RU2661858C1 - Method of registration of the time of sprinkler refitting movement (options) and device for its implementation - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: invention relates to the field of fire engineering, namely to control or indicator devices for determining the position of readiness of equipment and, in particular, to the methods, control and recording of the response time of firer sprinklers during their tests for temperature and response time. Method for recording the response time of the fire sprinkler includes monitoring the time from the start of the change in the temperature of the sprinkler surrounding the medium until the activation of the thermal fire sprinkler, and the moment of activation of the thermal lock of the fire sprinkler is determined by one of two ways of interaction between this sprinkler and a rod made of a non-conductive material or of an electrically conductive material with an outer surface covered with an insulating material, on which a metal ring is mounted in a certain position: contact with the end of the nozzle of the sprinkler, fixed immovably to the sprinkler, the metal ring of the piston moving vertically downward inside the nozzle of the sprinkler under the action of gravitational forces; by the fact of contact with the metal ring of the rod fixed immovably, the end of the nozzle of the sprinkler, moving vertically down the rod under the action of gravitational forces. Device for implementing the method for recording the response time of the fire sprinkler comprises a rod mounted inside the nozzle of the tested sprinkler, and a measuring and signaling system unit, wherein the rod is made of a non-conductive material or of an electrically conductive material with an outer surface covered with an insulating material, is provided with a metal ring adjustable along its length, the distance in the initial state between this ring and the end of the nozzle of the sprinkler is assumed to be non-contactable between them, the metal housing of the test sprinkler and the metal ring being connected to the input of the measuring and signaling system unit.

EFFECT: above methods and the device for carrying out the method for recording the fire sprinkler response time allow to automate the process of measuring the activation time of fire sprinklers when checking the temperature and the response time.

3 cl, 4 dwg

Description

The invention relates to the field of fire fighting equipment, and in particular to control or indicator devices for determining the readiness position of equipment and, in particular, to methods, monitoring and recording the response time of sprinkler sprinklers in the process of testing them for temperature and response time.

The most complete information about sprinklers, including sprinkler ones, is presented in the monograph “Sprinklers for water and foam automatic fire extinguishing systems” [L.M. Meshman, S.G. Tsarichenko, V.A. Bylinkin et al .; Under the total. ed. N.P. Kopylova. Teaching aid. - M .: VNIIPO, 2002. - 315 p.]. This manual provides a classification of irrigators (p. 9-12, 23-29), design features (p. 120-228), temporary (p. 76-99) and temperature (p. 60-61, 70-76) characteristics and various test methods of irrigators are described according to domestic, international and foreign regulatory documents, including methods for determining the temporal (p. 79-83, 92) and temperature (p. 73-76) parameters. Domestic test methods set forth in the training manual are enshrined in GOST R 51043-2002 “Automatic water and foam fire extinguishing installations. Sprinkler and deluge sprinklers. General technical requirements. Test Methods. "

According to paragraph 127 of the "List of national standards containing the rules and methods of research (testing) and measurements, including the rules for sampling, necessary for the application and implementation of the Federal Law" Technical Regulation on Fire Safety Requirements "and the implementation of conformity assessment" (see The order of the Government of the Russian Federation of March 10, 2009 No. 304-r (as amended by the order of the Government of the Russian Federation of June 11, 2015 No. 1092-r), as well as paragraphs 7.1 and 7.6 of GOST R 51043-2002, sprinklers must be mandatory suspension rush to certification tests.

One of the most important parameters characterizing the operational performance of traditional sprinkler sprinklers, which should be checked during these tests according to GOST R 51043-2002, is the temperature and response time. To reduce the total duration of the tests, several irrigators are tested simultaneously.

Checking the response temperature in accordance with GOST R 51043-2002 (paragraph 8.14) is carried out by heating the sprinklers in a liquid bath of the thermostat with a working fluid of at least 3 dm ³ for each sprinkler from a temperature of (20 ± 5) ° С until the heat lock will not collapse. The ratio of the size of the volume filled with the liquid (length x width x height), respectively (1: 1: 1) ± 20% or (diameter x height), respectively (1: 1) ± 20%. The response temperature must be within the limits of the nominal temperature (Clause 3.1.24), regulated by GOST R 51043-2002 (Clause 5.1.1.6).

The response time of the sprinkler sprinkler according to GOST R 51043-2002 (Clause 8.15) is carried out by placing the sprinkler at a temperature of (20 ± 2) ° С in a thermostat with an ambient temperature of (30 ± 2) ° С higher than the conditional response time . The response time of the sprinkler is counted from the moment it is placed in the thermostat until the activation of its thermal lock. This time should not exceed the standard nominal value given in GOST R 51043-2002 (subclauses 3.1.27 and 5.1.1.6).

