RU2807440C1 - Fire detector testing stand - Google Patents

Abstract

FIELD: fire-fighting equipment.

SUBSTANCE: invention relates to stands for studying and monitoring various fire detectors in conditions close to a real fire and combustion. The stand for testing fire detectors comprises a rectangular measuring chamber with an inspection window, inside which thermal and/or smoke and/or flame fire detectors are placed in mounting sockets adapted for horizontal movement along rails fixed to the ceiling of the measuring chamber. As a test flame source, gas burners were used, configured for remote ignition, located at the bottom of the chamber on both sides of the electric heater, on which a steel sheet was laid to place a sample of combustible material on it. A supply fan is located in the lower part of the end wall of the chamber, and an exhaust fan is installed on the ceiling, near the opposite end wall, which is the chamber door. The supply and exhaust fans, as well as the electric heater and gas burners are connected to the control panel. Fire detectors are connected to a fire alarm control device, the outputs of which are connected to the negative contacts of the windings of n electromagnetic relays, the positive contacts of the windings of which and one contact of their keys are connected to the positive terminal of the power supply, and the second contact of each key is connected to the input of the controller, to which a temperature sensor and a gas analyser for CO, O₂ and CO₂ gases located inside the measuring chamber and a screen located outside the chamber are connected. The fire alarm control unit and the controller are connected to a DC power supply.

EFFECT: expanding the range of devices for testing fire detectors.

1 cl, 1 dwg

Description

The invention relates to fire-fighting equipment, in particular to stands for research and control of smoke, heat and flame fire detectors and can be used to determine the response delay time and the probability of fire detectors operating in conditions close to a real fire and ignition.

A known chamber for testing fire detectors [RU 2168214 C2, IPC G08B29/20 (2000.01), publ. 05.27.2001], containing a fan, an air flow equalizer, an air flow speed sensor, a temperature sensor, and electric heaters. The chamber is made in the form of two coaxial cylindrical pipes made of heat-insulating material located one inside the other, wherein the outer pipe has a heat-insulating bottom and cover, and in the inner pipe an air flow equalizer, an air flow speed sensor, a temperature sensor and on it are installed sequentially along the air flow. The detectors being tested are installed on the inner surface in a plane perpendicular to the chamber axis, at the same distance from each other. Electric heaters are located in the annular space below the level of the tested detectors and symmetrically relative to the common axis of the chamber, and the fan is located in the lower part of the chamber and its axis is aligned with the axis of the chamber.

In this chamber, ascending heat flows are simulated, which makes it possible to test fire detectors that respond only to the thermal radiation of electric heaters.

A device for testing smoke fire detectors [RU 2284579 C2, IPC G08B17/103 (2006.01), G08B29/00 (2006.01), publ. 03/10/2006], containing a smoke generator connected to a measuring chamber, inside of which there are fans, sockets for smoke fire detectors, emitter and photodetector units electrically connected to the smoke meter. Sockets for smoke detectors are evenly installed on the surfaces of the measuring chamber. The emitter and photodetector blocks are located nearby and a reflector is installed at the maximum distance from them with the ability to receive the optical signal emitted by the emitter block and transmit the reflected optical signal to the photodetector block with subsequent conversion of the optical signal into an electrical signal, while an exhaust fan is introduced to remove smoke from the measuring chamber .

In the measuring chamber of such a device, only smoke formation is simulated, which makes it possible to test only smoke fire detectors.

A known stand for testing thermal fire detectors [RU 2110843 C1, IPC G08B17/00 (1995.01), G01K 19/00 (1995.01), publ. 05.10.1998], containing a hollow housing, installed in the housing sequentially along the direction of the heat flow, an electric fan connected to the fan control unit, an electric heater connected to the heater control unit, a heat flow equalization unit, a tested fire detector connected to a recording device, and a temperature sensor , connected to another recording device. Between the heat flow equalization unit and the fire detector being tested there is a heat flow modulator, made in the form of a cover disk with calibrated holes, driven into rotation by an electric motor, in turn connected to the disk rotation control unit.

Such a stand allows you to evaluate the performance characteristics of only one type of fire detectors - thermal. In addition, the physical and chemical processes occurring inside the stand itself are far from real fires and combustions, which leads to inaccurately recorded characteristics of the detectors.

