Roberts Gorden Heating System CRV B 2 User Guide

®
CoRayVac  
Custom Engineered,  
Gas-Fired, Low-Intensity  
Infrared Heating System  
CRV-B-2  
CRV-B-4  
CRV-B-6  
CRV-B-8  
CRV-B-9  
CRV-B-10  
CRV-B-12  
CRV-B-12A  
Design Manual  
®
All designs must be installed in strict accordance with the CORAYVAC  
Installation, Operation and Service Manual (P/N 127102NA).  
Roberts-Gordon LLC  
1250 William Street  
P.O. Box 44  
Buffalo, New York 14240-0044  
Telephone: 716.852.4400  
Fax: 716.852.0854  
Toll Free: 800.828.7450  
© 2009 Roberts-Gordon LLC  
P/N 127500NA Rev D 05/09  
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TABLE OF CONTENTS  
SECTION 1: Concept ..............................................................1  
SECTION 2: The CRV-Series System.....................................2  
2.1 Safety...........................................................................2  
2.2 Zero Regulator.............................................................2  
2.3 Fuel Savings and Comfort ...........................................4  
SECTION 3: Clearances to Combustibles.............................5  
3.1 Required Clearances to Combustibles.........................5  
SECTION 4: Sizing and Design Considerations...................9  
4.1 Radiant Adjustment to Heat Loss ................................9  
4.2 Radiant Height Adjustment Factor...............................9  
4.3 Selecting the Burners ................................................ 10  
4.4 Radiant Distribution ................................................... 10  
SECTION 5: Flow Loading.................................................... 12  
5.1 Radiant Branch Flow ................................................. 12  
5.2 Pump Capacity .......................................................... 14  
5.3 Tailpipe Flow.............................................................. 14  
SECTION 6: Radiant Tube and Tailpipe............................... 15  
6.1 Radiant Tube Length.................................................. 15  
6.2 Tailpipe....................................................................... 15  
6.3 Design Parameters .................................................... 16  
6.4 CRV-Series Design Methods..................................... 16  
6.5 Tailpipe Design Method ............................................. 18  
SECTION 7: Example CRV-Series System Layouts............21  
7.1 Example System Layout (Option 1)............................21  
7.2 Example System Layout (Option 2)............................22  
7.3 Example System Layout (Option 3)............................22  
7.4 Example System Layout (Option 4)............................23  
7.5 Example System Layout (Option 5)............................23  
7.6 Example System Layout (Option 6)............................24  
7.7 Example System Layout (Option 7, 8 and 9)...............25  
SECTION 8: Control Methods ..............................................26  
8.1 ROBERTS GORDON® System Control  
(P/N 02770002) .........................................................26  
8.2 ROBERTS GORDON® ULTRAVAC..........................26  
8.3 SPST Transformer Relay (P/N 90417600K)...............27  
8.4 DPST Transformer Relay (P/N 90436300).................27  
8.5 Pressure Switch .........................................................27  
SECTION 9: Air Supply System ...........................................28  
9.1 Pressurized................................................................28  
9.2 Non-Pressurized ........................................................28  
9.3 Outside Air System Design Requirements.................28  
SECTION 10: ROBERTS GORDON® ULTRAVACDesign  
Requirements.................................................31  
SECTION 11: CRV-Series Equipment Specifications.........32  
11.1 Burner and Burner Controls......................................32  
11.2 Equipment ................................................................32  
Roberts-Gordon LLC  
© 2009  
All rights reserved. No part of this work covered by the copyrights herein may be reproduced  
or copied in any form or by any means - graphic, electronic, or mechanical, including  
photocopying, recording, taping or information storage and retrieval systems - without the  
written permission of Roberts-Gordon LLC.  
Printed in U.S.A.  
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TABLE OF FIGURES  
Figure 1: Assembly Overview (Two Branch System Shown).....3  
Figure 2: Standard Reflector .....................................................6  
Figure 3: One Side Reflector.....................................................6  
Figure 4: Two Side Reflectors ...................................................6  
Figure 5: Universal Shield, Position 1 .......................................7  
Figure 6: Universal Shield, Position 2 .......................................7  
Figure 7: Universal Shield, Position 3 .......................................7  
Figure 8: 2-Foot Deco Grille......................................................8  
Figure 9: Barrier Shield.............................................................8  
Figure 10: Protective Grille........................................................8  
Figure 11: Radiant Distribution (Average Coverage)............... 11  
Figure 12: Radiant Distribution (Increased Coverage) ............ 11  
Figure 13: Radiant Distribution (Heavy Coverage).................. 11  
Figure 14: Burner Flow Units .................................................. 13  
Figure 15: Vacuum Loss Curve for 4" Shared Tailpipe...........14  
Figure 16: Tube Length vs. Efficiency...................................... 16  
Figure 17: Possible Damper Coupling Locations ....................20  
Figure 18: Example System Layout (Option 1).......................21  
Figure 19: Example System Layout (Option 2).......................22  
Figure 20: Example System Layout (Option 3).......................22  
Figure 21: Example System Layout (Option 4).......................23  
Figure 22: Example System Layout (Option 5).......................23  
Figure 23: Example System Layout (Option 6).......................24  
Figure 24: Example System Layout (Option 7).......................24  
Figure 25: Example System Layout (Option 8).......................24  
Figure 26: Example System Layout (Option 9).......................25  
Figure 27: Air Supply System Capacity by Duct Length and  
Diameter................................................................28  
Figure 28: Outside Air Blower.................................................29  
Figure 29: Sample Layout for Pressurized Outside Air  
Systems..................................................................30  
LIST OF TABLES  
Table 1: CORAYVAC® Design Parameters ............................12  
Table 2: Pump Capacity..........................................................14  
Table 3: Pump Exhaust Requirements...................................14  
Table 4: Allowable Tailpipe Lengths.......................................17  
Table 5: Operating Characteristics; Condensing or  
Non-Condensing ......................................................18  
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SECTION1:CONCEPT  
SECTION 1: CONCEPT  
The concept of CRV-Series is easy to understand.  
However, it means discarding old ideas because CRV-  
Series is a different kind of heating system.  
CRV-Series is a gas-fired, vacuum-operated, low-  
intensity infrared heating system incorporating a pat-  
ented incremental burner system.  
Gas-Fired means it uses clean-burning Natural or  
Propane gas.  
Vacuum-Operated means that the pump draws all  
the products of combustion through the system and  
expels them outdoors.  
Low-Intensity means the radiant surfaces of the  
tubes do not glow red; instead they operate at a lower  
temperature (less than 900° F or 482.2° C) and radiate  
heat at lower intensity per square foot of radiating sur-  
face. Area coverage is provided by long runs of 4" (10  
cm) O.D. tubing which hang from the ceiling or roof  
supports. Reflectors direct the radiant heat downward  
to occupied areas.  
Radiant refers to the heat radiated by the CRV-Series  
system. Because this heat is in the form of infrared  
rays, it does not directly heat the air. Instead, the rays  
heat objects such as floors, people, walls, cars,  
machines, tools, etc. The warm objects, in turn, heat  
the air through convection.  
Incremental Burner System means that several  
burners can operate in-series and fire into the same  
run of steel tube that carries the combustion gases  
from upstream burners. Each of these burners in a  
radiant branch may have different firing rates; also, the  
space between burners may vary. This allows the  
designer to match heat gain to heat loss for each area  
of the building. Firing burners in-series provides higher  
thermal and radiant efficiency.  
In a properly designed low-intensity radiant system,  
the occupants should be barely aware of the radiant  
heat when the system is firing. They will feel little or no  
change when the thermostat is satisfied and the sys-  
tem is not firing. This combines with warm floors,  
warm walls and draft-free operation to improve the  
mean radiant temperature of the space. This is the key  
to the exceptional comfort and fuel efficiency provided  
by the CRV-Series system.  
1
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CRV-SERIES DESIGN MANUAL  
SECTION 2: THE CRV-SERIES SYSTEM  
A CRV-Series system consists of one pump, a control With CRV-Series, all equipment and controls are  
system, and a number of burners, see Page 3, Figure C.S.A. design certified, both as individual parts and  
1. It also includes an extended tube surface (4" (10  
also as a complete heating system. Also, individual  
cm) steel tubing) covered by highly efficient reflectors electrical component parts are listed as applicable.  
to direct the radiant heat downward to the floor. The  
tubing nearest the burners radiates with the most  
intensity and is called radiant tube. This should be  
located over areas with the greatest heat loss. The  
rest of the tubing surface (located between the radiant  
tube and the pump) radiates with less intensity and is  
called tailpipe. This can be located in areas with  
lower heat loss.  
2.2 Zero Regulator  
CRV-Series uses a 100% pre-mix burner with the input  
dependent on system vacuum. With no vacuum, the  
zero regulator prevents gas flow. When vacuum is  
present, the burner fires and input increases as vac-  
uum increases. As the input increases, the amount of  
air also increases. Over the normal range of operating  
vacuum, the gas/air ratio is essentially linear.  
While it is important to locate radiant tubes over areas  
with high heat loss, such as the perimeter of the build-  
ing, it is not essential to cover all areas directly with  
radiant heat. Center areas (away from external walls)  
This unique and patented feature provides optimum  
combustion conditions at all times. Combustion condi-  
tions are unaffected by fluctuations in fuel pressure,  
vacuum, dirty air filters, changes in atmospheric pres-  
and other areas of low heat loss can be adequately  
sure, wind velocity or other climate conditions.  
heated without direct coverage as long as the input of  
the system is adequate for the total building heat loss.  