Similar tests for the response temperature are provided by the international standard ISO 6182-1: 2014 “Fire protection. Automatic sprinkler systems. Part 1: Requirements and test methods for sprinklers)) - “Fire protection. Sprinkler fire extinguishing installations. Part 1: Technical requirements and test methods for sprinkler sprinklers "(p. 7.7.1) and UL 199" Standard for Automatic Sprinklers for Fire Protection Service)) - "Sprinkler sprinklers AUP (p. 7.1 and 18)." The sprinklers are placed upright in a ∅250 glass vessel, with a capacity of approximately 7 liters, and is almost completely filled with liquid. An electromechanical mixer is used to ensure uniform temperature. The temperature is measured with a thermometer; thermocouples can be used to control the temperature.

Checking the response time of the sprinkler sprinkler according to ISO 6182-1: 2014 (Clause 7.7.1) and UL 199 (Clauses 19.1-19.2) is carried out on a stand consisting of a closed box duct with a cross section of 203 × 203 mm, in which heated air flow. The air flow is heated in a heat chamber. The air speed is controlled by a damper. Excessive pressure in the pipeline is eliminated thanks to the outlet openings. To create a uniform flow rate in the working chamber in which the test sprinkler is installed, it is partitioned off on both sides with a fine mesh. The temperature of the heated air stream is controlled by a thermocouple.

It should be noted that the test procedure of the listed domestic and foreign standards does not provide for the automation of the test process, therefore, the fact of the activation of the sprinklers is established by the sound characteristic of the destruction of its thermal lock.

If the tests are carried out to determine the response temperature, it is necessary to note and record the temperature at which the sprinkler has triggered by a thermometer. Since several sprinklers are subjected to tests at the same time, the operator often does not have time to mark the response temperature on the thermometer. But even if the temperature is continuously recorded on a computer, without knowing the time of activation of the sprinkler, it is not possible to set the response temperature of each of the tested sprinklers.

Trigger sprinkler irrigation tests are carried out in a sealed chamber, the sound becomes poorly distinguishable and often commensurate with the background noise of the environment.

These circumstances require constant intense attention of the operator; therefore, errors determined by the human factor are not excluded during the testing process. In this case, the operator may notice that the sprinkler is triggered either prematurely, or vice versa, “blink” this time. When a limited number of sprinklers are supplied for testing, situations arise when due to the lack of additional sprinklers the dates of the planned tests are disrupted.

Often it is necessary to conduct comparative tests of sprinkler sprinklers of various manufacturers. These tests should be carried out simultaneously under identical conditions. In this case, “hearing” it is not possible to determine the response time of a particular sprinkler.

Known sprinkler sprinklers containing, as a rule, a nozzle with an outlet, a spray outlet mounted on the arms, a heat lock with a thermosensitive element that can be destroyed at a given threshold temperature (flask or soldered metal plates), which perform, in addition to the usual traditional functions of monitoring the ambient temperature and automatic actuation, also additionally functions of control of actuation of a sprinkler and remote start.

For example, in the "Sprinkler Sprinkler" [ed. testimonial. USSR No. 1443889 A1, IPC A62C 37/08, publ. 12.15.88] the control device for the operation of the sprinkler is made in the form of a tape rolled up on a spray socket, unwound with a stream of sprayed liquid when the sprinkler is triggered, which allows you to quickly visually identify triggered sprinklers and take measures for their rapid replacement.

In the "Sprinkler sprinkler" [Russian patent No. 2170125, IPC A62C 37/08 (2006.01), A62C 37/08 (2006.01), publ. 07/10/2001] a control device for activating the sprinkler, made in the form of a tape made of fireproof material and unwinding when the sprinkler is triggered, one end is fixed to the base, and the other end is attached to the outlet. Moreover, the roll is placed in a plate attached by flexible ties along one edge to the spray outlet, and on the opposite edge to the removable gasket, made mainly of acoustic emission material, placed between the destructible element and the locking unit.

All these devices provide visual fixation of the response of the sprinkler sprinkler, but do not allow the automatic indication of activation of its thermal lock, and therefore, accurately determine the duration of the sprinkler sprinkler.

Sprinkler sprinklers are known in which, when activated, a contact electric circuit is broken, which can be used to automate the testing of these sprinklers for time and response temperature.

