-GG12-62-NS 24x24x12 /4 700 1.75 0.125 6 2 200°F 62 165 AF-GG12-62-WS 24x24x12'/4 700 3.90 0.125 6 2 200=F 70 173 AF-GG12-62-TS 24x24x12/4 700 3.90 0.125 6 2 200"F 70 173 3

AF-GG16-62-AS 24x24x16 /4 1000 1.75 0.125 6 2 200"F 79 205 3

AF-GG16-62-NS 24x24x16 /4 1000 1.75 0.125 6 2 200°F 86 212 3

AF-GG16-62-WS 24x24x16 /4 1000 3.90 0.125 6 2 200F 98 224 3

AF-GG16-62-WSD 24x24x16 /4 1000 3.90 0.125 6 2 200*F 100 226 3

AF-GG16-62-TS 24x24x16 /4 1000 3.90 0.125 6 2 200*F 98 224 AF-GG16-62-TSD 24x24x16 3/4 1000 3.90 0.125 6 2 200*F 100 226 3

AF-GG18-62-AS 24x24x18 /4 1250 1.75 0.125 6 2 200°F 90 225 3

AF-GG18-62-NS 24x24x18 /4 1250 1.75 0.125 6 2 200°F 96 231 3

AF-GG18-62-WS 24x24x18 /4 1250 4.10 0.125 6 2 200"F 105 240 3

AF-GG18-62-TS 24x24x18 /4 1250 4.10 0.125 6 2 200°F 105 240

/ 5 -0 02 - 2 -

9

ATTACHMENT 8 HEA Fites Orern Inoration Ordering Information: Type IV(V-Bed) Stainless SteelAdsorber Note: A P may vary by +/- 20% due to physical characteristics of the carton. These variations must Full Size Gasket Seal Adsorbers be considered when sizing fans.

Model Size Rated Approx. Res. No. of Bed Max. Approx. Approx.

Number H xW x D Flow AP Time Beds Depth Temp. Carbon Ship Wt.

Net Wt.

(inches) (CFM) (In. W, .) (sec.) (inches) (lbs.) (lbs.)

1 AG-GC12-101-AS 24x12x11 /2 500 0.90 0.083 10 1 200*F 29 89 1

AG-GC12-101-NS 24x12x11 /2 500 0.90 0.083 10 1 200°F 32 92 1

AG-GC12-101-WS 24xl2xll 2 500 2.00 0.083 10 1 200*F 35 95 1

AG-GC12-101-TS 24x12x11 /2 500 2.00 0.083 10 1 200'F 35 95 AG-GG12-101-AS 24x24x111 2 1000 0.90 0.083 10 1 200'F 58 148 1

AG-GG12-101-NS 24x24x11 /2 1000 0.90 0.083 10 1 200'F 64 154 1

AG-GG12-101-WS 24x24x11 12 1000 2.00 0.083 10 1 200*F 70 160 1

AG-GG12-101-TS 24x24x11 2 1000 2.00 0.083 10 1 200-F 70 160 3

AG-GG16-81 /8 -AS 24x24x16 1000 0.85 0.125 8 1 /8 200*F 75 205 3

AG-GG16-81 /8-NS 24x24x16 1000 0.85 0.125 8 13/8 200*F 80 210 AG-GG16-81 3/8-WS 24x24x16 1000 2.10 0.125 8 13/8 200*F 90 220 3

AG-GG 16-81 /8-TS 24x24x16 1000 2.10 0.125 8 13/8 200*F 90 220 AG-GG12-62-AS 24x24x111/2 700 1.75 0.125 6 2 200'F 59 157 1

AG-GG12-62-NS 24x24x11 /2 700 1.75 0.125 6 2 200'F 62 160 1

AG-GG12-62-WS 24x24x11 /2 700 3.90 0.125 6 2 200'F 70 168 AG-GG12-62-TS 24x24x111 /2 700 3.90 0.125 6 2 200*F 70 168 AG-GG 16-62-AS 24x24x16 1000 1.75 0.125 6 2 200'F 79 200 AG-GG16-62-NS 24x24x16 1000 1.75 0.125 6 2 200'F 86 207 AG-GG16-62-WS 24x24x16 1000 3.90 0.125 6 2 200"F 98 219 AG-GG16-62-WSD 24x24x16 1000 3.90 0.125 6 2 200*F 100 221 AG-GG16-62-TS 24x24x16 1000 3.90 0.125 6 2 200'F 98 219 AG-GG16-62-TSD 24x24x16 1000 3.90 0.125 6 2 200*F 100 221 AG-GG18-62-AS 24x24x18 1250 1.75 0.125 6 2 200*F 90 220 AG-GG18-62-NS 24x24x18 1250 1.75 0.125 6 2 200OF 96 226 AG-GG18-62-WS 24x24x18 1250 4.10 0.125 6 2 200*F 105 235 AG-GG18-62-TS 24x24x18 1250 4.10 0.125 6 2 200'F 105 235 10

ATTACHMENT 8 HEA Fites ordrin Infomaio Ordering Information: Type IV (V-Bed) Stainless Steel Adsorber Small Size Adsorbers Note: A P may vary by +/- 20% due to physical characteristics of the carton. These variations must be considered when sizing fans.