A known stand for testing fire flame detectors [RU 122512 U1, IPC G08B29/00 (2006.01), publ. 11.27.2012], selected as a prototype, containing a measuring chamber, inside of which there is a test source, sockets for installation and electrical connection of fire detectors, equidistant from the test flame source. A light-tight partition is installed between the test flame source and the sockets with the possibility of passing the light flux to fire flame detectors. A control ionization chamber is connected to one of the sockets, and a smoke optical density meter is installed in the coverage area of the fire detectors.

This stand allows you to evaluate the performance of only one type of fire detector - flame.

The technical result of the invention is to expand the arsenal of technical means for testing fire detectors.

The stand for testing fire detectors, as in the prototype, contains a rectangular measuring chamber, inside of which there are mounting sockets for placing fire flame detectors and a test flame source.

According to the invention, the measuring chamber is made with an observation window; heat and/or smoke and/or flame fire detectors are placed in mounting sockets made with the possibility of horizontal movement along rails fixed to the ceiling of the measuring chamber. As a test flame source, gas burners were used, configured with the possibility of remote ignition, located at the bottom of the chamber on both sides of the electric heater, on which a steel sheet was laid to place a sample of combustible material on it. A supply fan is located in the lower part of the end wall of the chamber, and an exhaust fan is installed on the ceiling, near the opposite end wall, which is the chamber door. The supply and exhaust fans, as well as the electric heater and gas burners are connected to the control panel. Fire detectors are connected to a fire alarm control device, the outputs of which are connected to the negative contacts of the windings of n electromagnetic relays, the positive contacts of the windings of which and one contact of their keys are connected to the positive terminal of the power supply, and the second contact of each key is connected to the input of the controller, to which a temperature sensor and a gas analyzer for CO, O2 and CO2 gases located inside the measuring chamber, and a screen located outside the chamber are connected. The fire alarm control unit and the controller are connected to a DC power supply.

In comparison with the prototype, the proposed invention allows testing, as well as determining the response delay times and the probability of operation of different types of fire detectors: heat, smoke and flame detectors in conditions close to real fires and ignitions in the premises.

In fig. Figure 1 shows a diagram of a stand for testing fire detectors.

The stand for testing fire detectors contains a rectangular measuring chamber 1 with an observation window 2 made of heat-resistant glass. The tested thermal and/or smoke and/or flame fire detectors 3 are placed in the corresponding mounting sockets, designed to move horizontally along rails mounted on the ceiling in the measuring chamber 1. Temperature sensor 4 (DT) and gas analyzer 5 (G), containing sensors gases CO, O ₂ and CO ₂ are located inside the measuring chamber 1. In the measuring chamber 1, a supply fan 6 is located in the lower part of its end wall, and an exhaust fan 8 is installed on the ceiling, near the opposite end wall, which is the door 7 of chamber 1. At the bottom of the measuring chamber 1, in its center, an electric heater 9 is installed, on which a steel sheet 10 is laid to place a sample of combustible material 11 on it. Gas burners 12 are installed on both sides of the electric heater 9, configured with the possibility of remote piezo ignition. Supply fans 6 and exhaust fans 8, as well as an electric heater 9 and two gas burners 12 are connected to a control panel 13 (PU) . Fire detectors 3 are connected to a fire alarm control device 14 (UUPS), the outputs of which are connected to the negative contacts of the windings of n electromagnetic relays 15. The positive contacts of the windings of n electromagnetic relays 15 and one contact of their keys are connected to the positive terminal of the DC power supply 16 ( BP). The second contact of each key is connected to the input of controller 17 (K). Temperature sensor 4 (DT) and gas analyzer 5 (G) are connected to the controller input 17 (K), and screen 18 (E) is connected to the controller output. The fire alarm control device 14 (UUPS) and the controller 17 (K) are connected to the DC power supply 16 (BP).

The main elements of the stand can be used: temperature sensor 4 (DT) - thermocouple; gas analyzer 5 (G) - stationary gas analyzer of the Senson-SV-5023 type; control panel 13 (PU) - control panel PKT-80PS; Fire alarm control device 14 (UUPS) - signal-20M fire alarm and reception control device; electromagnetic relay 15 - electromagnetic relay PLC-RSC-12DC/21; controller 17 (K) - Aries PLC63; screen 18 (E) - graphic monochrome panel Aries IP320; DC power supply 16 (BP) - power supply RIP-12.