For example, in the "Sprinkler sprinkler with controlled start" [Russian patent No. 2379080, IPC A62C 37/08 (2006.01), A62C 35/10 (2006.01), publ. 01/20/2010], "Sprinkler sprinkler with controlled start" [RF patent No. 2471524, IPC А62С 2/00, publ. 01/10/2013] and "Sprinkler sprinkler with controlled launch" [RF patent No. 2526705C1, IPC A62C 35/10 (2006.01), publ. 08.27.2014] the control device for the activation of the sprinkler includes a contact pair "shut-off valve - conical cup". Contact shut-off valve and cone cup are fastened together due to the tightening force of the heat-sensitive element. When the temperature-sensitive lock is triggered, the contact pair, under the action of the pressure of the extinguishing agent, falls out of the landing socket of the sprinkler sprinkler and breaks up, which corresponds to the opening of the contacts of the electric network.

Also known is the "System of household and fire water supply [ed. testimonial. USSR No. 1606133, IPC A62C 37/36, publ. 11/15/1990], in which the device for controlling the operation of the sprinkler sprinkler is a metal plate welded together between the thermal sprinkler of the sprinkler, isolated from the housing and connected in series with the help of conductors to the fire pump starting circuit. In the event of a fire under the influence of an elevated temperature, the thermal lock breaks, as a result of which the electric circuit breaks.

The well-known "Position sensor of a falling fire-fighting device" [Russian patent No. 2053823, А62С 37/00, publ. 02/10/1996]. The sensor is made with a housing, in the cavity of which there is an electrical circuit switch, and has a signal element in the form of an elastic plate, one of the end sections of which is connected to the housing and interacts with the electrical circuit switch, and the other with the valve lock of the water supply device. The housing can have a U-shape and holes in the walls through which an elastic plate is inserted into its cavity, interacting with the switch of the electric circuit.

The well-known "system of drinking water and fire water" [ed. testimonial. USSR No. 1174044, class A62C 32/04, publ. 08/23/1985], containing a water supply pipe, a fire and household drinking pumps, non-return valves and sprinkler sprinklers connected to the fire pipeline, the fire and domestic water pumps through the check valves are connected to the supply pipe, and sprinkler sprinklers are connected through the fire pipe to feed line. The sprinkler sprinkler is equipped with a valve held by a thermal lock. The electrically conductive element is mounted on the arms of the irrigator. When the sprinkler is activated, the electrically conductive element is destroyed, which is a signal to turn on the fire pump.

Known "Sprinkler sprinkler - Quick response sprinkler head" [patent US 5622225 A, publ. 04/22/1997], containing a thermal lock that operates at a given temperature, and an element made of metal with memory, changing its shape at a given temperature and turning on the electric circuit by contact with the conductive parts of the irrigator.

Known "Sprinkler-signaling device" [ed. testimonial. USSR No. 1690793 Al, А62С 37/10, publ. 15.11.1991], containing a nozzle with a channel in which a fitting is mounted on one side and a valve on the other hand, a lock with a disconnecting device, the elements of which are interconnected by a low-melting junction, a destructible wire-conducting signaling element in contact with a low-melting junction. In this case, the signaling element consists of an elastic rod element of the loop and is connected to the plates with its ends, electrically isolated from them, and the elastic rod element is placed in the loop and interacts with it movably.

Also known is the "Sprinkler-signaling device" [ed. testimonial. USSR No. 1553152 A1, cl. A62C 37/10, publ. 03/30/1990] containing a supply fitting, a housing with a fire extinguisher supply chamber, a lock, a signal device with contact moving means, the signal device being made three-position with means for setting a threshold pressure value, the contact moving means of the signal device is located in an additional chamber and is made in the form a spring-loaded cylinder with an elastic membrane and with two holes, one of which is located on the same axis with the channel, and the second in the lower part of the cylinder, and the elastic meme injury associated with contact of the signaling device, which is elastic.

The well-known "Sprinkler sprinkler with controlled launch" [Russian patent for utility model No. 80345U1, IPC A62C 2/00 (2006.01), publ. 02/10/2009], comprising a housing in which a shut-off valve is pressed through a sealing disc spring, a thermally decomposing sensitive element connected to a thermal heating element, with terminals for communication with a control power source, equipped with a normally closed contact group associated with the terminals of the thermal heating element. Moreover, the contact group is made in the form of a shut-off valve and a cone cup located between the shut-off valve and a thermally degradable sensing element, and the seating surface of the cone cup has a shape identical to the shape of the cone sample of the shut-off valve.

The well-known "Sprinkler sprinkler with visual indication" [Russian patent for utility model No. 112053U1, IPC A62C 2/00 (2006.01), publ. 01/10/2012], comprising a housing, an outlet in which closes a shut-off valve, a control unit for controlling the state of a shut-off valve, including a thermally decomposing sensing element, around which a heating element made in the form of a spiral is mounted, and a normally closed contact group. Moreover, the conclusions of the control unit and the state control of the shutoff valve are associated with the terminals of the control panel of the fire control and LED control, the conclusions of which are connected with the terminals of the control panel.