Ordering information below is for small size gel and gasket seal adsorbers, grouped by adsorbent materials (Activated Carbon, Nuclear Grade Carbon, Whetlerized Carbon and ASZM-TEDA Carbon).

Small Size Stainless Steel Gel Seal Adsorbers - Activated Carbon Model Size Rated Approx. Res No. of Bed Max. Approx. Approx.

Numbe~r Hx2W xD Flow AP Time Beds Depth Temp. Carbon Ship W]

w~ithGelSalChannelNt t

_____ (inches) (CFMf) (In- WG.) (sec.) (inches) (lbs.) Olbs.)

AF-BB6-41-AS 8x 8x 65/8 40 0.45 0.083 4 1 2007F 3 16 3

AF-CC6-41 /8-AS 12x12x 61/e 55 0.90 0.125 4 13/8 200"F 8 33 AF-CC12-413 /e-AS 12x12x12 1/4 140 1.10 0.125 4 13/ 200*F 14 53 3 3 AF-CC16-41 /8-AS 12x12x16 /4 465 0.85 0.125 4 11/% 200"F 45 124 Small Size Stainless Steel Gasket Seal Adsorbers - Activated Carbon Mode Sz Rate Approx. Re.# No. of Bed Max. Approx. Approx.

Number KzW xD Flow AP Time Beds Depth~ TemTp. Carbon Ship Wt.

_______ (kinches) (CFM) (in. WG.) (sec.) (inches) (lbs.) (lbs.)

7 AG-BB6-41-AS 8x8x5 1e 40 0.45 0.083 4 1 200*F 3 15 3 7 AG-CC6-41 /8-AS 12x12x5 1/ 55 0.90 0.125 4 13/8 200'F 8 31 3 1 AG-CC12-41 /8-AS 12x12x11 /2 140 1.10 0.125 4 13/8 200"F 14 51 AG-CG16-413 /8-AS 12x24x16 465 0.85 0.125 4 13/8 200°F 45 121 11

ATTACHMENT 8 HE A Fites Orern Inorato Small Size Stainless Steel Gel Seal Adsorbers - Nuclear Grade Carbon Model Size Rated Approx. Res. No. of Bed Max. Approx. Approx.

Number H xW xD Flow ftP Time Beds Depth Temp. Carbon Ship Wt.

wI Gel Seal Channel Net Wt.

(inches) (CFM) (In. W.G.) (sec.) (inches) (lbs.) (Ibs.)

AF-BB6-41-NS 8x 8x 65/8 40 0.45 0.083 4 1 200°F 3 16 3

AF-CC6-41 /8-NS 12xl2x 65/8 55 0.90 0.125 4 13/8 200'F 8 33 3 1 AF-CC12-41 /8-NS 12x12x12 /4 140 1.10 0.125 4 1% 200*F 15 54 3

AF-CC16-41 /8-NS 12x12x163 /4 465 0.85 0.125 4 1138 200°F 48 127 Small Size Stainless Steel Gasket Seal Adsorbers - Nuclear Grade Carbon Model Size Rated Approx. Res. No. of Bed Max. Approx. Approx.

Number HxWxD Flow AP Time Beds Depth Temp. Carbon Ship Wt.

Net Wt.

(inches) (CFM) (In. WG.) (sec.) (inches) (Ibs.) (lbs.)

AG-BB6-41-NS 8x 8x 57/8 40 0.45 0.083 4 1 2000F 3 15 3

AG-CC6-41 /8-NS 12x12x 57/8 55 0.90 0.125 4 13/8 200°F 8 31 3 1 AG-CC12-41 /8-NS 12x12x11 /2 140 1.10 0.125 4 13/8 200OF 15 52 3

AG-CG16-41 /8-NS 12x24x16 465 0.85 0.125 4 13/8 200'F 48 124 Small Size Stainless Steel Gel Seal Adsorbers - Whetlerized Carbon Model Size Rated Approx. Res. No. of Bed Max. Approx. Approx.