However, to achieve the highest degree of comfort and  
fuel savings, it is recommended that the CRV-Series  
system be located to provide as complete and even a  
distribution as is practical. In addition, several different  
reflector and shield configurations are available to  
direct the radiant heat to or away from desired areas.  
Page 3, Figure 1 illustrates the components of a typi-  
cal CRV-Series system. The system shown is a four  
burner system composed of two branches. A branch  
consists of a single run of tubing, including an end  
burner, followed by any burners downstream. A  
branch ends at a tee or a cross (where other branches  
connect). For a single branch system, the branch ends  
at the pump.  
2.1 Safety  
Safety is a prime consideration of CRV-Series. First,  
there is a pre-purge of the complete tube network prior  
to flame ignition. Then, to ensure that there will be no  
gas flow unless the pump is operating, a pressure  
switch located at the pump must activate prior to igni-  
tion. After the pressure switch has closed, there are  
two valves in-series in each burner that must be ener-  
gized, as well as a zero regulator. Additionally, slow  
opening gas valves provide smooth ignition and  
enhance reliability. Once the thermostat has been sat-  
isfied, the burners turn off and the pump continues to  
run for two minutes to purge the entire system of flue  
gases.  
2
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SECTION 2: THE CRV-SERIES SYSTEM  
FIGURE 1: Assembly Overview (Two Branch System Shown)  
3
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CRV-SERIES DESIGN MANUAL  
2.3 Fuel Savings and Comfort  
Space heating can be accomplished with less input  
capacity when a radiant heating system is utilized,  
rather than with a conventional convective heating  
system. Why is this so?  
A conventional, convective heating system, such as a  
unit heater or central furnace works by heating the air,  
which then indirectly heats the area and  
occupants. CRV-Series utilizes infrared energy to heat  
objects, people and surfaces directly, not the air. The  
warm objects and floor create a heat reservoir, which  
then re-radiates to the surroundings and also heats  
the air by convection.  
The radiant energy received by the occupants, directly  
from the heater or indirectly from the  
surroundings via re-radiation, serves to increase the  
mean radiant temperature (MRT) of the space. In a  
manner similar to direct sunlight, the increased MRT  
allows the occupant to perceive a comfort condition at  
a reduced air temperature. The resulting reduced air  
temperature within the space provides the  
following fuel-saving advantages:  
• Reduced stratification of air in the space.  
• Reduced transmission heat loss due to lower tem-  
perature inside than assumed design  
condition.  
• Reduced air change heat loss, to the extent that  
exfiltration through cracks or openings near the  
roof will be decreased because of decreased  
stack effect.  
• Decreases the actual degree days experienced.  
4
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SECTION 3: CLEARANCES TO COMBUSTIBLES  
SECTION 3: CLEARANCES TO COMBUSTIBLES  
3.1 Required Clearances to Combustibles  
• Hang heater in accordance to the minimum sus-  
pension requirements.  
Clearances are the required distances that combusti-  
ble objects must be away from the heater to prevent  
serious fire hazards. Combustibles are materials,  
which may catch on fire and include common items  
such as wood, paper, rubber, fabric, etc. Maintain  
clearances to combustibles at all times for safety.  
• If the radiant tubes must pass through the building  
structure, be sure that adequate sleeving and fire  
stop is installed to prevent scorching and/or fire  
hazard.  
Clearances for all heater models are located on the  
burner assembly and on Page 6, Figure 3 through  
Page 8, Figure 10 in this manual. Check the clear-  
ances on each burner for the model heater being  
installed to make sure the product is suitable for your  
application and the clearances are maintained. Read  
and follow the safety guidelines below:  
WARNING  
• Keep gasoline or other combustible materials  
including flammable objects, liquids, dust or  
vapors away from this heater or any other appli-  
ance.  
Fire Hazard  
Keep all flammable objects, liquids and  
vapors the minimum required clearances to  
combustibles away from heater.  
The stated clearances to combustibles represents  
a surface temperature of 90° F (32° C) above  
room temperature. Building materials with a low  
heat tolerance (such as plastics, vinyl siding, can-  
vas, tri-ply, etc) may be subject to degradation at  
lower temperatures. It is the installer’s responsibil-  
ity to assure that adjacent materials are protected  
from degradation.  
Some objects will catch fire or explode when  
placed close to heater.  
Failure to follow these instructions can result  
in death, injury or property damage.  
• Maintain clearances from heat sensitive  
equipment and workstations.  
• Maintain clearances from vehicles parked below  
the heater.  
• Maintain clearances from swinging and overhead  
doors, overhead cranes, vehicle lifts, partitions,  
storage racks, hoists, building construction, etc.  
• In locations used for the storage of combustible  
materials, signs must be posted to specify the  
maximum permissible stacking height to maintain  
required clearances from the heater to the com-  
bustibles. Signs must be posted adjacent to the  
heater thermostat. In the absence of a thermo-  
stat, signs must be posted in a conspicuous loca-  
tion.  
• Consult local Fire Marshal, Fire Insurance Carrier  
or other authorities for approval of proposed  
installation when there is a possibility of exposure  
to combustible airborne materials or vapors.  
5
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CRV-SERIES DESIGN MANUAL  
NOTE: 1. All dimensions are from the surfaces of all tubes, couplings, elbows, tees and crosses.  
2. Clearances B, C and D can be reduced by 50% after 25' (7.5 m) of tubing downstream from  
where the combustion chamber and the tube connect.  
FIGURE 2: STANDARD REFLECTOR  
(inches)  
(centimeters)  
Model  
A
4
4
4
4
4
4
4
4
B
20  
20  
20  
20  
36  
36  
36  
36  
C
D
A
B
C
D
CRV-B-2  
48  
48  
48  
48  
60  
60  
60  
60  
20  
20  
20  
20  
36  
36  
36  
36  
11  
11  
11  
11  
11  
11  
11  
11  
51  
51  
51  
51  
92  
92  
92  
92  
122  
122  
122  
122  
153  
153  
153  
153  
51  
51  
51  
51  
92  
92  
92  
92  
A
CRV-B-4  
CRV-B-6  
CRV-B-8  
CRV-B-9  
CRV-B-10  
CRV-B-12  
CRV-B-12A  
B
D
C
.
FIGURE 3: ONE SIDE REFLECTOR  
Model  
(inches)  
(centimeters)  
A
4
4
4
4
4
4
4
4
B
C
D
A
B
31  
31  
31  
31  
31  
31  
31  
31  
C
D
51  
CRV-B-2  
CRV-B-4  
CRV-B-6  
CRV-B-8  
CRV-B-9  
CRV-B-10  
CRV-B-12  
CRV-B-12A  
12  
12  
12  
12  
12  
12  
12  
12  
56  
56  
56  
56  
60  
60  
60  
60  
20  
20  
20  
20  
42  
42  
42  
42  
11  
11  
11  
11  
11  
11  
11  
11  
143  
143  
143  
143  
153  
153  
153  
153  
A
51  
51  
51  
107  
107  
107  
107  
B
D
C
FIGURE 4: TWO SIDE REFLECTORS  
Model  
(inches)  
(centimeters)  
A
4
4
4
4
4
4
4
4
B
C
D
A
B
31  
31  
31  
31  
31  
31  
31  
31  
C
D
A
CRV-B-2  
CRV-B-4  
CRV-B-6  
CRV-B-8  
CRV-B-9  
CRV-B-10  
CRV-B-12  
CRV-B-12A  
12  
12  
12  
12  
12  
12  
12  
12  
56  
56  
56  
56  
60  
60  
60  
60  
12  
12  
12  
12  
12  
12  
12  
12  
11  
11  
11  
11  
11  
11  
11  
11  
143  
143  
143  
143  
153  
153  
153  
153  
31  
31  
31  
31  
31  
31  
31  
31  
B
D
C
6
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SECTION 3: CLEARANCES TO COMBUSTIBLES  
NOTE: 1. All dimensions are from the surfaces of all tubes, couplings, elbows, tees and crosses.  
2. Clearances B, C and D can be reduced by 50% after 25' (7.5 m) of tubing downstream from  
where the combustion chamber and the tube connect.  
FIGURE 5: UNIVERSAL SHIELD, POSITION 1  
(inches)  
(centimeters)  
Model  
CRV-B-2  
CRV-B-4  
CRV-B-6  
CRV-B-8  
CRV-B-9  
CRV-B-10  
CRV-B-12  
CRV-B-12A  
A
4
4
4
4
8
8
8
8
B
C
D
A
B
31  
31  
31  
31  
46  
46  
46  
46  
C
D
12  
12  
12  
12  
18  
18  
18  
18  
12  
12  
12  
12  
24  
24  
24  
24  
12  
12  
12  
12  
18  
18  
18  
18  
11  
11  
11  
11  
21  
21  
21  
21  
31  
31  
31  
31  
61  
61  
61  
61  
31  
31  
31  
31  
46  
46  
46  
46  
A
C
B
D
FIGURE 6: UNIVERSAL SHIELD, POSITION 2  
Model  
(inches)  
(centimeters)  
A
4
4
4
4
4
4
4
4
B
C
D
A
B
61  
61  
61  
61  
92  
92  
92  
92  
C
D
CRV-B-2  
24  
24  
24  
24  
36  
36  
36  
36  
48  
48  
48  
48  
48  
48  
48  
48  
24  
24  
24  
24  
36  
36  
36  
36  
11  
11  
11  
11  
11  
11  
11  
11  
122  
122  
122  
122  
122  
122  
122  
122  
61  
61  
61  
61  
92  
92  
92  
92  
A
CRV-B-4  
CRV-B-6  
CRV-B-8  
CRV-B-9  
CRV-B-10  
CRV-B-12  
CRV-B-12A  
B
D
C
FIGURE 7: UNIVERSAL SHIELD, POSITION 3  
Model  
(inches)  
(centimeters)  
A
4
4
4
4
8
8
8
8
B
C
D
A
B
31  
31  
31  
31  
31  
31  
31  
31  
C
D
77  
CRV-B-2  
12  
12  
12  
12  
12  
12  
12  
12  
56  
56  
56  
56  
60  
60  
60  
60  
30  
30  
30  
30  
42  
42  
42  
42  
11  
11  
11  
11  
21  
21  
21  
21  
143  
143  
143  
143  
153  
153  
153  
153  
A
CRV-B-4  
CRV-B-6  
CRV-B-8  
77  
77  
77  
B
D
CRV-B-9  
CRV-B-10  
CRV-B-12  
CRV-B-12A  
107  
107  
107  
107  
C
7
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CRV-SERIES DESIGN MANUAL  
NOTE: 1. All dimensions are from the surfaces of all tubes, couplings, elbows, tees and crosses.  