Sprinkler sprinkler works as follows. After carrying out work related to the installation of sprinklers or during their maintenance, an electrical signal is supplied from the receiving and monitoring firefighter and control device to the controlled sprinkler. The LED starts to glow, but the control unit and the state of the shut-off valve are not triggered, which allows you to visually verify the correct installation of the control line connecting the specific sprinkler to the fire alarm control panel and the integrity of this circuit. In the event of a fire, the actualization of this sprinkler is no different from the operation of a traditional sprinkler sprinkler.

The well-known "Sprinkler sprinkler" [patent of Russia №2339419, A62C 37/08, publ. November 27, 2008], in which a heat-sensitive fusible lock includes a housing in which there is an open space, a material melting at a low temperature, placed in an open space, an actuating pin supported by a heat-sensitive lock melting at a low temperature, as a result of which this pin provides support for the exhaust valve, an electric heater designed to heat the material melting at low temperature, and an electrical power line designed to supply electricity VA to the electric heater, while the power line contains a thermocouple for measuring temperature. The first and second conductors come into contact with each other. Moreover, the fuse includes a drum-shaped non-conductive housing. An electrical contact element is attached to the lower part or formed on the lower part of the housing and is electrically connected to the cathode wire connected to the negative pole. An anode wire attached to the positive pole is attached to the inner surface of the housing. In addition, a spiral electric heater is attached to the outer surface of the housing. One contact clamp (terminal, terminal) of the electric heater is connected to the electric contact element, while the other contact clamp of the electric heater is connected to the anode wire through material melting at low temperature. The outer surface of the electric heater, that is, the farthest part of the housing, is coated with a corrosion-resistant and insulating covering film, as a result of which the electric heater is protected. In this case, the electric heater is made of carbon paste or a metal film.

In another embodiment, the electric heating coil is inserted into a hollow cylindrical glass ampoule filled with heat-expanding gas or liquid. Each of the sprinkler sprinklers is connected to a temperature sensor. When the temperature sensor detects a fire, a current is applied to the fuse, as a result of the generated heat, the material melting at a low temperature melts, or the fluid capable of thermal expansion expands, so that the acting pin is displaced downward, or the bulb body is destroyed, resulting in outlet valve opens.

The well-known "Installation for extinguishing a fire" [Russian patent No. 2460560, A62C 35/00, A62C 37/08, publ. 09/10/2012], containing an automatic fire extinguishing agent feeder connected to a pipeline distribution network, and status and start-up control modules. The distribution network contains sprinkler sprinklers with controlled start-up and an addressable control panel for fire control. Each sprinkler sprinkler contains a socket, a housing with a disk spring, a shut-off valve, a thermally degradable sensing element and a normally closed contact group connected by leads to a thermally heated element located on the thermally sensitive element. The contact group is made in the form of a shut-off valve and a conical cup.

Known "Sprinkler head" [ed. USSR No. 1391665 A1, IPC 4 A62C 37/08, publ. 04/30/1988] containing a fitting, in the distribution hole of which there is a valve, a spray outlet mounted on the fitting, and a locking system for holding the valve, including levers fastened by a heat-sensitive lock made in the form of metal plates overlapped by a fusible joint, and it is additionally equipped the control unit for spontaneous displacement of the plates of the heat-sensitive lock, in which the joint of the metal plates is covered with insulating layers, inside of which is made in the form of oya metallographic paste sensor with leads for connection with an indicator.

The famous "Sprinkler sprinkler" [certificate. for a utility model of Russia No. 39497 U1, IPC 7 A62C 37/08, publ. 08/10/2004], comprising a housing at the outlet of which a diaphragm is installed, having an outlet opening closed by a valve pressed in the outlet by means of a locking device interfaced with a driving link connected to a heat-sensitive element made in the form of a plate made of a material with a shape memory effect . In this case, an electric heating element is connected in series with the electrical contact of the alarm circuit.

Irrigation operation can be carried out in two ways.

1. When the environment reaches the activation temperature of the sprinkler, the plate is twisted, made of a material with a shape memory effect, into a spiral. This twisting of the plate ultimately leads to the activation of the sprinkler and the switching of its contacts. In this case, the operation signal is sent to the alarm and control device.

2. On command from the outside, the supply voltage is supplied to the electric heating element. In this case, the heat-sensitive element of the sprinkler is heated, as a result of which a plate made of a material with a shape memory effect is twisted into a spiral, the sprinkler is activated, and a signal about its operation is sent to the signaling and control device.