Number H xW x D Flow AP Time Beds Depth Temp. Carbon Ship Wt.

w/ Gel Seal Channel Net Wt.

(inches) (CFM) (In. WG.) (sec.) (inches) (Ibs.) (lbs.)

AF-BB6-41-WS 8x 8x 65/8 40 1.00 0.083 4 1 200'F 4 17 3

AF-CC6-41 /8-WS 12x12x 6 58 55 2.10 0.125 4 13/8 200'F 9 34 3

AF-CC12-41 /8-WS 12x12x12/4 140 2.10 0.125 4 13/8 200"F 16 55 3 3 AF-CC16-41 /8-WS 12x12x16 /4 465 2.10 0.125 4 1138 200'F 50 129 Small Size Stainless Steel Gasket Seal Adsorbers -Whetlerized Carbon Model Size Rated Approx. Res. No. of Bed Max. Approx. Approx.

Number HxWxD Flow AP Time Beds Depth Temp. Carbon Ship Wt.

Net Wt.

(inches) (CFM) (In. WG.) (sec.) (inches) (lbs.) (lbs.)

AG-BB6-41-WS 8x 8x 51/8 40 1.00 0.083 4 1 200'F 3 15 3

AG-CC6-41 /8-WS 12x12x 57/8 55 2.10 0.125 4 13/8 200'F 8 31 AG-CC12-413/8-WS 12x12x11 1

/2 140 2.10 0.125 4 13/8 200'F 15 52 AG-CG16-413/8-WS 12x24x16 465 2.10 0.125 4 13/8 200'F 48 124 12

ATTACHMENT 8 A AN Cinersorb: IncineratableHigh Efficiency Gas Adsorber The Cinersorb is the solution to problems associated with the disposal of carbon adsorbers contaminated with toxic, carcinogenic, microbiological, radioactive or other dangerous contaminants.

Many facilities have a waste disposal problem regarding high-efficiency adsorbers that are loaded with dangerous contaminants. In the past, high-efficiency adsorbers (i.e.. adsorbers that exhibit a mechanical efficiency of 99.9%)

have been manufactured with metal frames.

Since these metal frame adsorbers cannot Incineration guidelines vary from contaminant always be safely refilled with fresh carbon, their to contaminant. The customer should determine disposal becomes a problem. that incineration meets the requirements The Flanders/CSC Cinersorb, which has a governed by type of contaminant in question and combustible frame constructed of high impact local regulations.

polystyrene plastic, solves this problem.

Features

• Polystyrene frame allows disposal by

• Designed, manufactured and tested under incineration (volume reduction exceeds a Quality Assurance Program that meets the 95%) requirements of ASME-NQA-1, "Quality

• Mechanical efficiency of 99.9% when tested Assurance Program for Nuclear Facilities" in accordance with IES-RP-CC-008-84, "Recommended Practice for Gas-Phase Adsorber Cells"

" Available in many sizes (See pp. 15-16),

allowing use in most standard filter housings

" Easier to handle, weighs 40 to 50% less than metal frame adsorbers

" Less expensive than metal frame adsorbers

• Corrosion resistant

• Can be filled with any adsorbent to capture almost any contaminant

" Many applications, including safety cabinet, glove box and fume hood exhaust, laboratory supply air and odor control 13

ATTACHMENT 8 HEA Fites Suggested Spcfcain an Orern.- ointo fo. Ci.

• Suggested Specifications Cinersorb Disposable Carbon Adsorbers From the tables on Pages 15-16, fill in the blanks for adsorberrequirements.

Adsorber shall be Flanders/CSC model pressure drop and second residence number . Adsorber frame shall be time. Adsorber screens shall be perforated constructed of high impact polystyrene to allow plastic supported by external spacers to prevent disposal of spent adsorber by incineration. distortion during filling with carbon. Adsorber Adsorbers shall have beds that are shall exhibit a minimum mechanical efficiency deep, arranged in a V-bank configuration. of 99.9% when tested in accordance with The filter frame shall be size: " high IES-RP-CC-008-84, "Recommended Practice for x " wide x " deep, and have a Gas-Phase Adsorber Cells."

(gel/gasket) seal on one side. The rated flow shall be CFM at _"w.g.