2. Clearances B, C and D can be reduced by 50% after 25' (7.5 m) of tubing downstream from  
where the combustion chamber and the tube connect.  
FIGURE 8: 2-FOOT DECO GRILLE  
Model  
(inches)  
(centimeters)  
A
4
4
4
4
4
4
4
4
B
C
D
A
B
31  
31  
31  
31  
46  
46  
46  
46  
C
D
CRV-B-2  
CRV-B-4  
CRV-B-6  
CRV-B-8  
CRV-B-9  
CRV-B-10  
CRV-B-12  
CRV-B-12A  
12  
12  
12  
12  
18  
18  
18  
18  
48  
48  
48  
48  
56  
56  
56  
56  
12  
12  
12  
12  
18  
18  
18  
18  
11  
11  
11  
11  
11  
11  
11  
11  
122  
122  
122  
122  
143  
143  
143  
143  
31  
31  
31  
31  
46  
46  
46  
46  
A
C
B
D
FIGURE 9: BARRIER SHIELD  
(inches)  
(centimeters)  
Model  
CRV-B-2  
CRV-B-4  
CRV-B-6  
CRV-B-8  
CRV-B-9  
CRV-B-10  
CRV-B-12  
CRV-B-12A  
A
4
B
12  
12  
12  
12  
C
12  
12  
12  
12  
D
A
11  
11  
11  
11  
B
31  
31  
31  
31  
C
31  
31  
31  
31  
D
31  
31  
31  
31  
12  
12  
12  
12  
A
4
4
4
B
D
- UNAPPROVED -  
- UNAPPROVED -  
- UNAPPROVED -  
- UNAPPROVED -  
- UNAPPROVED -  
- UNAPPROVED -  
- UNAPPROVED -  
- UNAPPROVED -  
C
FIGURE 10: PROTECTIVE GRILLE  
Model  
(inches)  
(centimeters)  
A
4
4
4
4
4
4
4
4
B
C
D
A
B
51  
51  
51  
51  
92  
92  
92  
92  
C
D
A
CRV-B-2  
CRV-B-4  
CRV-B-6  
CRV-B-8  
CRV-B-9  
CRV-B-10  
CRV-B-12  
CRV-B-12A  
20  
20  
20  
20  
36  
36  
36  
36  
48  
48  
48  
48  
60  
60  
60  
60  
20  
20  
20  
20  
36  
36  
36  
36  
11  
11  
11  
11  
11  
11  
11  
11  
122  
122  
122  
122  
153  
153  
153  
153  
51  
51  
51  
51  
92  
92  
92  
92  
C
B
D
8
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SECTION 4: SIZING AND DESIGN CONSIDERATIONS  
SECTION 4: SIZING AND DESIGN CONSIDERATIONS  
The building heat loss must be calculated in accor-  
dance to accepted energy load calculation methods.  
heating system. The ability of a radiant system to pro-  
vide the advantages of these radiant effects rests  
ASHRAE (American Society of Heating, Refrigeration largely with the ability of this system to establish a  
and Air-Conditioning Engineers) offers in-depth infor-  
reserve heat capacity in the floor. Without this reserve  
mation that is useful in calculating energy loads. The  
capacity, radiant comfort cannot be achieved. (The  
CRV-Series system input is determined in concert with exception is station heating/spot heating applications  
the required radiant adjustment to heat loss and height where sufficiently high levels of direct radiation are  
adjustment factors.  
received from the heater.) The height adjustment fac-  
tor is a means to insure adequate floor level radiant  
intensity to “charge” the floor heat reservoir.  
4.1 Radiant Adjustment to Heat Loss  
The practice of applying an adjustment factor to heat  
loss calculations for radiant heating systems is well  
known within the radiant heating industry, having been  
used by manufacturers for over 25 years. A number of  
studies have been conducted to identify the values of  
the adjustment factor in the range of 0.8 to 0.85  
depending on efficiency (higher efficiency uses lower  
factor). This adjustment can be more thoroughly  
understood when considering the following radiant  
effect issues:  
Proportionately larger wall surfaces also remove  
energy from the floor to a larger degree, decreasing  
the heat reservoir.  
The increased input capacity recommended by a  
height adjustment factor is not extraneous as com-  
pared to the heat loss calculation. Rather, it is a real-  
ization that in order to maintain radiant comfort  
conditions (and the economic benefits), a minimum  
radiant level must be maintained at the floor.  
• Infrared energy heats objects, not the air.  
It is recommended that an adjustment to the heat loss  
of 1% per foot (3% per meter) for mounting heights  
above 20' (6 m), be added up to 60' (18 m). Above this  
height, additional correction overstates the BTU  
requirement as determined by the heat loss.  
• Lower ambient temperatures reduce the amount  
of air infiltration.  
• Less air stratification with radiant heat.  
• Lower ambient air temperatures reduce the trans-  
mission heat loss through walls and roof.  
EXAMPLE 1:  
• Elevated floor temperature provides a thermal  
reserve capacity.  
Given a building with a calculated heat loss of  
350,000 (Btu/h), what is the installed capacity  
required of a CORAYVAC system mounted at  
• Increased mean radiant temperature allows occu-  
pants to perceive thermal comfort at the reduced  
air temperature.  
®
30' (9 m)?  
®
CORAYVAC Installed Capacity = Heat Loss x  
Each of these issues impacts favorably on the reduc-  
tion of the installed capacity of the radiant heating sys-  
tem. This fact, together with the realization that the  
standard ASHRAE heat loss calculation methods  
(particularly the transmission heat loss coefficients)  
have been developed specifically for conventional hot  
air systems, demonstrates the need for the heat loss  
adjustment factor.  
Radiant Adjustment x Height Adjustment  
®
For CORAYVAC systems, a .80 radiant adjust-  
ment factor is used.  
The height adjustment is 1% per foot over 20'  
(3% per meter over 6 meters), or 1.10.  
®
CORAYVAC Installed Capacity = 350,000  
(Btu/h) x .80 x 1.10 = 308,000 (Btu/h)  
• In general, a .80 adjustment factor should be  
used for CRV-Series systems.  
A 12% reduction in installed capacity vs. a  
conventional heating system.  
4.2 Radiant Height Adjustment Factor  
As discussed above, the installed input capacity of  
radiant heating systems is typically reduced as com-  
pared to the calculated heat loss due to the radiant  
effects associated with a properly designed radiant  
9
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CRV-SERIES DESIGN MANUAL  
EXAMPLE 2:  
calculated CRV-Series system required installed  
capacity.  
Given a building with a calculated heat loss  
of 500,000 Btu/h, what is the installed capac-  
ity required of a CRV-Series system mounted  
at 50' (15 m)?  
4.4 Radiant Distribution  
Radiant heat distribution at occupant level must be  
considered in the burner and design selection  
process.  
®
CORAYVAC Installed Capacity = Heat Loss x  
Distribution of heat between radiant branches at floor  
level is more critical at the perimeter of buildings. This  
is where the heat loss is highest. Therefore, it may be  
possible to combine different applications of distribu-  
tion within the same building. The following figures  
show three different applications of rules to determine  
distribution.  
Radiant Adjustment x Height Adjustment.  
®
For CORAYVAC systems, a .80 radiant adjust-  
ment factor is used.  
The height adjustment is 1% per foot over 20'  
(3% per meter over 6 meters), or 1.30.  
®
CORAYVAC Installed Capacity = 500,000  
(Btu/h) x .80 x 1.30 = 520,000 (Btu/h).  
4.4.1 Radiant Distribution (Average Coverage)  
The aim of this distribution is to provide average or  
lighter than average radiant intensity and works well  
for general building heating. See Page 11, Figure 11.  
The distance between radiant branches can vary  
between 2.5 to 4 (or more) times the mounting height.  
Note in Example 2, if equipment had been convention-  
ally sized based on thermal output only, a nearly iden-  
tical input requirement would result. For mounting  
heights above 60' (18 m), no further correction is gen-  
erally necessary if the floor level radiant intensity is  
sufficient to establish a reserve capacity (hence, radi-  
ant comfort), and the heat loss  
This distribution is commonly used in applications  
such as warehouses and lower heat loss areas of a  
building.  
Lighter coverage can be used in areas where occu-  
pant traffic is low.  
requirement is satisfied based on thermal output.  
