Bosch Appliances Smoke Alarm D296 D297 User Manual

D296/D297 Series  
Projected Beam  
Smoke Detectors  
Application Guide  
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1.0 Scope  
This application guide is intended to assist in determining the best locations and applications of the D296 Series Long Range Beam  
Smoke Detectors.  
This application guide contains information from the National Fire ProtectionAssociation standard NFPA-72, the National FireAlarm  
Code, on automatic fire detectors and discusses the general application rules for the D296 Series.  
Your Local Authority Having Jurisdiction (AHJ) should always be consulted before beginning the installation of any fire  
alarm system.  
2.0 Glossary of Terms  
Beam Smoke Detector (Projected Beam Smoke Detector)  
A device which senses smoke or smoke and heat by projecting a light beam from  
a transmitter across the protected area to a receiver that monitors the light signal.  
Smoke and/or heat entering the beam path will decrease the light signal causing an alarm.  
Detector Coverage  
The area in which a smoke detector or heat detector is considered to effectively  
sense smoke and/or heat. This area is limited by applicable listings and codes.  
Listed  
The inclusion of a device in a list published by a recognized testing organization,  
indicating that the device has been successfully tested to meet the accepted standards.  
Obscuration  
The reduction of the ability of light to travel from one point to another due to  
the presence of solids, liquids, gases, or aerosols.  
Receiver  
The device, in a projected beam smoke detector system, which monitors the  
signal level of the light which is sent by the transmitter.  
Sensitivity  
The ability of a smoke detector to respond to a given level of smoke.  
Smoke  
The solid and gaseous airborne products of combustion.  
Spot-Type Detector  
A device which senses smoke and/or heat at its location only. Spot-type detectors  
have a defined area of coverage.  
Stratification  
The effect which occurs when smoke, which is hotter than the surrounding  
air, rises until equal to the temperature of the surrounding air, causing the smoke to stop rising.  
Transmitter  
The device in a projected beam smoke detector which projects the light across the protected area to its associated receiver.  
Trouble Condition  
The status of a device or system which impairs its proper operation, i.e.,  
open circuit on an initiation loop. The notification of a trouble condition indicated  
on a control panel or annunciator is a “TROUBLE” SIGNAL.  
NFPA 72®, National Fire Alarm Code® are registered trademarks of the National Fire Protection Association.  
D296/D297 Series Application Guide  
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3.0 Introduction  
Why should I use Beam Smoke Detectors and where should I use them?  
Where there are high ceilings such as in atriums and aircraft hangers. Because the detectors mount on the walls easier access  
is achieved.  
• Where there is a dusty environment such as in warehouses, factories and barns. The detectors have built-in compensation to  
prevent alarms due to dust.  
• Where there are expansive ceilings. One set of beam smoke detectors can replace up to 24 spot type smoke detectors. This  
saves on service and installation costs especially is such areas as large offices or department stores.  
• On ornamental ceilings where spot detectors would be a distraction.  
• Where there is limited access to the ceiling such as in factories and warehouses.  
The D296 Series are Long Range Projected Beam smoke detectors which consist of separate transmitters and receivers. The  
projected beam smoke detectors consist of a transmitter that projects an infrared beam across the protected area to a receiver  
containing a photosensitive cell, which monitors the signal strength of the light beam. The detector works on the principle of light  
obscuration. The photosensitive element of the beam smoke detector sees light produced by the receiver in a normal condition. The  
receiver is calibrated to a preset sensitivity level based on a percentage of total obscuration. This sensitivity level is determined by  
the length of the beam (the distance between the transmitter and receiver) and the desired response time. Eight sensitivity settings  
are available for selection by the installer based on the length of the beam used in a given application.  
The transmitter may be powered independently from the receiver, which can greatly reduce wiring runs and, therefore, installation  
cost. Since battery back up is required for fire alarm systems, battery back up would be required for the transmitter whether it is  
powered from the panel or independently.  