In all of the above irrigators equipped with a trip control device, the cessation of current flow can be used to indicate the state of the irrigator - the irrigator has worked. Therefore, when conducting tests for temperature and response time, there are no automation problems - their contact group can be used to automatically determine the duration of operation of such sprinklers.

Activation control sprinkler sprinklers have a great future, but so far most of the millions of produced sprinklers are traditional, not equipped with actuation control, and therefore they cannot be used in their pure form when conducting automated tests for time and actuation temperature.

Known "Explosion suppression device" [ed. testimonial. USSR No. 571021, А62С 3/00, publ. 05/06/1977], comprising a hollow cylindrical body made of electrically conductive material with a piston located in it, a pyro-exciter and a spray mounted on opposite ends of the body, with several holes made along the length of the body, each of which has a measuring probe in the form of an insulated conductor, protruding into the internal cavity of the housing for a length greater than the radius of the hole, and the entire group of measuring probes is connected to an electronic unit for recording the hydrodynamic characteristics of the device.

Between the piston and the spray gun there is a fire extinguishing agent, separated from the explosive atmosphere of the technological apparatus by a separation membrane. The device operates as follows. Under the pressure of the gases generated when the pyroexciter is triggered, the piston creates high pressure in the cavity filled with the extinguishing agent. Under the action of high pressure, the separation membrane breaks in front of the numerous nozzle openings, as a result of which the piston moves, displacing the extinguishing agent. During movement, the piston alternately contacts the measuring probes, cuts them and closes them on the housing. The moment of contact is fixed by the measuring circuit. Knowing the volume of liquid between the measuring probes and determining the contact time, it is possible to calculate the rate of extinguishing agent as the piston moves.

The principle of recording the movement of the piston given in the explosive suppression device could be used for sprinklers equipped with a piston when registering their activation.

Numerous sprinkler sprinklers (mainly sprayers) are known in which the piston rod hermetically separates the high pressure chamber from the spray holes. When the thermal lock of the sprinkler sprinkler is triggered by the pressure of the extinguishing agent, the piston moves and opens the passage to the holes of the sprinkler.

Such devices include, for example, "Sprinkler sprayer - Sprinkler" [US patent No. 6347669 B1, publ. 02/19/2002], "High-pressure sprinkler sprays of the RVD type" (see. Technical conditions. High-pressure sprinkler and deluge sprays of the RVD type. TU 4854-134-00226827-2016. ZAO "Spetsavtomatika").

In "Sprinkler sprayer - Sprinkler" [US patent No. 6347669 B1, publ. 02/19/2002] a sleeve-like piston rod separates the high-pressure chambers from the spray holes.

Also known is "Sprinkler" [Russian patent No. 2409404, A62C 37/08, B05B 15/00, publ. 01/20/2011) containing a housing in which there is at least one nozzle, a heat-activated start-up element and a protective element that is in front of the nozzle in a protective position and mechanically protects the start-up element when the sprinkler is in an inactive mode, while the protective the element is configured to move to a second position in which the nozzle and the start element are not protected by a protective element. The sprinkler housing is movable relative to the mounting housing between two positions: the first position in which the sprinkler is inactive and the second position in which the sprinkler housing is extended, wherein the sprinkler housing is movable from the pressure of the medium relative to the mounting housing from the first position to the second position and at the same time with the possibility of directing efforts to the protective element to move it from the protective position to the second position, whereby the sprinkler is in the second dix housing sprinkler installed in ready mode.

Also known is the “Sprinkler with a thermosensitive flask” [US patent No. 6491110, IPC А62С 2/00], in which the flask is a closed hollow cylindrical glass shell filled with a liquid with a low boiling point, an electric heating coil placed in the shell, a negative electrode, formed on the outer surface of the lower end of the shell and connected to the first end of the winding; a positive electrode located on the outer surface of the side wall of the shell and connected to the second end of the winding.

The well-known "spray head and fire extinguishing system" [Russian patent No. 2077905, MPK7 A62C 37/08, A62C 37, publ. 04/27/1997], comprising a housing having a Central hole with a movable shaft-piston having a shoulder for the formation of an annular cavity between the shaft and the surrounding wall of the hole, which communicates with the corresponding supply line and has the same cross-sectional area as the end of the piston subjected the effects of fluid pressure prevailing in line. The spring force is designed to act on the piston in the release direction.