Model Number Breakdown (Example)

Adsorber jLrame G= Gasket Seal]

F= Gel Seal 1Frame Material

= P la s tic 1A k _Q_ _ _ _ _ _P Hiah Wide Deed Adsorbent Material CC12 = 12"x 12"x 11 1/2" A = Activated Carbon (8 x 16 Mesh)

CG16 = 12"x 24"x 16 N = Nuclear Grade Carbon (8 x 16 Mesh)

GC16 = 24"x 12"x 16" W = Whetlerized Carbon (12 x 30 Mesh)

GC12 = 24"x 12"x 11 1/2" T = ASZM-TEDA Carbon (12 x 30 Mesh)

GG12 = 24"x 24"x 11 1/2" GG16 = 24"x 24"x 16" Bed Thickness GG18 = 24"x 24"x 18" I = 1" Bed Thickness I Y/e= I D/e" Bed Thickness 2 = 2" Bed Thickness Number of Beds Per Cell 3 = 3 Beds per Cell 4 = 4 Beds per Cell 8 = 8 Beds per Cell 10 = 10 Beds per Cell 12-= 12 Beds per Cell Iii 711 Notes:

1. In the charts on the following pages, pressure drop and weight will vary slightly due to variations in carbon particle size distribution and packing density.

2. Not all model number combinations above are available.

14

ATTACHMENT 8 Ordering Information: CinersorbDisposableCarbonAdsorber These adsorbers are designed as disposable above 1200 F or if contaminants will attack the units. DO NOT refill with fresh carbon for reuse. polystyrene plastic frame material.

NOT recommended for use in systems Note: A P may vary by +/- 20% due to physical characteristics of the carton. These variations must Gel Seal Housings be considered when sizing fans.

Model Size Rated Approx. Res. No. of Bed Max. Approx. Approx.

Number H xW xD Flow AP Ti me Beds Depth Temp. Carbon Ship Wit.

wlothGlSeal Chane Not Wit.

______ (inches) (CFM) (in. W. .) (sec.) (inches) (1bs.) (lbs.)

AF-GC12-101-AP 24x12x12'/4 500 0.90 0.083 10 1 1207F 23 92 1

AF-GC12-101-NP 24x12x12 14 500 0.90 0.083 10 1 1207F 25 95 AF-GC12-101-WP 24x12x12l14 500 2.00 0.083 10 1 120°F 26 98 AF-GC12-101-TP 24x12x12l/4 500 2.00 0.083 10 1 120-F 26 98 1

AF-GG12-101-AP 24x24x12 /4 1000 0.90 0.083 10 1 120F 43 153 AF-GG12-101-NP 24x24x12l1a 1000 0.90 0.083 10 1 120"F 49 159 1

AF-GG12-101-WP 24x24x12 /4 1000 2.00 0.083 10 1 120"F 52 165 1

AF-GG12-101-TP 24x24x12 14 1000 2.00 0.083 10 1 120"F 52 165 AF-GG12-62-AP 24x24x12 1/4 700 1.75 0.125 6 2 200"F 59 162 1

AF-GG12-62-NP 24x24x12 14 700 1.75 0.125 6 2 200F 59 162 3 3 AF-GG16-81 /8-AP 24x24x16 14 1000 0.85 0.125 8 13/8 120F 74 113 3 3 AF-GG16-81 /8-NP 24x24x16 /4 1000 0.85 0.125 8 13/8 1207F 79 118 3

AF-GG16-81 %-WP 24x24x16 /4 1000 2.10 0.125 8 1% 120F 88 127 3

AF-GG16-81%-TP 24x24x16 /4 1000 2.10 0.125 8 13/8 1207F 88 127 AF-GG16-121-AP 24x24x16 3/4 1000 .5 0.125 12 1 120F 120 78 3

AF-GG16-121-NP 24x24x16 /4 1000 .5 0.125 12 1 120'F 120 78 3

AF-GG16-62-AP 24x24x16 14 1000 1.75 0.125 6 2 120*F 80 115 3

AF-GG16-62-NP 24x24x16 /4 1000 1.75 0.125 6 2 120'F 84 119 3

AF-GG16-62-WP 24x24x16 /4 1000 3.90 0.125 6 2 120*F 96 131 AF-GG16-62-TP 24x24x16 3/4 1000 3.90 0.125 6 2 120*F 96 131 3

AF-GG18-62-AP 24x24x18 /4 1250 1.75 0.125 6 2 1207F 79 127 3

AF-GG18-62-NP 24x24x18 /4 1250 1.75 0.125 6 2 120°F 86 131 3

AF-GG18-62-WP 24x24x18 14 1250 4.10 0.125 6 2 120°F 98 140 3

AF-GG18-62-TP 24x24x18 /4 1250 4.10 0.125 6 2 120*F 100 140 15

ATTACHMENT 8 HE A Fites Orerin Inomto

• fo -ro Ordering Information: CinersorbDisposable CarbonAdsorbers Note: A P may vary by +/- 20% due to physical characteristics of the carton. These variations must be considered when sizing fans.