Unlike spot type photoelectronic smoke detectors, beam smoke detectors are generally less response sensitive to the color of  
smoke. Therefore, a beam smoke detector may be well suited to applications unsuitable for spot-type photoelectronic detectors,  
such as applications where the anticipated fire would produce black smoke. Beam smoke detectors do require visible smoke and  
therefore may not be as sensitive as ion detectors in some applications.  
Beam smoke detectors are sensitive to the cumulative obscuration presented by a smoke field. This cumulative obscuration is  
created by a combination of smoke density and the linear distance of the smoke field across the projected light beam. Cumulative  
obscuration, then, is a measure of the percentage of light blockage.  
Since the sudden and total obscuration of the light beam is not a typical smoke signature, the detector will see this as a trouble  
condition, not an alarm. This threshold is at a sensitivity level which exceeds 90 to 95% total obscuration. This minimizes the  
possibility of an unwanted alarm due to the blockage of the beam by a solid object, such as a sign or ladder, being inadvertently  
placed in the beam path.  
Very small, slow changes in the quality of the light source also are not typical of a smoke signature. These changes may occur  
because of environmental conditions such as dust and dirt accumulation on the transmitter and/or receiver’s optical assemblies.  
These changes are typically compensated for by the automatic environmental compensation circuit. When the detector is first  
turned on and put through its setup program, it assumes the light signal level at that time as a reference point for a normal condition.  
As the quality of the light signal degrades over time, perhaps due to dust, the environmental compensation circuit will compensate  
for this change. The rate of compensation is limited to insure that the detector will still be sensitive to slow or smoldering fires. When  
the automatic environmental compensation circuit can no longer compensate for the loss of signal (as with an excessive accumulation  
of dirt) the detector will signal a trouble condition.  
The receiver indicates a trouble condition if the the beam strength is increased by more than 20%. This can be caused by incorrect  
alignment of the transmitter and receiver or a partially blocked beam when the transmitter and receiver are installed.  
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4.0 Specifications  
Power:  
D296  
D297  
18 to 32 VDC Receiver: 45 mA @ 24 VDC, Transmitter: 20 mA @ 24 VDC  
10.2 to 18 VDC Receiver: 50 mA @ 12 VDC, Transmitter: 20 mA @ 12 VDC  
One Normally Open (NO) Contact rated 1 A, 60 VDC maximum for resistive loads. One  
Auxiliary Form “C” (NO/C/NC) contact rated 1 A, 60 VDC maximum for resistive loads.  
One Normally Closed (NC) Contact rated 1A, 60 VDC maximum for resistive loads. Opens  
when the cover is removed, power is lost or the beam is blocked.  
Automatic Signal Synchronization eliminates the need for a synchronization wire. Self-  
compensating circuitry compensates for signal loss due to dust or dirt buildup on lens and  
signals a trouble condition upon signal loss of 50%.  
Alarm Output:  
Tamper/Trouble Output:  
Signal Processing:  
Operation:  
The transmitter emits an invisible pulsed infrared beam to the receiver. If the beam is obscured  
beyond the selected threshold by smoke, the receiver signals an alarm. If the beam is  
completely blocked, the receiver signals a trouble.  
Alarm Response Selectivity:  
Eight (8) sensitivity settings are available. Selectable response time of 5 or 30 sec.  
Storage & Operating Temperature: -22°F to +130°F (-30° C to +55°C). For UL Certificated Installations +32°F to 120°F (0°C to  
50°C).  
Test Features:  
Externally visible LEDs on transmitter and receiver give indication of signal, alarm, and  
supervision conditions. Signal voltage output on receiver assists in alignment and  
troubleshooting. D306 Indicator Plate (included) provides LED indication of the detector’s  
status/condition, and provides a point to read/test the signal voltage.  
Dimensions (H x W x D):  
Coverage:  
Mounting:  
Pattern Pointability:  
Radio Frequency Interference  
(RFI) Immunity:  
7 in. x 5.5 in. x 5.5 in. (17.8 cm x 13.9 cm x 13.9 cm)  
30 to 350 ft (9 m to 107 m) range, up to 60 ft (18 m) spacing on smooth, flat ceilings.  