Known "Sprinkler sprinkler" [US patent No. 3525402, class. 169/40, 169/42 (IPC A62C 37/10, A62C 37/08), publ. 08/25/1970], comprising a housing with a central channel in communication with the supply line, at least one nozzle located inside the housing, and a gate mounted at the output of the central channel, characterized in that it comprises a shaft with a shoulder for movably mounted in the central channel of the housing the formation between the wall of the Central channel and the shaft of the annular compensating cavity in communication with the supply line, and a spring located in the housing with the possibility of impact on the shaft, while the cross-sectional area of the annular comp The sensing cavity is equal to the cross-sectional area of the shaft end exposed to the pressure of the fluid in the supply line.

It is known "Autonomous fire extinguishing and signaling device" [patent of Russia №2245730, А62С 37/08, publ. 02/10/2005], containing thermosensitive elements made of a material with thermomechanical shape memory and equipped with two pairs of permanent magnets connected by the same poles, each of which is placed in a corresponding housing, is mounted on a corresponding head loaded in its direction from a non-magnetic material rod, loaded with a spring, installed in the guides of the housing. The rod head has a through hole, each of the rods is equipped with a fuse made in the form of a cotter pin installed in the through hole of the rod head.

Each pair of permanent magnets is installed with the possibility of interaction with the corresponding inductor located in the magnetic support, and two corresponding pairs of permanent magnets with reed switch blocks, each of which is installed with the possibility of its reed switches falling into the range of the corresponding pair of permanent magnets. Each of the normally open contacts of the first and second reed switches of the first block of reed switches is connected to one of the contacts of the inductance coil of the second pair of permanent magnets. Each of the normally open contacts of the first and second reed switches of the second reed switch unit is connected to one of the contacts of the inductance coil of the first pair of permanent magnets. The outputs of the first and second reed switches are connected in pairs to the contacts of the fire extinguisher. Each of the third reed switch blocks is built-in through a normally closed contact and output to one of the loops. Each of the thermosensitive elements is installed in a corresponding housing with the possibility of releasing the heads of the corresponding rod covered by it.

If the temperature in the zone of location of the temperature-sensitive element rises to the threshold, then the temperature-sensitive element, diverging, releases the rod head. A pair of magnets fixed on the rod, passing through the inductor, generates a current pulse that passes through the already closed contacts of the first and second reed switches of the first block, so the fire extinguishing system is activated.

When the reed switches of the second block get into the field of a pair of magnets, the previously opened contacts of the first and second reed switches of the second block are closed and the previously closed contact of the third reed switch opens. As a result of opening a previously closed contact of the third reed switch, a signal will appear on the remote control about the operation of the heat-sensitive element and the autonomous fire extinguishing device as a whole.

The disadvantages of the sprinklers (and sprayers) equipped with a piston considered above include the inability to control the state of both the sprinkler itself and the state of the electrical circuit, i.e. there is no principal possibility of remote determination of the fact of the sprinkler actuation, since in the design of these sprinklers there are no elements of remote control that make it possible to unambiguously determine the fact of activation of the sprinkler.

Closest to the claimed methods and device for the totality of signs is "Autonomous fire extinguishing device" [Russian patent No. 2198007, IPC A62C 37/08, publ. 02/10/2003], taken as a prototype of the claimed technical solution. The device comprises a housing with radiation detectors mounted on it, each of which is made in the form of a parabolic mirror reflector, in the focal plane of which a thermosensitive element of material with a thermomechanical shape memory is installed in the form of a curved plate, and the plates are mechanically connected to electric switches and pistons that overlap the pneumatic system supply of extinguishing medium, rotary nozzles, nozzles for supplying extinguishing medium to the ignition zone and is electrically connected to an electric switch it electrical power and fire risk object electrochain fire alarm.

In the event of a fire, the corresponding parabolic reflector directed towards it focuses the radiant energy onto the curved part of the plate of material with a thermomechanical memory. When the plate is heated, it extends and it releases the piston, which, moving, opens the inlet of the device for the release of extinguishing agent. In this case, the switch switches normally open contacts of the fire alarm circuit.

The disadvantages of this "Autonomous fire extinguishing device" include the following:

- a fairly complex design of the electrical circuit of the fire alarm circuit;

- the complexity, complexity and practical impossibility of equipping each tested sprinkler with a similar electrical switch.

The purpose of the proposed technical solution is to enable registration of activation of sprinkler sprinklers during testing for temperature and response time.

The essence of the proposed method (p. 1 of the claims) consists in the fact that in the method for recording the response time of the sprinkler sprinkler, which includes monitoring the time from the moment the temperature of the surrounding sprinkler starts to change until the sprinkler sprinkler irrigation lock is activated, the activation moment of the sprinkler sprinkler irrigation lock is determined upon contact with the end face of the fitting, fixed fixed irrigator, a metal ring mounted in a certain position on the rod from a non-conductive material or from an electrically conductive material with an outer surface coated with an insulating material, and moving vertically downward under the influence of gravitational forces inside the sprinkler nozzle when the heat-sensitive bulb of the thermal lock of the sprinkler sprinkler is destroyed.