The stand works as follows. The door 7 of the chamber 1 is opened, after which a flammable material 11 is placed on the steel sheet 10, for example, pieces of wood or linoleum, or cardboard or other flammable material. From the DC power supply 16 (BP), voltage is supplied to the fire alarm control device 14 (UUPS), the controller 17 (K) and n electromagnetic relays 15. Using the control panel 13 (PU), either the electric heater 9 or gas burners with remote piezo ignition 12 depending on the required fire initiation mechanism. Through the viewing window 2, the process of combustion of flammable material 11 is visually monitored. At the same time, an electrical signal is sent from the control panel 13 (PU) to the controller 17 (K) to start testing n fire detectors 3, either of the same type (heat, smoke or flame) or different types. To monitor the state of the gas environment inside the stand, signals from temperature sensor 4 (DT) and gas analyzer 5 (G) are sent to controller 17 (K). When fire detectors 3 are triggered, the signal from them is sent to the input of the fire alarm control device 14 (UUPS), which sends a signal to the winding of the corresponding electromagnetic relay 15, the number of which corresponds to the number of fire detectors 3 installed in the measuring chamber 1 n. The signal from the corresponding The key of the electromagnetic relay 15 is supplied to the input of the controller 17 (K). After the test is completed, the control panel 13 (PU) sends an electrical signal to the controller 17 (K), as well as a signal to turn off the electric heater 9 or gas burners with remote piezo ignition 12, as well as to turn on the supply 6 and exhaust 8 fans. Using controller 17 (K), the operating characteristics of fire detectors 3 are recorded: the average response delay time and the probability of fire detectors triggering. The average response delay time is determined by the controller 17 (K) as the arithmetic average of the response times of all activated fire detectors 3 of the same type according to the formula:

t = ( t ₁ + t ₂ +…+ t _m )/ m ,

where m is the number of activated fire detectors of the same type;

t ₁ , t ₂ , t _m is the response delay time of the corresponding fire detector (time is counted from the moment an electrical signal is sent to controller 17 (K) about the start of the test from control panel 13 (PU) until the corresponding fire detector 3 is triggered).

The probability of triggering fire detectors 3 of one type is calculated using controller 17 (K) according to the formula:

P = m / k⋅ 100%,

where m is the number of activated fire detectors of the same type;

k is the total number of fire detectors of the same type.

After this, the values of the response delay times ( t ), the probability of response ( P ) of fire detectors, as well as the maximum values of temperature and concentration of gas components inside the stand are displayed on screen 18 (E), which allows us to draw a conclusion about the best type of fire detectors (based on the lowest value the average response delay time and/or the highest response probability value) for the fire initiation mechanism considered during the test, as well as the type or combination of types of combustible materials.

Claims (1)

A stand for testing fire detectors, containing a rectangular measuring chamber, inside of which there are nests for placing fire flame detectors and a test flame source, characterized in that the measuring chamber is made with an observation window, thermal and/or smoke, and/or flame fire detectors are placed in mounting sockets made with the possibility of horizontal movement along rails fixed to the ceiling of the measuring chamber, and gas burners are used as a test flame source, configured with the possibility of remote ignition, located at the bottom of the chamber on both sides of the electric heater, on which a steel sheet is laid for placing a sample of flammable material on it, a supply fan is placed in the lower part of the end wall of the chamber, and an exhaust fan is installed on the ceiling near the opposite end wall, which is the chamber door, supply and exhaust fans, as well as an electric heater and gas burners are connected to the control panel, firefighters the detectors are connected to a fire alarm control device, the outputs of which are connected to the negative contacts of the windings of n electromagnetic relays, the positive contacts of the windings of which and one contact of their keys are connected to the positive terminal of the power supply, and the second contact of each key is connected to the input of the controller to which they are connected a temperature sensor and a gas analyzer for CO, O ₂ and CO ₂ gases located inside the measuring chamber, and a screen located outside the chamber, while the fire alarm control unit and the controller are connected to a DC power supply.