Surface or ceiling mount to standard 4 in. / 10.2 cm square or octagonal electrical boxes.  
Internally pointable ±90° horizontal, ±10° vertical.  
No alarm or setup on critical frequencies in the range from 26 to 950 Megahertz at 50 v/m.  
Listings:  
UL Listing UL268 & UL268A, ULC Listing, MSFM Permit #1943, NY City MEAAcceptance  
#MEA274-93-E, CSFM #7260-1062:106, FM Job #0X2A9.AY, and CE.  
5.0 Accessories  
Standard:  
D306 Remote Indicator Plate. This standard accessory provides a status monitor of the condition of the beam  
smoke detector and allow for a calibration voltage measurement to determine if the detector is within the calibration  
range. The D306 may be mounted to a standard single gang box.  
Optional:  
D307 Remote Test/Indicator Plate. This optional accessory provides a status monitor of the condition of the beam  
smoke detector and allow for a calibration voltage measurement to determine if the detector is within the calibration  
range. Remote test and detector reset can also be performed from the plate using a keylock switch. The D307 may  
be mounted to a standard double Wiremold box.  
D309 Alignment Strobe. This optional accessory provides a visual indication to assist on the alignment of the D296  
transmitter and receiver.  
D1005 Test Cord. This optional accessory provides an electrical connection to the D296 receiver to assist in the  
alignment of the receiver and transmitter.  
D308 Field Test Kit. This optional accessory allows testing the calibration of the D296 Series Beam Smoke  
Detectors by providing a calibrated amount of obscuration between the transmitter and receiver.  
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6.0 Applications  
6.1 Coverage  
The D296 Series Projected Beam Smoke Detectors are primarily used to provide for smoke detection in large areas with open or  
high ceilings.  
The D296 Series Detectors have a coverage range of up to 350 ft (106 m). On a smooth flat ceiling, the beams may be placed up to  
60 ft (18 m) apart. That means that one D296 can replace up to 24 spot smoke detectors with a 30 ft (9.1 m) spacing.  
Beams are permitted to be installed vertically or at any angle needed to afford protection of the hazard involved (for example, vertical  
beams through the open shaft area of a stairwell where there is a clear vertical space inside the handrails).  
The following should be considered before installing beam smoke detectors:  
• Will there be a clear line of sight between the transmitter and receiver at all times?  
• Is it likely that objects such as signs or boxes might be placed in the beam path in the future, or will moving objects such as  
traveling cranes or forklift trucks enter the beam path?  
• In anticipating the type of fire that might occur, would air movement or obstacles prohibit the smoke from reaching the detectors?  
6.2 Stratification  
Section B.4.6.1 of NFPA 72®, National Fire Alarm Code® (2002 Edition) states: “The potential for the stratification of smoke is  
another concern in designing and analyzing the response of detectors. This is of particular concern with the detection of low energy  
fires and fires in compartments with high ceilings.”  
Hot Fresh Air  
Stratification  
The upward movement of smoke in the plume depends on the smoke being buoyant relative to the surrounding air. Stratification  
occurs when the smoke or hot gases flowing from the fire fail to ascend to the smoke detectors mounted at a particular level (usually  
the ceiling) above the fire due to the loss of buoyancy. This phenomenon occurs due to the continuous entrapment of cooler air into  
the fire plume as it rises, resulting in cooling of the smoke and fire plume gases. The cooling of the plume results in a reduction of  
buoyancy. Eventually the plume cools to a point where its temperature equals that of the surrounding air and its buoyancy diminished  
to zero. Once this point of equilibrium is reached, the smoke will cease its upward flow and form a layer, maintaining its height above  
the fire, regardless of the ceiling height, unless and until sufficient additional thermal energy is provided from the fire to raise the layer  
due to its increased buoyancy. The maximum height to which the smoke will ascend, especially early in the development of a fire,  
depends on the convective heat release rate of the fire and the ambient temperature in the compartment.  
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6.3 Environmental Considerations  
6.3.1 Outdoor  
Beam smoke detectors are inappropriate for outdoor applications. Environmental conditions such as temperature extremes, bright  
sunlight, rain, freezing rain, snow, sleet, fog and dew can interfere with the proper operation of the detector. Outdoor conditions also  
make smoke behavior impossible to predict.  