Due to the complexity of installations with mounting  
heights over 60' (18 m), it is advisable to contact Rob-  
erts-Gordon for further information regarding the spe-  
cific application.  
4.4.2 Radiant Distribution (Increased Coverage)  
The aim of this distribution is to provide continuous  
radiant intensity. See Page 11, Figure 12. The  
distance between radiant branches is about 2 times  
the mounting height.  
4.3 Selecting the Burners  
The number of burners and input for each must be  
specified in the design layout. The following  
factors should be considered when selecting burner  
input:  
This distribution is commonly used in areas bordering  
high heat loss areas or areas requiring increased radi-  
ant intensity to achieve occupant comfort.  
4.4.3 Radiant Distribution (Heavy Coverage)  
• Heat gain and distribution required.  
• Mounting height.  
The aim of this distribution is to provide increased radi-  
ant intensity in areas that range from sedentary work  
to spot heating for loading docks. See Page 11, Figure  
13. The y dimensions in the diagram is the height  
above floor level where overlap of the radiant output  
will occur.  
• Flow loading restrictions.  
• Length of radiant branches.  
• Distance required between burners.  
• Desired radiation intensity.  
In practice, y = 6' (1.83 m) is commonly used in areas  
where occupant comfort doing sedentary work is an  
important factor. In loading bays, spot heating and  
areas of high heat loss, the horizontal distance (x)  
between branches can be as little as 0.5 times the  
mounting height.  
In general, lower burner inputs can be used for lower  
mounting heights and where lower heat gains are  
required. Higher burner inputs are used primarily with  
higher mounting heights and where high heat gain is  
required.  
The number of burners required can be calculated by  
dividing the input rating of the selected sizes into the  
10  
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SECTION 4: SIZING AND DESIGN CONSIDERATIONS  
FIGURE 11: Radiant Distribution (Average Coverage)  
H= mounting height  
3 H  
90°  
H
FIGURE 12: Radiant Distribution (Increased Coverage)  
H= mounting height  
2 H  
90°  
H
FIGURE 13: Radiant Distribution (Heavy Coverage)  
H= mounting height  
y= height above the  
floor level where  
overlap of radiant  
output will occur  
x=2H-2y  
x
H
90°  
y
11  
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CRV-SERIES DESIGN MANUAL  
SECTION 5: FLOW LOADING  
The patented CRV-Series burner system allows a  
burners, the burner inlet flow consists the of the total of  
number of burners to be installed in-series, in the  
the end vent air plus the combustion gases from all  
same radiant tube, resulting in a long, continuous radi- upstream burners.  
ant emitting surface to give even heat distribution  
The requirement for minimum burner inlet flow is met if  
the total flow units entering the combustion chamber  
To enable the burners to be correctly located within the meets or exceeds the minimum as shown on Page 12,  
within the building.  
system, to maintain system operating vacuum and  
obtain design flue gas temperatures at the pump, the  
design layout is based on a simplified flow principle  
using a “flow unit.”  
Table 1.  
5.1 Radiant Branch Flow  
The flow in a radiant branch consists of the end vent  
flow units plus the flow units of combustion air from all  
burners. Page 13, Figure 14 shows a representation  
of flow units for various types of branches.  
The flow unit is defined as the amount of fuel/air mix-  
ture for a heat input of 10,000 (Btu/h). This corre-  
sponds to a flow rate of 1.83 cfm at 65-70°F.  
The limiting factor for maximum flow in the radiant sec-  
tion has been determined experimentally in terms of  
the maximum burner inlet flow units that can be toler-  
ated without degradation of combustion characteris-  
tics at the last downstream burner. If more than the  
maximum number of burners are installed per radiant  
branch, the vacuum loss across the additional burners  
will increase appreciably.  
For the purpose of design, flow units enter the CRV-  
Series system in one of two ways:  
• Through the burner.  
• Through the end vent plate.  
Flow units exit the system as spent products of com-  
bustion via the pump.  
The purpose of the end vent air is to dilute the hot  
combustion gases at the burner, thereby promoting  
uniform heating of the tube while avoiding excessive  
heating of the combustion chamber.  
This maximum flow in the radiant branch can be  
expressed for each burner firing rate by either a maxi-  
mum number of burners per branch or the maximum  
number of flow units. See Page 12, Table 1.  
For the end burner, the burner inlet flow consists of the  
end vent air and combustion air. For all other  
®
Table 1: CORAYVAC Design Parameters  
Burner Model  
B-2  
B-4  
40  
4
B-6  
60  
6
B-8  
80  
8
B-9*  
90  
B-10 B-12A B-12  
Input (Btu/h) x (1000)  
Flow Units per Burner  
20  
2
100  
10  
110  
12  
120  
12  
9
Flow Units per End Vent  
(minimum flow units entering combustion chamber)  
6
10  
15  
20  
15  
20  
20  
20  
Maximum Number of Burners per Branch  
Maximum Number of Flow Units per Branch  
Radiant Tube Length (average distance between burners)  
Minimum (ft)  
6
4
4
4
2
4
3
3
18  
26  
39  
52  
33  
60  
56  
56  
10  
15  
20  
5
12.5  
20  
25  
5
20  
25  
35  
10  
8
20  
30  
45  
10  
10  
20  
30  
50  
10  
10  
30  
40  
60  
15  
15  
35  
50  
70  
15  
15  
35  
50  
70  
15  
15  
Recommended (ft)  
Maximum (ft)  
Minimum Distance from Burner to Downstream Elbow (ft)  
Suggested Minimum mounting Height (ft)  
8
8
* CRV B-9 requires first downstream tube from burner to be aluminized heat-treated.  
12  
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SECTION 5: FLOW LOADING  
FIGURE 14: Burner Flow Units  
B-10 Burner #1  
Total Flow  
End Burner  
Units  
B-10 Burner #2  
B-10 Burner #3  
20 + 10 + 10 + 10  
= 50 Flow Units  
Downstream Burner  
Downstream Burner  
End Vent Air  
+ 20 Flow Units  
Combustion Gas  
Combustion Gas  
+ 10 Flow Units  
+ 10 Flow Units  
Combustion Gas  
+ 10 Flow Units  
Coupling  
Burner 1  
Burner 2  
Burner 3  
Burner #2  
Flow Units  
Burner Firing Rate  
Burner #3 Total Flow  
End Vent  
Burner #1  
Burner #  
Btu/h  
Flow Units  
Units  
Flow Units Flow Units  
1
2
3
20,000  
20,000  
20,000  
2
2
4
6
2
6
12  
1
2
3
40,000  
40,000  
40,000  
4
4
6
8
22  
33  
10  
1
2
3
60,000  
60,000  
60,000  
6
15  
1
2
3
80,000  
80,000  
80,000  
8
9
8
9
44  
33  
50  
20  
15  
1
2
90,000  
90,000  
1
2
3
100,000  
100,000  
100,000  
10  
10  
10  
12  
20  
20  
1
2
3
120,000 (or 110,000)  
120,000 (or 110,000)  
120,000 (or 110,000)  
12  
12  
12  
10  
56  
50  
1
2
3
120,000  
100,000  
80,000  
20  
8
13  
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CRV-SERIES DESIGN MANUAL  
5.2 Pump Capacity  
number of flow units carried in the tube.  
The flow unit capacity of the pump is indicated on  
Page 14, Table 2, as a function of installed altitude.  
When the CRV-Series system is designed in accor-  
dance with this set of instructions and is in proper  
operating condition, a vacuum from 2-3" w.c. will be  
obtainable at each end vent (i.e. at all burners).  
See Figure 15. Readings for length and flow when  
plotted on the graph must fall on OK side to avoid  
excessive vacuum losses.  
FIGURE 15: Vacuum Loss Curve for 4" Shared  
Tailpipe  
130  
120  
100  
Table 2: Pump Capacity  
Installed Altitude  
Maximum Flow Units  
EP-200 EP-300  
Feet Above  
Sea Level  
Meters Above  
Sea Level  
EP-100  
Series  
112  
105  
100  
95  
Series  
224  
215  
206  
197  
188  
180  
170  
161  
NOT OK  
90  
0 m - 609 m  
66  
63  
60  
57  
54  
51  
48  
45  
0' - 2000'  
610 m - 914 m  
2001' - 3000'  
3001' - 4000'  
4001' - 5000'  
5001' - 6000'  
6001' - 7000'  
7001' - 8000'  
8001' - 9000'  
80  
915 m - 1219 m  
1220 m - 1524 m  
1525 m - 1828 m  
1829 m - 2134 m  
2135 m - 2438 m  
2439 m - 2743 m  
70  
OK  
SIDE  
60  
90  
84  
50  
40  
30  
20  
10  
80  
75  
There are a number of design requirements which, if  
not met, will reduce the vacuum obtainable and  
thereby the effective flow capacity of the pump. These  
include:  
30 40 50 60 70  
90 100 110 120  
80  
Maximum Flow Units per Single Tailpipe Section  
NOTE: For 6" (15 m) tailpipe, length is limited to a  
maximum of 100’ (30 m). See Page 16, Section 6.3  
for more details.  
Lengths shown include allowance for 1 elbow every  
50' (15 m); deduct 15% of length for each additional  
elbow used per 50' (15 m) length.  
Minimum Length of Tailpipe - If less than the  
minimum length of tailpipe is provided per radiant  
branch, there will be insufficient cooling of the com-  
bustion gases and improper operation of the pump.  
Line Loss Check for Tailpipe is applicable to  
sections of tailpipe which are common to two or  
more radiant branches (i.e. shared lengths). See  
Page 14, Figure 15.  
