RU68158U1 - FIRE DETECTION DEVICE - Google Patents

Abstract

The utility model relates to fire alarms, and more specifically to fire detection devices.

The objective of the utility model is to expand the functionality of the device for fire detection.

The technical result achieved by the implementation of the inventive utility model is expressed in the creation of an automatic suction device that provides early detection of a fire due to several related factors.

Description

The utility model relates to fire alarms, and more specifically to fire detection devices.

Fire detectors are known for detecting a fire due to several related factors. A device for detecting fire [1] is known, which reacts to the appearance of two factors, for example, smoke, as well as an elevated temperature at the facility. This detector contains first and second sensors, outputs connected to the corresponding inputs of the first and second signal processing units, the first outputs of which are connected to the first and second inputs of the OR logic element, the second outputs of the first and second signal processing units are connected to the first and second inputs of the logical the "And" element, the output of which is connected to the third input of the "And" logical element, the output of which is connected to the input of the alarm notification generator.

When the detector is working, the combination of smoke and heat detection channels is carried out according to the 2I-OR logic circuit. At the same time, the formation of the “Fire” notice occurs when any controlled parameter (concentration of smoke particles or temperature) reaches the corresponding high threshold, as well as when both controlled parameters of other, lower threshold values are reached.

The disadvantage of the device [1] is that the fire is detected only at the place of its location, while the detected factors must naturally reach this place by the convection-diffusion path, which significantly increases the total time of fire detection from the moment it occurs. The use of such "point" fire detectors is ineffective in facilities with a complex configuration of equipment and materials, high ceilings, in the presence of branched networks of power cables behind a false ceiling or under a raised floor, as well as in specific conditions of exposure to aggressive environments or radiation. This narrows the functionality of the device [1].

Closest to the claimed utility model is a device for fire detection ASD-PRO company "Sistem-Sensor" [2], a block diagram of which is presented in figure 1. The device comprises an intake pipe with openings connected through an air filter to the inlet of the measuring chamber, in which there is a smoke detector, an aspirator, an anemometer, a signal processing unit, a control unit, an indication unit, and an alarm notification generator. The output of the smoke detector is connected through the signal processing unit to the first input of the control unit,

the first output of which is connected to the input of the display unit, and the second output is connected to the input of the alarm notification generator. The outlet of the measuring chamber through an aspirator is connected to an anemometer, the electrical output of which is connected to the second input of the control unit.

The principle of operation of the prototype device is the forced sampling of air from the protected space through the intake pipe with openings and smoke detection using a highly sensitive smoke sensor.

The use of this device reduces the time of fire detection compared to the device [1] primarily due to the "cumulative" detection, when air is taken remotely from many points within the protected zone [3].

The disadvantage of the device [2] is the limited functionality associated with its detection of a fire only on one basis - smoke, which does not allow its use in facilities where this factor is not dominant.

The objective of this utility model is to expand the functionality of a device for fire detection.

The technical result achieved by the implementation of the inventive utility model is expressed in the creation of an automatic suction device that provides early detection of a fire due to several related factors.

The specified technical problem is solved due to the fact that the known device contains a prototype containing an aspirator, anemometer, a signal processing unit, a control unit, an indication unit and an alarm notification shaper, an intake pipe with openings connected through an air filter to the inlet of the measuring chamber, which contains a smoke sensor, the output of which is connected to the first input of the signal processing unit, the first output of which is connected to the first, the input of the control unit, the first output of which is connected to the input of the ind Ikation, and the second output is connected to the input of the alarm notification generator, the outlet of the measuring chamber through an aspirator is connected to an anemometer, the electrical output of which is connected to the second input of the control unit, a temperature sensor and a gas sensor located in the measuring chamber, a logic unit, and outputs of the temperature sensor are introduced and the gas sensor are connected respectively to the second and third inputs of the signal processing unit, the second and third outputs of which are connected respectively to the third and fourth inputs of the unit Eye control, the first, second and third outputs of the signal processing unit are connected to the corresponding inputs of the logical unit, the output of which is connected to the fifth input of the control unit.

Figure 2 shows a block diagram of the inventive device for detecting fire. The device comprises an intake pipe with holes 1, an indication unit 2, a logic unit 3, an air filter 4, an alarm driver 5, a control unit 6, a signal processing unit 7, a measuring chamber 8, an aspirator 9, an anemometer 10. The signal processing unit 7 contains a unit the signal processing of the smoke sensor 11, the signal processing unit of the temperature sensor 12 and the signal processing unit of the gas sensor 13. In the measuring chamber 8 there is a smoke sensor 14, a temperature sensor 15 and a gas sensor 16.

The intake pipe with holes 1 is connected through an air filter 4 to the inlet of the measuring chamber 8, in which there is a smoke sensor, 14, a temperature sensor 15 and a gas sensor 16, the outputs of which are connected to the first, second and third inputs of the signal processing unit 7, the first output which is connected to the first input of the control unit 6, the first output of which is connected to the input of the display unit 2, and the second output is connected to the input of the alarm notification generator 5, the outlet of the measuring chamber 8 through an aspirate OR 9 is connected to an anemometer 10, the electrical output of which is connected to the second input of the control unit 6, the outputs of the temperature sensor 15 and the gas sensor 16 are connected respectively to the second and third inputs of the signal processing unit 7, the second and third outputs of which are connected to the third and fourth inputs, respectively control unit 6, the first, second and third signal processing units 7 are connected to the corresponding inputs of the logical unit 3, the output of which is connected to the fifth input of the control unit 6.