6.3.2 Indoor  
Avoid sources of heat and air movement:  
• Don’t mount the detectors where hot or cold air can blow directly into the beam path.  
• Heating, ventilating, air conditioning systems and ceiling fans can cause smoke to be blown away from the projected beam.  
Smoke must accumulate in the projected beam to be detected.  
• Heaters mounted close to the projected beam path can cause the beam to be distorted.  
Avoid sources of bright light:  
• Sunlight. Avoid pointing the receiver directly at the rising or setting sun. If you are installing the unit where sunlight can’t be  
avoided, mount the receiver slightly higher than the transmitter and aimed down towards the transmitter. This should reduce the  
problem by causing the receiver to look below the horizon.  
Bright Lights. Although bright lights are generally not a problem, exposed bulbs of high pressure sodium, mercury vapor and  
metal halide should not be placed in close proximity to the receiver. Bare fluorescent lights may pose a problem in long hallways  
where a series of lights run perpendicular to the beam.  
6.4 Mounting  
Section 5.7.3.4.8 of NFPA 72®, National Fire Alarm Code® (2002 Edition) states: "The light path of projected beam-type detectors  
shall be kept clear of opaque obstacles at all times."  
Section A.5.7.3.4.8 of NFPA 72®, National Fire Alarm Code® (2002 Edition) states: "Where the light path of a projected beam-type  
detector is abruptly interrupted or obscured, the unit should not intiiate an alarm. It should give a trouble signal after verification of  
blockage."  
Because beam smoke detectors are line-of-sight devices which go into trouble on sudden and total loss of signal, care must be  
taken that all obstacles be kept clear of the beam path at all times.  
This requirement could make the use of beam smoke detectors impractical in factory applications where overhead cranes and hoists  
are present and in warehouses where high fork lifts may block the beam. This factor should also be considered in occupied areas  
where normal ceiling heights exist.  
Beam smoke detectors depend on the measurement of the projected beam to sense smoke. Therefore, shifts in the alignment of the  
beam due to movement of the transmitter or receiver can cause trouble or alarm conditions.  
• Always select a stable mounting surface. The walls and attached girders of steel-sided buildings (especially those walls facing the  
sun) may be very unstable throughout the day. A roof support girder may provide better support in this case.  
• Never mount the units to a suspended support such as a pipe or length of wood supported at only one end.  
• Never use mirrors to extend the beam around corners.  
• Never mount behind clear glass or plastic covers other than those supplied by Bosch with the detectors.  
• When mounting in high ceiling areas such as atriums, several mounting levels should be considered to account for stratification  
due to ceiling height or low energy fires.  
Multiple  
Level  
Mounting  
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6.5 Location and Spacing  
NFPA 72-2002®, 5.7.3.4.1 states: “Projected beam-type smoke detectors shall be located in accordance with the manufacturer’s  
documented instructions.” The D296 Series Projected Beam Detectors allow for a Range (distance between the Transmitter and  
Receiver) of 30 to 350 feet (9.1 to 106 meters) and a Spacing (the distance between systems) of up to 60 feet (18 meters).  
On smooth ceilings, a spacing of not more than 60 ft (18.3 m) between projected beams and not more than one-half that spacing  
between a projected beam and a sidewall (a wall parallel to the beam travel) should be used. Other spacing may be determined  
based on ceiling height, airflow characteristics and response requirements.  
In some cases, the transmitter is mounted on one end wall and the receiver is mounted on the opposite wall. It is also permitted to  
mount the transmitter and receiver up to one-quarter of the spacing distance away from the end walls.  
½ S  
Receiver  
¼ S  
Transmitter  
¼ S  
S
½ S  
Transmitter  
Receiver  
S = Selected detector spacing  
6.6 Ceilings  
6.6.1 Flat Ceilings  
For projected beam applications, a flat, smooth ceiling is considered to have a height of 12 ft (3.6 m) or lower, and beam or solid joist  
depths of 1 ft (0.3 m) or less. Open trusses that are less than 10% material and 90% open air are not considered to affect the flow  
of smoke. Smooth flat ceiling guidelines will apply where the trusses are used.  