The essence of the proposed method (according to claim 2 of the claims) consists in the fact that in the method for recording the response time of the sprinkler sprinkler, which includes monitoring the time from the moment the temperature of the sprinkler sprinkler starts to change until the sprinkler sprinkler sprinkler thermal lock is activated, the sprinkler sprinkler sprinkler thermal lock activation time is determined upon contact with a metal ring mounted in a certain position on a fixed shaft fixed from non-conductive m material or from an electrically conductive material with an external surface coated with an insulating material, moving under the influence of gravitational forces during the destruction of the heat-sensitive flask of its thermal lock vertically down this sprinkler rod.

The technical effect realized by the claimed methods of recording the response time of the sprinkler sprinkler allows:

- determine the activation time of each of the tested sprinkler sprinklers when they are jointly tested for time or temperature response;

- provide automation of the test process;

- identify activated sprinkler sprinkler.

The essence of the claimed device lies in the fact that in the device for implementing the method for recording the response time of the sprinkler sprinkler, which includes a rod installed inside the nozzle of the test sprinkler, and a measuring and signal system unit, the rod is made of non-conductive material or of an electrically conductive material with a coated insulating material the outer surface is equipped with a metal ring adjustable along its length, and the distance in the initial state between this ring and t The nozzle of the sprinkler nozzle is received without contact between them, while the metal housing of the test sprinkler and the metal ring are connected to the input of the measuring and signal system unit.

The technical effect realized by the claimed device for implementing the method for recording the response time of the sprinkler sprinkler allows:

- significantly simplify the device that provides automation of the test process when determining the response time of the tested sprinkler sprinklers when testing for time or temperature response;

- to ensure the universality of the design for a wide range of types of sprinkler sprinklers when determining the activation time of the tested sprinkler sprinklers when testing for time or temperature response;

- eliminate errors inherent in the human factor when registering activation of sprinkler irrigators.

When determining the conformity of the distinguishing features of the invention with the criterion of “inventive step”, the prior art and, in particular, known methods and devices related to the field of fire fighting equipment, in particular, to control or indicator devices for determining the readiness position of the equipment and, in particular, to methods, control and registration of the response time of sprinkler sprinklers in the process of testing them for temperature and response time.

Thus, the distinguishing features of the proposed technical solution are new and meet the criterion of "novelty."

Analysis of other technical solutions showed that the known methods and devices do not solve the above problems, solved by the claimed technical solution. The prior art does not reveal technical solutions, the hallmarks of which provide a solution to the problem.

Based on the foregoing, we can conclude that the claimed technical solution meets the criterion of "inventive step", and the invention itself is new.

In FIG. 1 and 3 show devices prior to operation of the sprinkler sprinkler, in FIG. 2 and 4 - after its operation.

The device contains a test sprinkler sprinkler 1, equipped with a thermal lock (heat-sensitive bulb 2 with a shut-off valve 3), a rod 4 with a diameter slightly smaller than the inner diameter of the nozzle 5 of the test sprinkler 1. The rod 4 can be made solid or hollow of non-conductive material or of electrically conductive material with an external surface coated with insulating material and equipped with a metal ring 6 adjustable along its length. Fitting 5 of the test sprinkler 1 and an adjustable metal ring 6 tzo conductors 8 connected to the input unit and the signal measuring system 9.

The number of simultaneously tested irrigators is not limited.

During testing, the sprinkler sprinkler 1 is placed in a thermostat (not shown in Fig. 1-4) and, depending on the design of the test equipment, the rod 4 is installed in the nozzle 5 on top (Fig. 1-2) or in the nozzle 5 from the bottom (Fig. 3- 4) the test sprinkler 1.

Before the test, the metal ring 6 is installed in such a way that its contact with the end face of the nozzle 5 is not allowed. During the test, when the sprinkler sprinklers are fixedly mounted, the shutoff valve 3 can hang on the screw 7, with the fixed rods, the shutoff valve 3 can hang directly on the end of the rod 4 Therefore, with an excessively large distance between the end face of the nozzle 5 and the metal ring 6, when the thermal lock is activated, there will be no contact between them. Given these circumstances, it is sufficient that the distance between the end face of the nozzle 5 and the metal ring 6 is (3-5) mm.

The metal case (in this case, nozzle 5) of the test sprinkler 1 and an adjustable metal ring 6 are connected by conductors 8 to the input of the measuring and signal system unit 9.