5.3.1 Pump Exhaust Length Requirements  
The tube length on the exhaust side of the pump is  
considered excessive if not within the following condi-  
tions:  
Table 3: Pump Exhaust Requirements  
Pump Series Exhaust Tube Length Exhaust Tube Diameter  
Excessive back pressure on discharge line of  
pump can be caused by partial blockage or too  
much flow for length. See Section 5.3.1  
EP-100  
EP-100  
EP-200  
EP-200  
EP-200  
EP-300  
EP-300  
EP-300  
Up to 25' (7.6 m)  
Up to 50' (15 m)  
Up to 10' (3 m)  
Up to 25' (7.6 m)  
Up to 50' (15 m)  
Up to 10' (3 m)  
Up to 25' (7.6 m)  
Up to 50' (15 m)  
4" 3 Elbows  
5" 3 Elbows  
4" 0 Elbows  
5" 3 Elbows  
6" 3 Elbows  
6" 1 Elbows  
7" 3 Elbows  
8" 3 Elbows  
More than maximum number of burners or flow  
units per radiant branch. See Page 14, Table 2.  
Excessive number of elbow or tee fittings  
which increases vacuum loss.  
5.3 Tailpipe Flow  
Excessive flow loading in a single section of tailpipe  
can cause low vacuum and lower effective pump  
capacity. For the pump to develop the proper vacuum,  
the length of tailpipe must not be excessive for the  
14  
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SECTION 6: RADIANT TUBE AND TAILPIPE  
SECTION 6: RADIANT TUBE AND TAILPIPE  
The main purpose of the tailpipe and the radiant tube Page 16, Figure 16 relates the effect on system ther-  
is to provide sufficient tube surface to transfer the heat mal efficiency of variations in radiant and tailpipe  
from the flue gases to the tube wall where it radiates  
from the tube. Radiant tube is defined as the tubing  
between burners firing in a radiant branch, plus the  
radiant tubing immediately following the last down-  
stream burner. Tailpipe is defined as all tubing  
between the radiant tube and the pump.  
lengths. The chart was created based on test data  
obtained in accordance with methodology developed  
by the National Bureau of Standards (NBSIR 80-2110)  
and recommendations on flue loss calculation con-  
tained in ANSI Z83.20/CSA 2.34 (latest edition).  
Actual installation variables (gas BTU content, air tem-  
perature and operation cycle, etc.) may effect efficien-  
cies (positively or negatively). Page 16, Figure 16 is  
presented as a guide to the designer for information  
only.  
Most of the radiant heat supplied by each burner is  
released from the radiant tube; the balance is released  
by the tailpipe. The placement of radiant tube to corre-  
spond to areas of major heat loss is the key to provid-  
ing uniform comfort levels. The use of adequate  
tailpipe is the key to high combustion efficiency and  
proper operation of the pump.  
NOTE: When accounting for the required tailpipe  
lengths during the design process, it is important to  
verify that the tailpipe for each branch is at least equal  
to the specified minimum.  
6.1 Radiant Tube Length  
The considerations in the selection of the length of  
radiant tube include the following:  
6.1.1 Minimum Radiant Tube Length  
Provides for the highest level of intensity per length of  
radiant tube and good radiant heat uniformity between  
burners. More tailpipe length is required to maintain  
operating efficiency and pump capacity.  
6.1.2 Maximum Radiant Tube Length  
Provides the lowest level of intensity per length of radi-  
ant tube, and consequently the largest span between  
burners. The radiant intensity will be reduced slightly  
for the last 5'-10' (2-3 m) of radiant tube before the  
next burner.  
The length of radiant tube required varies according to  
the burner input. Consideration has been given to the  
use of a standard 10' (3 m) length of tube or lengths  
that can be cut from same without waste. See Page  
12, Table 1.  
When positioning radiant tube to give the required  
radiant distribution, it is important to consider:  
• Clearances to combustible materials.  
• Lighting equipment and other suspended objects.  
6.2 Tailpipe  
Tailpipe provides a low level of radiant intensity per  
length. The length of tailpipe for systems can be varied  
according to the flow units in the system and the  
designed radiant length. Longer lengths of tailpipe will  
attain higher operating efficiencies and therefore con-  
densation will occur.  
15  
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CRV-SERIES DESIGN MANUAL  
FIGURE 16: Tube Length vs. Efficiency  
3.0  
2.5  
2.0  
1.5  
1.0  
83%  
84%  
85%  
86%  
87%  
88%  
89%  
90%  
Steady State Thermal Efficiency (%)  
NOTE: Thermal efficiency values shown do not include the contribution due to condensing conditions when  
operating in cyclic fashion. To estimate cyclic efficiencies, add 2-3% to the values obtained from the graph.  
6.3 Design Parameters  
in insufficient vacuum to burners.  
When designing branches of 4 B-8 or larger burners  
in-series, the following limitation to the pump capacity  
applies:  
6.4 CRV-Series Design Methods  
1. Layout the system to suit the BTU input  
required.  
Pump Model Series Maximum Loading  
2. Calculate the system design for each branch  
EP-100:Not Allowed  
individually.  
EP-200:1 Branch of 4 burners  
EP-300:2 Branches of 4 burners  
3. Calculate the number of flow units per branch of  
burners. Add the flow units for each branch  
together to get the total system flow units. See  
Page 12, Table 1 for the rules for each burner  
model. See Page 13, Figure 14 for example flow  
unit calculations.  
For systems that are designed above 90% pump  
capacity, the following limitations of shared tailpipe  
apply:  
• 4" (10 cm) tailpipe: limited to maximum of 2 com-  
bined branches and length limited to maximum of  
20' (6 m). See Page 14, Figure 15 for all other  
tailpipe considerations.  
Flow Units Per Branch  
Branch 1  
Branch 2  
Branch 3  
Branch 4  
Branch 5  
Branch 6  
+
+
+
+
+
+
• 6" (15 cm) tailpipe limited to maximum of 4 com-  
bined branches and length limited to maximum of  
100' (30 m).  
• When calculating required tailpipe length 1' (.3 m)  
of 6" manifold tube is equivalent to 1.3' (.4 m) of 4"  
tailpipe.  
Total System  
Flow Units =  
Failure to comply with the above parameters will result  
16  
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SECTION 6: RADIANT TUBE AND TAILPIPE  
4. Select pump model series for total system flow  
units:  
EP-100: up to 66 flow units  
EP-200: up to 110 flow units  
EP-300: up to 224 flow units  
5. See Page 14, Table 2 for altitudes greater than  
2000'.  
6. For each branch, add the length of radiant tube  
after each heater:  
Radiant Tube Length  
After Each Burner  
Burner  
1
2
3
4
5
6
+
+
+
+
+
+
Total Radiant Tube  
Length in Branch =  
Repeat this calculation for each branch in the  
system.  
7. Divide the total radiant tube length in the branch  
by the number of burners in the branch to get  
the average radiant length per burner.  
Average Radiant  
Length Per Burner =  
Repeat this calculation for each branch in the  
system.  
8. Using the average radiant length per burner  
(Calculated in Step 7) See Page 17, Table 4 to  
select the allowable tailpipe lengths per flow  
unit.  
Table 4: Allowable Tailpipe Lengths  
Burner Model  
B-2  
B-4  
B-6  
B-8  
B-9  
B-10  
B-12/B-12A  
Radiant Tube Length (average distance between burners)  
Minimum (ft)  
10  
15  
20  
12.5  
20  
20  
25  
35  
20  
30  
45  
20  
30  
50  
30  
40  
60  
35  
50  
70  
Recommended (ft)  
Maximum (ft)  
25  
Tailpipe length per flow unit  
Minimum (ft)*  
1.2  
1.5  
2.5  
1.7  
1.2  
1.5  
2.5  
1.7  
1.2  
1.5  
2.5  
1.7  
1.2  
1.5  
2.5  
1.7  
1.2  
1.5  
2.5  
1.7  
1.2  
1.5  
2.5  
1.7  
1.2  
1.5  
2.5  
1.7  
Recommended (ft)  
Maximum (ft)  
Maximum (ft) for EP-100 only  
*Minimum tailpipe lengths can only be used if radiant tube length is recommended or greater.  
17  
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CRV-SERIES DESIGN MANUAL  
EXAMPLE 3: B-10 Radiant Tube vs. Tailpipe Length  
For a B-10 burner system of 200 flow units and an average of 40' radiant tube length per burner, See  
Page 17, Table 4 for the tailpipe lengths per flow unit that can be used and the corresponding  
operating characteristic.  
From Table 4, we can use between 1.2' per flow unit and 2.5' per flow unit when the average radiant length  
per B-10 burner is 40'. By multiplying the number of flow units in the system (200 flow units) by the mini-  
mum tailpipe length from the chart (1.2' per flow unit), we see that we will need a minimum of 240' of tailpipe  
for this system. Likewise, by multiplying the number of flow units in the system (200 flow units) by the maxi-  
mum tailpipe length from the chart (2.5' per flow unit), we see that maximum system, tailpipe length is 500'.  
Tailpipe length range for a B-10 burner system with 200 flow units and an average radiant tube length of 40’  
is 240'-500'. The length of the tailpipe will determine whether the system is condensing or non-condensing.  
Given a certain radiant tube length and tailpipe length, the operating characteristic can be determined  
using Table 5.  