Gasket Seal Housings Model Size Rated Approx. Res. No. of Bed Max. Approx. Approx.

Number H xW x D Flow AP Time Beds Depth Temp. Carbon Ship Wt.

Net Wt.

(inches) (CFM) (In. WG.) (sec.) (inches) (Ibs.) (lbs.)

AG-GC12-101-AP 24x12x11 1/2 500 0.90 0.083 10 1 1207F 23 42 AG-GC12-101-NP 24x12x11'1/2 500 0.90 0.083 10 1 1207F 25 44 AG-GC12-101-WP 24x12x111/2 500 2.00 0.083 10 1 120F 26 45 AG-GC12-101-TP 24x12x111/2 500 2.00 0.083 10 1 120*F 26 45 AG-GG12-101-AP 24x24x111/2 1000 0.90 0.083 10 1 120°F 43 77 1

AG-GG12-101-NP 24x24x11 /2 1000 0.90 0.083 10 1 120*F 49 83 1

AG-GG12-101-WP 24x24x11 /2 1000 2.00 0.083 10 1 120'F 52 86 1

AG-GG12-101-TP 24x24x11 /2 1000 2.00 0.083 10 1 120'F 52 86 AG-GG12-62-WP 24x24x11 1/2 700 1.75 0.125 6 2 200°F 59 162 AG-GG12-62-TP 24x24x111/2 700 1.75 0.125 6 2 200'F 59 162 3

AG-GG16-81 /8-AP 24x24x16 1000 0.85 0.125 8 11/8 120"F 74 113 3

AG-GG16-81 /8-NP 24x24x16 1000 0.85 0.125 8 1V/8 120'F 79 118 3

AG-GG 16-81 /8-WP 24x24x16 1000 2.10 0.125 8 13/8 120"F 88 127 3

AG-GG16-81 /8-TP 24x24x16 1000 2.10 0.125 8 13/8 120'F 88 127 AG-GG16-121-AP 24x24x16 1000 0.5 0.125 12 1 120'F 120 78 AG-GG16121-NP 24x24x16 1000 0.5 0.125 12 1 120'F 120 78 AG-GG16-62-AP 24x24x16 1000 1.75 0.125 6 2 120"F 80 115 AG-GG16-62-NP 24x24x16 1000 1.75 0.125 6 2 120'F 84 119 AG-GG16-62-WP 24x24x16 1000 3.90 0.125 6 2 1207F 96 131 AG-GG16-62-TP 24x24x16 1000 3.90 0.125 6 2 120*F 96 131 AG-GG18-62-AP 24x24x18 1250 1.75 0.125 6 2 120F 92 127 AG-GG18-62-NP 24x24x18 1250 1.75 0.125 6 2 120F 96 131 AG-GG18-62-WP 24x24x18 1250 4.10 0.125 6 2 120F 105 140 AG-GG18-62-TP 24x24x18 1250 4.10 0.125 6 2 120*F 105 140 16

ATTACHMENT 8 HEG Fites Typ // Tra Cabo Adob Type IITray Carbon Adsorbers The Flanders/CSC Type II adsorber meets the design and performance criteria of IES-RP-CC-008-84, "Recommended Practice for Gas-Phase Adsorber Cell.' It is primarily used by the nuclear industry. The Flanders/CSC Type II cell exhibits a minimum mechanical efficiency of 99.9% when tested in accordance with that standard.

The Flanders/CSC Type II cell incorporates two 2-inch beds. Three cells are designed to be modular with a 1000 CFM HEPA filter in both flow rate and size. By using multiple Type II cells, any required flow rate can be obtained. StandardType IITray CarbonAdsorber The Flanders/CSC Type II cell is made of AG-1-1997, "Code on Nuclear Air and Gas 300-Series stainless steel. Dimensions are Treatment.' At a rated flow of 333 CFM each maintained to assure conformance with shall provide a 0.25 second residence time with the requirements of IES-RP-CC-008-84, an approximate pressure drop of 1.10" water "Recommended Practice for Gas-Phase gage. Approximate filled weight of the adsorber Adsorber Cells." It is designed, manufactured is 96 lbs. with a maximum operating tempera-and tested under a quality assurance program ture of 2000 F. The adsorber shall exhibit a that meets the basic requirements of ASME mechanical efficiency of 99.9% when tested NQA-1, "Quality Assurance Program Require- in accordance with IES-RP-CC-08-84, ments for Nuclear Facilities." "Recommended Practice for Gas-Phase Adsorber Cells." The adsorber shall be Application designed, manufactured and tested under a Type IITray adsorbers are designed so that three Quality Assurance Program that meets the cells in parallel are modular with a 1000 CFM basic requirements of ASME NQA-1, "Quality HEPA filter. These adsorbers are primarily used Assurance Program Requirements for Nuclear by the nuclear industry. They are usually Facilities."

installed in large "built-up" banks inside walk-in plenums.