The first input of the signal processing unit 7 is the input of the signal processing unit of the smoke sensor 11, the first output of the signal processing unit 7 is the output of the signal processing unit of the smoke sensor 11, the second input of the signal processing unit 7 is the input of the signal processing unit of the temperature sensor 12, the second output of the signal processing unit 7 is the output of the signal processing unit of the temperature sensor 12, the third input of the signal processing unit 7 is the input of the signal processing unit of the gas sensor 13, the third output of the signal processing unit 7 is the output Lok processing gas sensor 13.

To achieve a technical result when implementing a utility model, the following options for the technical implementation of individual blocks can be used.

Intake pipe with holes 1, display unit 2, air filter 4, alarm generator 5, control unit 6, signal processing unit 7, measuring chamber 8, aspirator 9, anemometer 10, smoke sensor 9 can be performed similarly to the prototype device [2 ]. This device uses a commercially available smoke analog smoke detector as a smoke detector.

IP 212-73 (PROFI-O). Similarly, commercially available fire detectors for temperature and gaseous products with an analog output can be used as temperature sensors [4]. The logical unit 3 can be performed on digital logic elements similarly to the device [1].

The functions performed by these blocks will be clear from the further description of the operation of the claimed utility model.

A device for detecting fire works as follows.

In the standby mode of operation, air through the holes in the intake pipe 1 under the action of the aspirator 9 enters the measuring chamber 8 with the sensors placed therein. The aspirator 9 is a suction device made in the form of a fan that creates a vacuum. An external filter traps large dust particles, ensuring stable operation of the device when it is used in dusty rooms.

The absence of output signals from the sensors in the absence of fire is displayed using the light indicators of the display unit 2, as well as the notification "Norm" transmitted by the shaper of the alarm notification 5.

The occurrence of a fire is accompanied by the appearance of concomitant factors. Practically, for all types of fire, and (or) smoke, heat, gaseous products (for example, СО, СО ₂ ) of different intensities are released. Their appearance in the measuring chamber leads to the appearance of electric signals at the output of the sensors 14-16, which are converted in the signal processing unit 7 into a form convenient for analysis and transmitted to the control unit 6, where they are compared with the set threshold values. If these values are exceeded by the signal of at least one sensor, the device displays the alarm state using display unit 2, the alarm notification generator 5 transmits a fire signal to the fire alarm system and (or) fire extinguishing system. Thus, the OR logic is implemented to detect fire factors by the device. Logic block 3 can implement the majority of logic “two out of three” or logic “3I” when signals from the outputs of the sensors have lower values than the threshold values set in block 6.

Such a construction of the device can increase the likelihood of detecting both a fire in which one of the detected factors is dominant - smoke, heat or gas, and a fire in which these factors are present, but not sufficiently intense.

Using an anemometer 10 installed in front of the outlet of the device, the air flow rate is controlled. This parameter determines the flow rate of the analyzed medium and is important for establishing the required sensitivity and maintaining it.

at a given level during operation. An electrical signal corresponding to the air velocity is generated by the anemometer 10 and transmitted to the control unit 6, which compares this signal with two set (upper and lower) threshold values, similar to the prototype device. When the signal value is between the upper and lower threshold values, the display unit 2 using the light indicators shows the normal value of the air speed. When the controlled speed value goes beyond the set limits for various reasons, in particular, due to a malfunction of the aspirator 9, the corresponding indicator in the display unit 2 lights up and an alarm notification is generated by block 5.

The ability to detect a fire by several concomitant factors as a result of forced air intake and its analysis in a special measuring chamber allows to increase the reliability of fire detection while reducing the detection time, which extends the functionality of the device.

The device according to this utility model can be used in fire alarm systems for installation in hard-to-reach places, at facilities with a complex configuration and operating conditions, without a permanent presence of people.

INFORMATION SOURCES:

1. UK patent No. 2 169 734A, CL IPC G08B 17/00, 1986.

2. Neplokhov I.G. Aspiration detectors: classification and characteristics. // Security systems. - M .: Grotek. No. 1 (73) 2007 - S.92 - 98.

3. Recommendations for the design of fire alarm systems using suction smoke detectors LASD and ASD series. - M .: VNIIPO, 2006.

4. Fire automatics 2007. Catalog.- M .: // Security industry. 2007 - 208 p.

Claims (2)

1. A device for detecting fire, comprising an aspirator, an anemometer, a signal processing unit, a control unit, an indication unit and an alarm driver, an intake pipe with openings connected through an air filter to the inlet of the measuring chamber, in which there is a smoke detector, the output of which is connected to the first input of the signal processing unit, the first output of which is connected to the first input of the control unit, the first output of which is connected to the input of the display unit, and the second output is connected to the input For alarm notification, the outlet of the measuring chamber through an aspirator is connected to an anemometer, the electrical output of which is connected to the second input of the control unit, characterized in that it is equipped with a temperature sensor and a gas sensor located in the measuring chamber, and a logic unit, the outputs of the temperature sensor and sensor gas are connected respectively to the second and third inputs of the signal processing unit, the second and third outputs of which are connected respectively to the third and fourth inputs of the control unit, ne The first, second and third outputs of the signal processing unit are connected to the corresponding inputs of the logical unit, the output of which is connected to the fifth input of the control unit. 2. The device according to claim 1, characterized in that the signal processing unit comprises a smoke sensor signal processing unit, a temperature sensor signal processing unit and a gas sensor signal processing unit, the first input of the signal processing unit is the input of the smoke sensor signal processing unit, the first output of the unit the signal processing unit is the output of the smoke sensor signal processing unit, the second input of the signal processing unit is the input of the temperature sensor signal processing unit, the second output of the signal processing unit is the output of the processing unit the temperature sensor signal, the third input of the signal processing unit is the input of the gas sensor signal processing unit, the third output of the signal processing unit is the output of the gas sensor signal processing unit.