Table 5: Operating Characteristics; Condensing or Non-Condensing  
Tailpipe Length per Flow Unit  
Minimum  
Recommended 1.7 ft/flow unit  
Maximum  
Radiant Tube Length (average distance between burners)  
Minimum  
N/A  
NC  
NC  
Borderline  
C
Borderline  
C
C
C
Recommended  
C
C
Maximum  
Borderline  
N/A=Not Allowed NC=Non Condensing C=Condensing  
6.5 Tailpipe Design Method  
the section of tailpipe.  
Given the overall length of tailpipe for the system, the  
following section provides the method for ensuring the  
design will function correctly.  
If flow units entering a shared tailpipe system exceed  
90% of pump capacity, the length of 4" diameter  
tailpipe must not exceed 20'.  
System with EP-300 Series Pump  
Total tailpipe  
' (includes 1 elbow / 50').  
For shared tailpipe up to 115 flow units, 4" diameter  
tailpipe can be used. See Page 14, Figure 15 for max-  
imum permissible length of tailpipe for the number of  
flow units entering the section of tailpipe.  
6.5.1 Rule of Thumb Unshared Calculations  
Total tailpipe - 10'  
= Optimum unshared  
Number of branches  
tailpipe per branch  
Select a pump discharge location and plan the route of  
the tailpipe. For example system layouts See Page 21,  
Figure 18 through Page 25, Figure 26 for different  
pump and system efficiency requirements. If these lay-  
outs are not suitable, it is necessary to customize the  
layout for the CRV-Series system to the individual  
building requirements.  
Shared tailpipe greater than 115 flow units use 6"  
diameter tube. Note that all tailpipe lengths for the pur-  
poses of calculation are expressed in terms of 4"  
diameter tube.  
Effective length: 10' (3 m) of 6" (15 cm) diameter  
tube = 13' (4 m) of 4" diameter tube.  
6.5.3 To Calculate the Total System Tailpipe  
For multiple branch systems, always plan to connect  
the unshared tailpipe together as close to the pump as  
possible for better system efficiency.  
Total unshared tailpipe + shared 4" branch tailpipe +  
effective length of shared 6".  
6.5.4 To Check Performance Criteria  
6.5.2 Shared Tailpipe Calculation  
Total system tailpipe  
= Tailpipe ft/flow unit  
Total flow units  
System with EP-100 or EP-200 Series Pump  
See Page 14, Figure 15 for maximum permissible  
Compare the results to Page 17, Table 4 and Page 18,  
length of tailpipe for the number of flow units entering  
18  
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SECTION 6: RADIANT TUBE AND TAILPIPE  
Table 5 for the burner model to ensure that the result-  
ing tailpipe lengths maintain intended operating char-  
acteristic.  
6.5.5 Damper Couplings  
Damper couplings are needed:  
• In any tailpipe branch that carries less flow units  
than other tailpipe branches connected to the  
same pump  
• In unsymmetrical layouts with branches having  
the same number of flow units, the damper cou-  
pling is placed in every branch except for the  
longest branch.  
The purpose of the damper coupling is to adjust the  
end vent vacuum down to the desired level. These are  
to be placed in the tailpipe section and not the radiant  
branch. The recommended location is before the first  
tee fitting or 10'-40' from the end of the radiant pipe.  
See Page 20, Figure 17; Page 23, Figure 21, Page  
24, Figure 25, and Page 25, Figure 26 for placement  
examples.  
19  
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CRV-SERIES DESIGN MANUAL  
FIGURE 17: Possible Damper Coupling Locations  
20  
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SECTION 7: EXAMPLE CRV-SERIES SYSTEM LAYOUTS  
SECTION 7: EXAMPLE CRV-SERIES SYSTEM LAYOUTS  
Systems that are symmetrical are preferred because  
the vacuum available in the system branches are bal-  
anced as a function of design (damper couplings are  
not needed).  
FIGURE 18: Example System Layout (Option 1)  
Where radiant tube lengths are variable in a single  
branch, the average length shall be used to determine  
the total radiant tube length. Tailpipe will begin after  
the last radiant tube following the last burner in the  
branch.  
20'  
(6 m)  
20'  
(6 m)  
20'  
(6 m)  
CRV-Series is most effective when there are at least 3  
burners in the radiant branch.  
30'  
(9 m)  
To assist with the selection of burners and system  
designs, the following figures show system layouts that  
have been used extensively with CRV-Series since  
1962. Designing systems using these layouts will  
mean altering the dimensions to suit the individual  
building.  
30'  
(9 m)  
30'  
(9 m)  
Generally, shared tailpipe reduces the available sys-  
tem vacuum. See Page 14, Section 5.3 for shared  
tailpipe design rules.  
10' (3 m)  
LEGEND  
7.1 Example System Layout (Option 1)  
®
CORAYVAC  
Burner  
Six B10 burners at minimum radiant tube length and  
2.5 ft/flow unit tailpipe, the recommended pump for  
this system is an EP-200 Series pump.  
Pump  
This system provides maximum radiant intensity on  
the left and right and adds supplemental radiant  
effects through the center creating very even radiant  
effects over the coverage area.  
Damper  
Radiant Tube  
Layout to provide high system efficiency, condensed  
radiant output and good uniformity of distribution.  
Adjust the lengths as necessary for different input sys-  
tems and to change the efficiency levels.  
Tailpipe  
6" Tailpipe  
21  
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CRV-SERIES DESIGN MANUAL  
FIGURE 19: Example System Layout (Option 2)  
FIGURE 20: Example System Layout (Option 3)  
40'  
(12 m)  
40'  
(12 m)  
30'  
(9 m)  
10' (3 m)  
40'  
20' (6 m)  
30'  
(9 m)  
(12 m)  
30'  
(9 m)  
40'  
(12 m)  
40'  
(12 m)  
6" Tailpipe  
50'  
(15 m)  
40'  
(12 m)  
40'  
(12 m)  
7.2 Example System Layout (Option 2)  
Six B10 burners at recommended radiant tube length  
and 1.2'/flow unit tailpipe, the recommended pump for  
this system is an EP-200 Series pump.  
Layout will minimize up front equipment cost of tubing  
by implementing minimum tailpipe length.  
Layout will exhibit minimum system efficiency. Adjust  
the lengths as necessary for different input systems  
and to increase the efficiency levels.  
7.3 Example System Layout (Option 3)  
Twelve B10 burners at minimum radiant tube length  
and 1.56'/flow unit tailpipe, the pump for this system is  
an EP-300 Series Pump.  
All shared tailpipe is 6" diameter.  
Layout will provide maximum radiant intensity  
between burners.  
Layout will exhibit minimum system efficiency. Adjust  
the lengths as necessary for different input systems  
and to increase the efficiency levels.  
22  
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SECTION 7: EXAMPLE CRV-SERIES SYSTEM LAYOUTS  
FIGURE 21: Example System Layout (Option 4)  
FIGURE 22: Example System Layout (Option 5)  
30'  
(9 m)  
40'  
(12 m)  
30'  
(9 m)  
40'  
(12 m)  
30'  
(9 m)  
40'  
(12 m)  
70'  
(21 m)  
30'  
(9 m)  
30'  
(9 m)  
40'  
(12 m)  
6" Tailpipe  
30'  
(9 m)  
10'  
(3 m)  
7.4 Example System Layout (Option 4)  
Nine B10 burners at recommended radiant tube length  
and 1.58'/flow unit tailpipe, the pump for this system is  
an EP-300 Series Pump.  
All shared tailpipe is 6" diameter.  
Layout will exhibit nominal system efficiency. Adjust  
the lengths as necessary for different input systems  
and to increase the efficiency levels.  
7.5 Example System Layout (Option 5)  
Six B10 burners at minimum radiant tube length and  
1.5'/flow unit tailpipe, the pump for this system is an  
EP-200 Series pump.  
23  
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CRV-SERIES DESIGN MANUAL  
Layout to provide minimum system efficiency. Adjust  
the lengths as necessary for different input systems  
and to increase the efficiency levels.  
This layout method is often used effectively in heatloss  
and perimeter heating applications.  
FIGURE 24: Example System Layout (Option 7)  
This system is generally accompanied by an addi-  
tional system, as shown, so that the radiant output of  
the additional system supplements the lack of radiant  
intensity from the tailpipe of the first system. This lay-  
out method is used in high heatloss and perimeter  
heating applications.  
30'  
(9 m)  
180'  
(55 m)  
30'  
(9 m)  
FIGURE 23: Example System Layout (Option 6)  
10' (3 m)  
negligible  
30'  
(9 m)  
30'  
(9 m)  
30'  
100'  
(9 m)  
(30 m)  
30'  
(9 m)  
30'  
(9 m)  
10' (3 m)  
FIGURE 25: Example System Layout (Option 8)  
30'  
(9 m)  
30'  
(9 m)  
30'  
(9 m)  
30'  
(9 m)  
10' (3 m)  
7.6 Example System Layout (Option 6)  
10' (3 m)  
Six B10 burners at minimum radiant tube length and  
2.3'/flow unit tailpipe, the pump for this system is an  
EP-200 Series pump.  
30'  
(9 m)  
Layout to provide high system efficiency, condensed  
radiant output and good uniformity of distribution.  
Adjust the lengths as necessary for different input sys-  
tems and to change the efficiency levels.  
24  
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SECTION 7: EXAMPLE CRV-SERIES SYSTEM LAYOUTS  
FIGURE 26: Example System Layout (Option 9)  
Layout to provide condensed radiant output and good  
uniformity of distribution. Layout will exhibit minimum  
system efficiency.  