Suggested Specifications Model Number Breakdown (Example)

Adsorber shall be Flanders/CSC V-2 Type II AG- -30 adsorber tray. The adsorber frame shall be constructed of Type 304 stainless steel and have Adsorber 30" Tray Length two (2), 2-inch deep beds. Adsorber screens Gasket Seal shall be perforated 26 gage Type 304 stainless steel (0.045" dia. holes, 37% open area) with Type IITray external reinforcement to prevent distortion Adsorber during filling with carbon. The adsorber shall be filled with 8 x 16 mesh, granular, activated, impregnated carbon that meets the requirements of Article FF-5000 of ASME/ANSI 17

ATTACHMENT 8 HEA Fites Orern Inomto fo Typ Tra Carbon A....be Ordering Information: Type II Tray CarbonAdsorber Flanders/CSC Type IITray Adsorber Rated Flow Velocity Mechanical Bed AP Approx. Approx.

through Efficiency Depth Filled Wt. Ship Wt.

(CFM) Carbon Bed (inches W.G.) (lbs.) (lbs.)

333 40 ft/minute 99.9% 2 inches 0.25 sec. 0.90 (+/-0.30) 105 Standard Options: Note: Flanders/CSC's Service Division can refill and recertify most types of High Efficiency 1 Different length cells Gas Adsorbers.

2 Special frame materials 3 Special adsorbents 4 Special faceplate 5 Sample canisters 6 Custom sizes 18

ATTACHMENT 8 HE A Fites - a. - ~amn Sysem Carbon Sampling Canisters Radioactive Iodine Performance In nuclear applications, *US Reg. Guide 1.52 Test details the frequency of having carbon tested Flanders/CSC can provide radioiodine testing for ability to remove methyl iodide. The sampler services on samples of carbon to determine if devices shown simplify the sample taking the samples meet customer specifications. Tests procedure. The sampler is removed, the can be expedited to prevent extended downtime sampler space is blanked off, and the sample is of the customer's air filtration system. Tests are sent to the lab for analysis. No in-place test is performed to latest versions of ASTM-D3803, required. (Note: If a filter is removed to provide ASME N509 and ASME AG-1; but, any a sample, an in-place test must be performed standard radioiodine testing can be performed.

after the filter is replaced.) Customer can also specify custom test Existing systems can use the compatible parameters, if required.

Flanders/CSC sampling system for easy *US Nuclear Regulatory Commission Regulatory Guide 1.52, "Design, Testing and Maintenance Criteria for Post Accident conversion. Engineered-Safety-Feature Atmosphere Cleanup System Air Filtration and Adsorption Units of Light-Water-Cooled Nuclear Power Plants."

Types of Adsorption There are three types of adsorption that concern us: 1. Kinetic, 2. Isotopic Exchange, and 3. Complexing or Chemisorption.

Carbon 3ampler Blank Off Plug and Canister/PlugRemoval Tool (furnished) Kinetic: Kinetic adsorption of a gas molecule or chemical vapor is the physical attraction of the molecule to the carbon granule by electrostatic forces. These forces, as they apply to small particles, are governed by van der Waals theories, and these attraction forces are termed van der Waals forces. Since these forces are physical in nature, the forces can be undone by physical effort. Thus, high temperature, high humidity, or other natural causes may cause an adsorbed contaminant to desorb.

Generally, the higher the boiling point, the larger the molecule size, and the lower the melting temperature, the easier the molecule is to kinetically adsorb and the stronger it is held once it is adsorbed.