Normal spacing may be used if the projected beams are running in the direction parallel to the run of the beams or solid joists.  
One-half spacing must be used if the projected beams are running at right angles to the run of the beams or solid joists.  
A Joist is considered to be a support that is 4 in. (100 mm) or more in depth and 3 ft (0.9 m) or less in spacing.  
A Beam is considered to be a support that is 4 in. (100 mm) or more in depth and 3 ft (0.9 m) or more in spacing.  
Transmitters  
½ S  
½ S  
Transmitter  
Receiver  
Ceiling beams (joists)  
S
Transmitter  
Receiver  
Receivers  
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If the ceiling beams (joists) exceed 1 ft (.03 m), the spacing between the beams exceeds 8 ft (2.4 m) or the ceiling height exceeds  
12 ft, the detectors must be located in every ceiling beam pocket.  
Transmitter  
Transmitter  
Receiver  
Ceiling beams (joists)  
Receiver  
Transmitter  
Receiver  
If the fire size is expected to exceed 1-MW (1000 KW), the ceiling height may be up to 28 ft before each beam pocket must be  
treated separately. It is recommended that you review Section B-2 Performance-Based Approach to Designing and Analyzing Fire  
Detection Systems in NFPA 72®, National Fire Alarm Code® (2002 Edition) to determine the potential fire size at the locaton.  
6.6.2 Sloped Ceilings  
Beamed ceilings with beams running parallel to (up) the slope, the spacing for flat beamed ceilings should be used. The ceiling  
height is considered the average height over the slope. For slopes greater than 10 degrees, the detectors located at one-half the  
spacing from the low end are not required. Spacing will be measured along a horizontal projection of the ceiling. For beamed  
ceilings with the beams running perpendicular to (across) the slope, the spacing for flat beamed ceilings should be used. One set  
of beams must be within 3 ft (1 m), measured horizontally, of the high point of the ceiling.  
3 ft.  
(1 m)  
Max.  
S
S
½ S  
Slope 10° or less  
3 ft.  
(1 m)  
Max.  
S
S
Slope greater than 10°  
Detector at ½ S not Required  
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6.6.3 Peaked Ceilings  
3 ft.  
(1 m)  
Max.  
Peaked structures follow the same  
guidelines as sloped ceilings with one  
exception: When calculating the  
location of the detectors, the first  
detector is within 3 ft (1 m) of the peak,  
measured horizontally. Additional  
detectors are spaced down from the  
detector near the peak.  
S
S
6.6.3 Long Ceilings  
Long ceilings over 350 ft (107 m) require more than one set of detectors to cover the entire  
length. To determine the number of detector sets required, divide the length of the ceiling by  
350 (107 if using metric standards) and round up to the nearest number. Locate the detector  
sets so that they cover an equal amount of area. Set the transmitters and receivers as  
shown to the right and below to avoid possible “cross-talk.” The minimum spacing between  
adjacent detectors is 1/10th of the distance between the transmitter and the receiver. For  
example, for a beam length of 300 ft (91.5 m), the minimum spacing is 30 ft (9.1 m).  
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7.0 Worksheet  
Be sure to include site features such as:  
• Support Beams (include direction)  
• Support posts  
• Peaks  
• Lights  
• Air handling units (HVAC)  
• Shelving  
• Anything suspended from the ceiling that might interfere with the beam  
• Directions (North, South, etc.)  
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Be sure to include site features such as:  
• Support beams  
• Ceiling height  
• Peaks  
Be sure to include site features such as:  
• Support beams  
• Ceiling height  
• Peaks  
© 2004 Bosch  
D296/D297 Series Projected Beam Smoke Detectors  
Application Guide  
130 Perinton Parkway, Fairport, New York, USA 14450-9199  
Customer Service: (800) 289-0096; Technical Support: (888) 886-6189  
P/N: F01U500951B 8/04  
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