30'  
(9 m)  
30'  
(9 m)  
10'  
(3 m)  
30'  
(9 m)  
10'  
(3 m)  
6"  
Tailpipe  
30'  
(9 m)  
30'  
(9 m)  
7.7 Example System Layout (Option 7, 8 and 9)  
These systems are for B9 burners only, this burner is  
specially rated for 2 burners in-series applications in  
the systems shown.  
Option 7 is a 180' (55 m) straight system connected to  
an EP-100 pump.  
Option 8 is a system connected to an EP-200 Series  
pump.  
Option 9 is a system connected to an EP-300 Series  
pump.  
These layouts show minimum allowed lengths. Addi-  
tional tubing may be added. The distance between the  
burners can be varied from 30' (9 m) to 20’ (6 m), but  
the overall system lengths must remain the same.  
Layout will minimize upfront equipment cost of tubing  
by implementing special shortened minimum tailpipe  
lengths.  
25  
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CRV-SERIES DESIGN MANUAL  
SECTION 8: CONTROL METHODS  
Electronic 24 Vac thermostats and mechanical ther-  
mostats with heat anticipator can be used. The sys-  
tem control offers a 24 Vac power supply to power  
electronic thermostats.  
DANGER  
Roberts-Gordon offers a selection of low voltage  
thermostats approved for use with the system  
control.  
A System Control operated system has two minutes  
post purge pump operation to completely exhaust  
products of combustion from the system. A system  
control provides indication of power to the pump and  
zones and indicates the status of the pressure switch  
with lights.  
Electrical Shock Hazard  
Disconnect electric before service or  
maintenance.  
More than one disconnect switch may be  
required to disconnect electric to the unit.  
The System Control is ETL listed in accordance with  
UL873 – Standard for Temperature Indicating and  
Regulating Equipment.  
Control must be properly grounded to an  
electrical source.  
Failure to follow these instructions can  
result in death or electrical shock.  
®
8.2 ROBERTS GORDON ULTRAVAC  
®
The ROBERTS GORDON ULTRAVAC is a micro  
processor based control package designed for modu-  
lating control of CRV-Series heaters based on outdoor  
temperatures. The controls offer full modulation  
between 60% and 100% of system maximum rated  
input.  
WARNING  
This controller is capable of giving control outputs to  
one pump and three heating zones. The controller  
also features inputs which are used for indoor and out-  
door signal condition monitoring.  
Explosion Hazard  
System status and settings are viewed and altered  
Turn off gas supply to heater before service.  
from a PC (not supplied) running ROBERTS GOR-  
DON ULTRAVAC Software.  
Failure to follow these instructions can result  
®
in death, injury or property damage.  
®
ROBERTS GORDON ULTRAVAC Software requires  
®
a PC (not supplied) running Windows 95 or higher,  
There are several methods of controlling CRV-Series  
systems. The options are as follows:  
®
with a Pentium class processor and at least 64k of  
RAM.  
®
8.1 ROBERTS GORDON System Control (P/N  
Special design requirements apply for CRV-Series  
02770002)  
®
systems using the ROBERTS GORDON ULTRA-  
®
The ROBERTS GORDON System Control is an  
VAC Controller, See Page 31, Section 10.  
electronic controller designed for the control of  
®
®
CORAYVAC and VANTAGE NP (multiburner only)  
systems.  
The System Control is capable of giving four zones of  
burners' temperature control and power. The control  
will also give power output to as many as two pumps,  
provided that the load is not greater than 20 A and 1  
Ø. For additional electrical specifications see the  
System Control Installation, Operation and Service  
manual (P/N 10091601NA).  
26  
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SECTION 8: CONTROL METHODS  
Buildings today demand all sorts of control options  
based on the user’s preference. ULTRAVAC™  
controls offer a host of communication options for  
integration with controls’ networks to best serve  
individual needs:  
indication of operating conditions. The transformer  
relay wiring diagram is shown in the CORAYVAC  
Installation, Operation and Service Manual (P/N  
127102NA).  
®
8.5 Pressure Switch  
®
BACnet : Interface ULTRAVAC™ with other building  
management control platforms with our BACnet  
A pressure switch is required to confirm pump opera-  
tion on all systems.  
option.  
TCP/IP (LAN): Connect to ULTRAVAC™ via your  
local area network of computers. Load ULTRAVAC™  
software onto any computer on the network and  
control and view your heating system from your  
computer.  
A pressure switch is also required on the inlet duct of a  
non-pressurized air supply.  
MODEM: Dial into ULTRAVAC™ from anywhere in  
the world via modem. Supplied as standard on all  
central controllers!  
RS-485: Hard wire ULTRAVAC™ directly to your  
computer.  
There are references in this manual to various trademarks. All  
trademarks mentioned herein, whether registered or not, are the  
property of their respective owners. Roberts-Gordon is not  
sponsored by or affiliated with any of the trademark or registered  
trademark owners, and make no representations about them,  
their owners, their products or services.  
Roberts-Gordon LLC is not sponsored by or affiliated with  
BACnet®.  
8.3 SPST Transformer Relay (P/N 90417600K)  
The transformer relay can be used to control an EP-  
®
100 or EP-201 pump CORAYVAC system. The single  
pole relay can only be used to control one zone of  
burners. The electrical circuit is a 120 V AC (20 A)  
supply. The transformer 24 V AC output for the ther-  
mostat is rated at 40 V A. Thermostats used with the  
transformer must not exceed this power requirement.  
A transformer relay operated system will not give any  
post purge pump operation to completely exhaust  
products of combustion from the system or provide  
indication of operating conditions. The transformer  
®
relay wiring diagram is shown in the CORAYVAC  
Installation, Operation and Service Manual (P/N  
127102NA).  
8.4 DPST Transformer Relay (P/N 90436300)  
The transformer relay can be used to control an EP-  
®
100 or EP-201 pump CORAYVAC system. The double  
pole relay can only be used to control two zones of  
burners. The electrical circuit is a 120 V AC (20A) sup-  
ply. The transformer 24 V AC output for the thermostat  
is rated at 40 VA. Thermostats used with the trans-  
former must not exceed this power requirement. A  
transformer relay operated system will not give any  
post purge pump operation to completely exhaust  
products of combustion from the system or provide  
27  
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CRV-SERIES DESIGN MANUAL  
SECTION 9: AIR SUPPLY SYSTEM  
®
An air supply free of dust and corrosive contaminants DON ULTRAVAC or relay transformer, a separate  
is essential for proper operation and best life expect- load relay package is required. Wire the control for the  
ancy with any heating system. With CRV-Series, there relay in parallel with the pump. The outside air blower  
are two alternatives available to the designer for pro-  
must have a separate 20 A, 120 V power supply.  
viding the air supply. These are:  
9.2 Non-Pressurized  
• Room air, a filter is standard for each burner.  
For a non-pressurized outside air supply, a 4" O.D. sin-  
gle wall pipe duct may be attached to the burner and  
end vent. For length and duct sizing requirements See  
Section 9.3. To prevent condensation, insulate the  
outside air duct.  
• Outside air system to duct air from an uncontami-  
nated source. The outside air system can be  
designed as a pressurized or non-pressurized  
system.  
9.3 Outside Air System Design Requirements  
9.3.1 Non Pressurized  
The first alternative above is usable when the dust  
load is not excessive and there is no usage of corro-  
sive contaminants such as solvents or vapors inside  
the building.  
• 6" diameter duct must not exceed 90' (27 m)  
• 4" diameter duct must not exceed 90' (27 m)  
The outside air system must be used in all applica-  
tions where corrosive contaminants may be present in  
the air even in trace amounts (few parts per million).  
• Elbows are equivalent to 10' (3 m) of duct length.  
• See the CRV-Series Installation, Operation, and  
Service Manual (P/N 127102NA) for ducting  
installation details.  
It is important for designers and owners of heating  
systems to note that the presence of contaminants in  
the combustion air supply will greatly accelerate the  
rate of corrosion on tube surfaces and will shorten the  
useful life of the heating system. This is true regard-  
less of whether the heating system is CRV-Series,  
other infrared systems or conventional gas or oil-fired  
equipment such as unit heaters, central boiler plant,  
etc.  
9.3.2 Pressurized Systems  
• 6" diameter duct must not exceed 120' (36 m) total  
per system.  
• 4" diameter duct must not exceed 120' (36 m) per  
radiant branch.  
• See the CRV-Series Installation, Operation, and  
Service Manual (P/N 127102NA) for ducting  
installation details.  
With the unique vacuum powered burners, the fuel/air  
mix remains constant, even if combustion air filters are  
dirty. It can be expected that the use of an outside air  
system will reduce but not eliminate the potential for  
corrosion due to contamination.  
FIGURE 27: Air Supply System Capacity by Duct  
Length and Diameter  
In a way similar to the CRV-Series pump system, the  
design of the air supply system also involves consider-  
ations of total flow units and acceptable combinations  
of duct lengths (and diameters) versus flow units car-  
ried. In certain circumstances, it may be desirable to  
introduce an outside air blower to pressurize the sys-  
tem. A small positive pressure is desirable and neces-  
sary to prevent the system from drawing in  
NOTE: For capacity requirements larger than shown, use 8" duct.  
140  
120  
100  
7"  
80  
60  
40  
20  
0
6"  
5"  
4"  
contaminated air.  
9.1 Pressurized  
For pressurized outside air supplies, the outside air  
blower motor has a pressure switch that must be used.  