Isotopic Exchange: A second "adsorption" mechanism is isotopic exchange. Radioactive materials usually have a family of isotopes. If a stable isotope is adsorbed on the carbon initially, an unstable isotopic compound will, when it comes into contact with the stable form of the element, exchange the isotopes. The 19

ATTACHMENT 8 HE A Fites Cabo Sapln Sytm stable form is now on the airborne molecule and Efficiency is the ability for the carbon to remove the radioactive form is on the molecular a desired contaminant. Methyl iodide efficiency, structure of the impregnant. An example of this for example, is determined by challenging the is carbon impregnated with K13. The radioactive carbon with an actual radioactive methyl iodide form of iodine in the organic form CH 31131 will vapor. The amount of the contaminant upstream isotopically exchange with the iodine on the of the carbon is known, and the amount that is carbon. This exchange is nondirectional, collected on backup beds is measured. The meaning the adsorbed (exchanged) radioactive efficiency of that carbon sample to remove species of iodine may very well exchange methyl iodide is easily calculated by comparing again. The result will be a different airborne the counts of the carbon sample to the counts radioactive methyl iodide molecule. This new on the backup beds. Test parameters such as radioactive molecule may again isotopically temperature and relative humidity greatly affect exchange with stable iodides on the carbon the efficiency.

in the K13 impregnant, and so on, until the Penetration, on the other hand, is a term used radioactive iodine is delayed long enough to to indicate the degree of leak tightness for decay into stable xenon. installed carbon systems. The installed system Complexing or Chemisorption: A third is subjected to a test gas that is easily adsorbed, capture mechanism is chemisorption. This is such as R-1 1 (trichlorofluoromethane). The the actual complexing, attaching chemically, of penetration, or by-pass of the R-11, is measured a radioactive iodine species to a stable downstream of the filter and that amount is impregnant that has the ability to share compared to the amount measured upstream electrons. Once the iodine is complexed, it does of the filter. A penetration value in percent is NOT desorb similarly to isotopic exchange. easily calculated from the collected data. This However, it may desorb similarly to the kinetic is also termed mechanical efficiency.

adsorption discussed. But if it does, the entire impregnant desorbs from the carbon, not just the iodine. An example of this is to impregnate the carbon with triethylenediamine (TEDA) or some other tertiary amine.

To take advantage of both impregnants and capture mechanisms, carbon can be co-impregnated. This allows the carbon to be used as a kinetic adsorber, an isotopic exchange medium and a complexing agent.

As long as the operating conditions are kept within normal bounds, the carbon will perform Residence Time as required. It will perform under high humidity Residence time is the term given to the time that conditions and under high temperature a gas stream contacts a carbon bed. For conditions better than a carbon with a single example, if a carbon bed were a foot thick and impregnant. the air stream moved at one foot per minute, Efficiency vs. Penetration the residence time would be one minute. Itwould take one minute for the air to move through the There is often confusion between "efficiency" bed.

and "penetration" of contaminants through a Typically, the carbon bed is 1-inch thick and the carbon bed.

air velocity is 40-feet per minute. What would 20

ATTACHMENT 8 HE A Fites eebnamln System the residence time be in that situation? (0.125 RT= 5x2 seconds) The residence time can be calculated 80 easily from the following relationships:

RT=5 xD RT: 10 80 V

Where:

RT = 0.125 second RT = Residence time (seconds)

D = Depth of carbon bed (inches)

The concept of residence time is very important V = Velocity of gas through bed (feet/min) from the designer's point of view. That is why Most of the time, the velocity will not be given Flanders/CSC is taking a lot of time to explain it and must be calculated from the relationship: fully. Flanders/CSC cannot design a system V= Q unless we know either the actual residence time required, or all of the parameters that determine A the optimum residence time, (flow rate, contami-Where: nants, concentrations, temperature, humidity, required efficiency, etc.)

V = Velocity of gas through bed (feet/min)

The residence time is critical to the chemisorp-A = Unbaffled area of carbon bed (sq.ft) tion or complexing phenomena. As the gas Q =Quantity of gas flowing through bed enters the bed, it must have time to interact with (CFM) the impregnants on the carbon. Too little time will mean that the contaminants will not interact Let's take an example from real life: Assume completely with the carbon or impregnants. Too that Q=1,000 CFM and that a single 6 panel, much time means that the system is not de-16-inch deep (in direction of air flow), 2-inch bed signed efficiently.

depth filter is to be used. To calculate the residence time, first determine the area of the In summary, you need to be aware of the carbon bed. The total area is 12.5 sq. ft. The important of residence time because the first 12.5 ft2 is determined by actual measurements question we ask about an inquiry for any of the unbaffied bed area on one side of the carbon system is, "What is the residence time carbon filter. Therefore: requirement?" If you do not know, we will have to determine it before the best system can be designed by our engineering staff.

A Capacity V= 1000 CFM The capacity of activated carbon is the 12.5 ft percentage of its own weight that an activated carbon can adsorb of a given vapor under V = 80 ft/min certain conditions. Some of these conditions And: are vapor concentration, temperature, humidity, air velocity, and defined breakthrough.