While testing several sprinklers simultaneously, their case and the metal ring of each rod are connected by their conductors to the corresponding input of the measuring and signal system unit (not shown in Figs. 1-4).

If, when testing the sprinkler (s), the rod 4 is placed below the sprinkler 1, then for stability of the measuring rod 4 it can be placed in the latch 10 (Fig. 3-4).

If the purpose of the tests is to check the response time, the tested sprinkler sprinklers are placed in an air thermostat, in which during the entire test cycle a temperature is maintained that exceeds their rated response temperature by 30 ° C. At the same time, the chronometer starts and the heating of the heat lock of the heat-sensitive bulb of the heat lock of the irrigator begins. When the thermosensitive flask reaches the nominal operating temperature, the irrigation thermal lock is activated, i.e. the first sprinkler is triggered, and then the other sprinklers are alternately triggered.

Moreover, if the rod 4 is located above the sprinkler 1 (Fig. 1-2), then it falls inside the nozzle 5 of the sprinkler 1 until the ring 6 rests on the end of the nozzle 5, if the measuring rod 4 is located under the sprinkler 1 (Fig. 3-4) , then the sprinkler 1 is lowered along the measuring rod 4 until the end of the fitting 5 abuts against the ring 6.

When the ring 6 contacts the end of the nozzle 5, the conductors 8 are connected, connected to the unit of the measuring and signal system 9. The unit of the measuring and signal system 9 registers the response time of each sprinkler and the temperature of the thermostat. At the same time, the same block 9 gives out sound and light alarms about the operation of each sprinkler.

If the purpose of the tests is to check the response temperature, then the N-number of tested sprinkler sprinklers are placed in a thermostat filled with liquid (liquid bath) at an initial temperature of 20 ° C. From this moment begins the countdown, heating the liquid and registering the temperature in the liquid bath.

After some time, in the process of increasing the temperature, a thermal lock is activated (the thermosensitive flask 2 is destroyed, as a result of which the shut-off valve 3 is released), i.e. the first sprinkler is triggered, and then the other sprinklers are alternately triggered. Moreover, if the rod 4 is located above the sprinkler 1 (Fig. 1-2), then it falls inside the nozzle 5 of the sprinkler 1 until the ring 6 rests on the end of the nozzle 5, if the measuring rod 4 is located under the sprinkler 1 (Fig. 3-4) , then the sprinkler 1 is lowered along the measuring rod 4 until the end of the fitting 5 abuts against the ring 6.

Upon contact of the ring 6 with the end face of the nozzle 5, the conductors 7 are connected, connected to the block of the measuring and signal system 9. The block of the measuring and signal system 9 registers the temperature of the liquid medium surrounding the test sprinklers at the time of operation of each sprinkler. At the same time, the same block 9 gives out sound and light alarms about the operation of each sprinkler.

Claims (3)

1. The method of recording the response time of the sprinkler sprinkler, including controlling the time from the moment the temperature of the surrounding sprinkler starts to change until the sprinkler sprinkler sprinkler lock is activated, characterized in that the moment of sprinkler sprinkler sprinkler activation is determined by the fact of contact with the end of the nozzle fixed to the sprinkler, a metal ring mounted in the initial state on the rod in such a way that its contact with the end face of the fitting is not allowed, and with erzhen made of non-conductive material or a conductive material coated with insulating material the outer surface and moves under the influence of gravitational forces vertically downwardly within nozzle sprinkler fracture thermosensitive bulb thermal lock sprinkler. 2. A method for recording the response time of the sprinkler sprinkler, including controlling the time from the moment the temperature of the surrounding sprinkler starts to change until the sprinkler sprinkler sprinkler is activated, characterized in that the moment of sprinkler sprinkler sprinkler activation is determined by the contact of the sprinkler nozzle with a metal ring installed in the initial state on the fixed rod so that its contact with the end face of the fitting is not allowed, and the rod olnen of non-conductive material or of an electrically conductive material coated with insulating material the external surface and the sprinkler is moved under the action of gravitational forces fracture the thermosensitive bulb thermal lock vertically downwards on the rod. 3. A device for implementing a method for recording the response time of a sprinkler sprinkler, comprising a rod installed inside the nozzle of the test sprinkler, and a measuring and signal system unit, characterized in that the rod is made of a non-conductive material or an electrically conductive material with an external surface coated with an insulating material, equipped with an adjustable along its length with a metal ring, and the distance in the initial state between this ring and the end of the sprinkler fitting is not taken up to OSCAL contact between them, with the metal housing of the test sprinkler and the metal ring connected to the input of the measuring and signaling system.

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