Wire this switch in-series with the pump pressure  
switch. When using an outside air blower with a ROB-  
0
50  
100  
150  
200  
250  
Straight Duct Length (feet)  
®
ERTS GORDON System Control, ROBERTS GOR-  
28  
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SECTION 9: AIR SUPPLY SYSTEM  
9.3.3 Pipe sizing  
To size each section of pipe proceed as follows:  
• Calculate the required flow units at each outlet of  
the supply system.  
• Measure the longest run of pipe from the blower  
to the most remote outlet. Use only this distance  
in Figure 27 (or the next longer distance if the  
exact distance is not shown). This is to provide  
assurance that the pressure drop to the most  
remote outlet will not exceed 0.25" w.c. when all  
outlets are supplied.  
See Figure 27, find the intersection point on the  
graph for the appropriate duct length and number  
of flow units. The duct size above this intersection  
point indicates what size duct work should be  
used. Proceed in a similar manner for each outlet  
and each section of duct. For each section of  
duct, determine the total flow unit capacity sup-  
plied by that section.  
Duct Design Rules  
• System should be designed so that the blower is  
positioned closest to the highest flow require-  
ments (end vents).  
• When a duct is carrying more than 40 flow units, it  
must be at least 6" diameter.  
Blower (P/N 90707501) Performance 112 Flow  
Units:  
One outside air blower is required per each EP-100 or  
EP-200 series pump and two outside air blowers may  
be required for each EP-300 series pump. Outside air  
blowers cannot be shared between two separate  
CRV-Series systems.  
FIGURE 28: Outside Air Blower  
29  
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CRV-SERIES DESIGN MANUAL  
FIGURE 29: Sample Layout for Pressurized Outside Air Systems  
20  
8
Branch A  
6" duct  
8
8
(44)  
4" duct  
15'  
(4.5 m)  
110'  
(33 m)  
B
4" duct  
10'  
P
Branch B  
(33)  
(22)  
6
6
15  
6
4
(3 m)  
max.*  
50'  
(15 m)  
Branch C  
10  
4
4
4" duct  
100'  
(30 m)  
Walls  
*NOTE: up to 10' (3 m) max. from blower  
inlet can be neglected for pressure drop  
calculations.  
6" Duct  
4" Duct  
30  
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®
SECTION 10: ROBERTS GORDON ULTRAVAC DESIGN REQUIREMENTS  
®
SECTION 10: ROBERTS GORDON ULTRAVAC DESIGN REQUIREMENTS  
CRV-B-2 and CRV-B-4 are not available for use with  
®
ROBERTS GORDON ULTRAVAC controls.  
CRV-Series systems designed with minimum  
radiant tube lengthshall have 1.5' - 2.0' per flow unit of  
tailpipe length.  
-OR-  
CRV-Series systems with recommended radiant tube  
length shall have 1.2' - 1.5' per flow unit of tailpipe  
length.  
31  
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CRV-SERIES DESIGN MANUAL  
SECTION 11: CRV-SERIES EQUIPMENT SPECIFICATIONS  
The total heating system supplied shall be design cer- 11.2 Equipment  
tified by the CSA International per American National  
Standard ANSI Z83.20/CSA 2.34 (latest edition).  
11.2.1 Burner  
Each burner assembly shall consist of heavy-duty  
11.1 Burner and Burner Controls  
cast-iron burner heads, pre-wired gas controls with  
electronic, three-try direct spark ignition and combus-  
tion air filter.  
11.1.1 Burners shall be designed to operate simulta-  
neously in series without adverse effects from com-  
bustion gases from upstream burners.  
11.2.2 Pump  
11.1.2 Burners shall be capable of firing on:  
Natural Gas, or LP Gas.  
The pump model supplied will vary with the capacity of  
the system. See the pump technical specification  
sheet or the installation, operation and service manual  
for product description and specification.  
11.1.3 Burners shall be supplied to fire at any one of  
the input firing rates as specified:  
CRV-B-2-20,000 (Btu/h)  
CRV-B-4-40,000 (Btu/h)  
CRV-B-6-60,000 (Btu/h)  
CRV-B-8-80,000 (Btu/h)  
CRV-B-9-90,000 (Btu/h)  
CRV-B-10-100,000 (Btu/h)  
CRV-B-12A-110,000 (Btu/h)  
CRV-B-12-120,000 (Btu/h)  
The pump shall be acoustically isolated from the sys-  
tem with a flexible connector with temperature rating of  
350°F minimum. The motor in the vacuum pump shall  
be secured with rubber mounts for acoustical isolation.  
11.2.3 Heat Exchanger  
Radiant tubing (between burners and 10’ - 70’ down-  
stream of last burner) shall be of 4" O.D. steel or heat  
treated aluminized tubing.  
As an option, the balance of the tubing shall be 4"  
O.D. steel tubing with an internal and external coating  
of acid-resistant porcelain.  
®
When using ROBERTS GORDON ULTRAVAC con-  
trols, burner rates will modulate between 60% and  
100% rated input (CRV-B-2 and CRV-B-4 are not avail-  
®
All heat exchanger (tubing) connections shall be made  
with stainless steel coupling assemblies. Standard  
couplings will be used in radiant sections. Lined cou-  
plings will be used in tailpipe sections.  
able for use with ROBERTS GORDON ULTRAVAC  
controls).  
11.1.4 The design of burners supplied shall provide  
for maintaining a constant proportion of fuel gas to fil-  
tered combustion air. These conditions are met for  
burners in which the pressure of both the fuel gas  
and the combustion air are introduced at zero (atmo-  
spheric) pressure and the flow of each is established  
by a vacuum on the downstream side of the flow  
metering orifices.  
11.2.4 Outside Air  
When specified, in contaminated environments, the  
system shall be capable of supplying air from the out-  
side to each burner and end vent for the support of  
combustion.  
11.1.5 To assure a high degree of fail-safe operation,  
the design shall preclude flow of gas if any or all of  
the following abnormal conditions occur in the non-  
firing mode:  
1. Main valve fails in open position.  
2. Vacuum pump motor fails to operate.  
3. Power fails.  
11.1.6 To further assure a high degree of safety, the  
system will be under negative pressure at all times  
during operation to preclude the possibility of the  
escape of combustion gases inside the building.  
11.1.7 The burner control assembly will include a zero  
regulator.  
11.1.8 All burners shall be pre-wired with a grounded  
electrical cord and plug.  
32  
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Attach this information to a wall near the ROBERTS GORDON® heater.  
®
I n f r a r e d H e a t i n g  
Read the Installation, Operation, and Service Manual thoroughly before installation, operation, or service.  
Know your model number and installed configuration.  
Model number and installed configuration are found on the burner and in the Installation, Operation and Service Manual.  
Write the largest clearance dimensions with permanent ink according to your model number and configuration in the open spaces below.  
OPERATING INSTRUCTIONS  
WARNING  
1. STOP! Read all safety instructions on this information sheet.  
2. Open the manual gas valve in the heater supply line.  
3. Turn on electric power to the heater.  
4. Set the thermostat to desired setting.  
TO TURN OFF THE HEATER  
1. Set the thermostat to off or the lowest setting.  
Fire Hazard  
IF THE HEATER WILL NOT OPERATE, TO ENSURE YOUR SAFETY,  
Keep all flammable objects, liquids and vapors the minimum  
FOLLOW THESE INSTRUCTIONS TO SHUT DOWN YOUR HEATER  
required clearances to combustibles away from heater.  
1. Set the thermostat to off or the lowest setting.  
2. Turn off electric power to the heater.  
3. Turn off the manual gas valve in the heater supply line.  
4. Call your registered installer/contractor qualified in the  
installation and service of gas-fired heating equipment.  
Some objects will catch fire or explode when placed close to  
heater.  
Failure to follow these instructions can result in death, injury  
or property damage.  
Maintain  
clearance  
to the side and  
clearance below  
the heater from vehicles  
and combustible materials.  
Roberts-Gordon Europe Limited  
Unit A, Kings Hill Business Park  
Darlaston Road, Wednesbury  
West Midlands WS10 7SH UK  
Telephone: +44 (0)121 506 7700  
Fax: +44 (0)121 506 7701  
Service Telephone: +44 (0)121 506 7709  
Service Fax: +44 (0)121 506 7702  
Roberts-Gordon LLC  
1250 William Street  
P.O. Box 44  
Buffalo, NY 14240-0044 USA  
Telephone: 716.852.4400  
Fax: 716.852.0854  
Toll Free: 800.828.7450  
Installation Code and Annual Inspections:  
All installation and service of ROBERTS GORDON® equipment must be performed by a contractor qualified in the installation and service of equipment sold and supplied by Roberts-Gordon and  
conform to all requirements set forth in the ROBERTS GORDON® manuals and all applicable governmental authorities pertaining to the installation, service and operation of the equipment. To help  
facilitate optimum performance and safety, Roberts-Gordon recommends that a qualified contractor conduct, at a minimum, annual inspections of your ROBERTS GORDON® equipment and  
perform service where necessary, using only replacement parts sold and supplied by Roberts-Gordon.  
Further Information: Applications, engineering and detailed guidance on systems design, installation and equipment performance is available through ROBERTS GORDON® representatives.  
Please contact us for any further information you may require, including the Installation, Operation and Service Manual.  
This product is not for residential use.  
© 2009 Roberts-Gordon LLC  
All rights reserved. No part of this work covered by the copyrights herein may be reproduced or copied in any form or by any means – graphic, electronic, or mechanical, including photocopying,  
recording, taping, or information storage and retrieval systems – without written permission of Roberts-Gordon LLC.  
Printed in U.S.A.  
P/N 91037912 Rev. H  
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