RT= 5xD V Example: If 100 pounds of activated carbon adsorbs 15 pounds of benzene before it reaches 21

ATTACHMENT 8 HEA Fitr an Fite Tetig Cabo Sapln System a customer defined breakthrough point of 5 ppm, 2. Carbon filters must:

then the capacity of that activated carbon for a Exhibit a minimum mechanical benzene is 15%.

efficiency of 99.9% (i.e., HEGA).

Decontamination Factor b Use high quality coconut shell The Decontamination Factor is the ratio of the activated carbon.

concentration of a contaminant in the untreated c Be sized for approximately 0.125 air to the concentration of the contaminant in second residence time.

the treated air.

3. All filters should be installed in "Bag-in/

If anyone asks what the Decontamination Bag-out" housings to protect main-Factor (DF) of a filter is, the answer can be te nance personnel and the environment.

obtained by calculating the RECIPROCAL of the penetration expressed as a fraction, or 4. Filtration system designs should have provisions for pulling samples of air or DF = 1 carbon for laboratory analysis (to assist Pen. in determining when carbon adsorbers Examples: need changing).

5. The disposal of hazaradous waste (i.e.,

spent HEPA and HEGA filters) should Penetration Calculation Result also be considered. Any HEPA or HEGA 40% DF = 1 DF = 2.5 filter containing regulated chemicals 0.40 should be disposed of in accordance with Federal, State and local restrictions.

6. The filtration system must be manufac-0.1% DF = 1 DF = 1,000 tured under a good quality control 0.001 program such as one that addressed the requirements of ASME NQA-1, "Quality Assurance Program Requirements for 5% DF = 1 DF = 20 Nuclear Facilities."

0.50 Design Principles for Filtering Dangerous Chemical Contaminants It is generally acknowledged that a properly designed filtration system to remove dangerous chemical contaminants should be as follows:

1. HEPA filters should be used to trap dangerous particulates and protect the carbon filters from collecting particulates and thereby increasing the adsorber's pressure drop.

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ATTACHMENT 8 HEGA F It s Geeal Ifratino Carbon an Adsortio Materal The following are some random thoughts and 9 The adsorption coefficient of carbon is information that will help you form a general idea the amount of a given material that the about carbon filter technology. These comments carbon will adsorb, by weight.

are to be considered as general axioms, and 10 Some hard to adsorb materials can be the reader should be able to "fill in" some of the displaced by easier to adsorb materi-unknown factors when unusual situations arise.

als. For example, acetic anhydride may However, there is no substitute for expert displace acetone. Acetone may advice and opinion, and the reader is urged to displace acetaldehyde, and acetalde-contact Flanders/CSC for answers to any hyde may displace acetylene.

technical problem, specific questions or additional information. 11 The lower the concentration of a material, the harder to achieve a high 1 Elemental iodine is adsorbed by removal percentage.

attraction of the iodine to the carbon.

This is called Kinetic adsorption. 12 One gram of carbon will adsorb one milligram of iodine. The potential 2 Methyl iodide, which comes from inventory of radioiodine in a nuclear elemental iodine (12) combining with power system is very small.

methane must be adsorbed by chemisorption, usually in the form of 13 Since carbon will adsorb anything isotopic exchange when KI carbon is adsorbable, it can be poisoned by used or complexing when TEDA carbon harmless materials and be unable to is used. adsorb the material that it was designed to control. That is why the carbon should 3 The recommended residence time for methyl iodide is 0.25 seconds residence always be protected from vapors that will harm it.

time per 2-inch bed. Tests have shown that the carbon will perform as required 14 Shelf life of carbon in properly packaged at twice that velocity or half that r drums or in filters having a vapor esidence time for a limited time period. barrier of some kind can be as long as five (5) years. Flanders/CSC recom-4 As the humidity increases, the ability of mends that carbon over three (3) years the carbon to perform is adversely old be retested to assure that it meets affected. However, the carbon must the efficiency requirements of the perform at 95% relative humidity original specifications.

in order to meet ASME AG-1 requirements. 15 Methyl iodide adsorbs-desorbs-adsorbs through the bed, exchanging iodine at 5 The heavier the molecular weight of a each juncture. That is to say, methyl material, the easier it is to adsorb.

iodide can be radioactive-stable-radio-6 The higher the boiling temperature of a active-stable until it decays into harm-material, the easier it is to adsorb. less xenon.

7 The converse of 5 and 6 is true. 16 Elemental iodine, once adsorbed, usually stays adsorbed.

8 One gram of 60% active carbon (as measured by carbon tetrachloride) has a surface area of about 1,000 square meters.

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