RU2671122C1 - Method of fire protection of warehouses with shelf storage and signal-starting standalone automatic device for implementing method - Google Patents

Abstract

FIELD: fire safety.SUBSTANCE: method of fire protection of warehouses with shelf storage and the signal-starting standalone automatic device for implementing the method relate to to the field of automatic fire-fighting systems with water-filled sprinkler networks, including with the use of water spray. Method involves the early detection of fire through the use of at least four spatially separated temperature sensors in each controlled area of the warehouse, connected to a separate device, a signaling autonomous automotor that performs: fire detection, automatic start-up of a controlled sprinkler.EFFECT: device is able to work as part of a group of devices, to perform a start-up delay, to be adjusted to the necessary operating conditions.8 cl, 6 dwg

Description

The invention relates to methods for fire protection of storage facilities with shelving, including the implementation of the preferred method of protecting the warehouse, and to a device that provides the implementation of protection methods.

The invention is known that relates to dry ceiling sprinkler systems and fire extinguishing methods (patent RU 2430762), designed to protect the shelving warehouse.

Dry sprinkler systems include dry pipe distribution networks with sprinkler sprinklers installed in them.

When a dry pipe system detects heat from a fire, the corresponding sprinkler is opened, releasing air from the distribution network, which reduces air pressure and activates the water supply, allowing water to fill the distribution network and exit through the opened sprinklers.

A disadvantage of the known system is the presence of a time delay from the moment the fire is detected to the supply of the extinguishing agent to the source of ignition; the delay is caused by the fact that it takes a certain time for air to escape from the network and to fill the network with a fire extinguishing substance (water).

A device for extinguishing fires in storage shelves with shelving (patent RU 2403929), containing sprinkler sprinklers with an electric start and a liquid flow alarm, located on the distribution pipe, which runs in the upper part of the rack at a distance that opens the torch of sprayed jets to the width of the rack, while a screen in the form of a broken plane or a hemisphere is installed above the distribution pipeline for heat accumulation with a peak above the center of the rack, and the projection of the screen and the rack on the mountains zontally plane are equal.

In the above device, it is possible to use a water-filled distribution network, which, in comparison with the distribution networks of dry sprinkler systems, is less inertial.

It should be noted that in the device, the initial operation of the fire extinguishing system comes from a sprinkler sprinkler, which has a thermocouple and a trigger device from an electric signal, by destroying the thermocouple under the influence of heat accumulated under the screen, which serves as the beginning of fire extinguishing, while the trigger device from the electrical signal for sprinklers is used in other sprinklers devices to form a group of triggered sprinklers.

Sprinkler sprinklers, automatically activated by means of their heat-sensitive lock, for example, thermoballs, are inferior in their sensitivity and inertia to special thermal fire detectors.

The disadvantage of this device is the significant inertia caused by the inertia of the destructible thermal lock (thermal bulb) of the sprinkler sprinkler used to start the fire extinguishing system.

Additional disadvantages of the device that reduce efficiency include:

- the inability to delay the start of the fire extinguishing system;

- the lack of ability to control the start of sprinklers through the remote control or automatically from less inertial fire detection systems;

- lack of control of electrical circuits for starting a controlled sprinkler sprinkler;

- limited selection of fire extinguishing media.

The aim of the invention is to increase the efficiency of protection of shelving warehouses from fire: due to earlier detection of fire, taking into account the production conditions of the warehouses, due to timely notification of a fire, by expanding the capabilities of controlling a fire extinguishing system using a control panel and other automatic means, due to control serviceability of starting and signal circuits.

In the proposed method of fire protection, which can be used in warehouses with shelf storage, there are stages in which:

- carry out early fire detection by using in one controlled area protected by one fire extinguishing device, at least four spatially separated temperature sensors that are connected to a signal-starting autonomous automatic device installed in the zone, while using the device’s microcontroller they generate a notification about fire provided that at least two of the four sensors are triggered simultaneously, in addition, each temperature sensor in the device by programming the microcontroller of the device, depending on the specific production conditions, it forms a certain type of fire detector having the property of maximum thermal, or differential thermal, or maximum differential thermal, or thermal with a differential characteristic;

- identify the place of occurrence of a fire by turning on the light and sound siren of a signal-starting autonomous automatic device with the formation of a fire notification transmitted via a fire alarm loop to a fire alarm control panel (or to a dispatcher's console);

- they automatically form the Start command by the signal-starting autonomous automatic control device and transmit it via the signal line to the corresponding fire extinguishing device, while the fire extinguishing device can be: sprinkler sprinkler with pyrotechnic electrically controlled drive, or sprinkler (spray) deluge with valve which has an electromechanical drive, or a powder fire extinguishing module, or an aerosol fire extinguishing module;

- provide, by means of a remote control and a signal-starting autonomous automatic device, manual remote control of the “Start” operation for all fire extinguishing devices;

- provide, by means of a signal-starting autonomous device, a delay in the automatic start of the fire extinguishing means;

- provide, through the control circuit for blocking and stopping the start-up, a signal-starting autonomous automatic delay of starting the fire extinguishing means from the device of the security control and fire alarm device;

- provide automatic triggering of a group of signal-starting autonomous automatic devices and starting their corresponding fire extinguishing devices;

- provide, by means of a signal-starting autonomous automatic device, control of an alarm loop and fire-extinguishing device start-up circuits.

The method using finely divided water involves the steps in which:

- Mount the distribution network directly above the racks along the entire length of the rack;

- Mount the distribution pipeline over the shelves with a width of 2.6 m in one thread in the center of the rack;

- mount sprinkler nozzles at a distance of (1.7 ± 0.1) m from the top of the stored goods, while the distance between the nozzles along the length of the pipeline should be (2.5 ± 0.1) m;

- install the distribution pipeline over the racks with a width of 3.1 m in two threads in the center of each paired rack, a number of nozzles in each thread are made in uniform increments (2.5 ± 0.1) m, while a row in one thread relative to a row in another thread shifted by half a step (checkerboard pattern);

- mount screens of galvanized profiled steel with a thickness of at least 0.5 mm (or other non-combustible materials) parallel to the floor surface above the distribution pipelines, while the screen is U-shaped and does not go beyond the dimensions of the rack, and the side walls have a height of at least 200 mm each;

- sprinkler nozzles are placed on distribution pipelines under the screen, while using nozzles with a temperature of operation of 68 ° C, the diameter of the thermosensitive flask is not more than 3 mm;

- install pyrotechnic electrically controlled drives on sprinkler nozzles, consisting of a removable bracket with a squib cartridge, the electric igniter of which is connected to the corresponding signal-starting autonomous automatic device located nearby;

- mount the signal-starting autonomous automatic devices in the immediate vicinity of the corresponding atomizer, while the thermosensitive sensors of the device should be distributed evenly in the four areas adjacent to the atomizer.

The most preferred in the proposed method with sprayers seems to use for fire extinguishing sprinkler sprayers with a pyrotechnic electrically controlled drive, pressurized sprinkler network, using finely sprayed water. The implementation of the preferred method involves the implementation of additional steps in which:

- provide a minimum pressure of the dictating sprinkler nozzle in the operating mode of at least 0.6 MPa;

- determine the estimated water flow from the condition of the simultaneous operation of four sprinkler nozzles located in the "dictating" zone (at the point of the protected room farthest from the pump station), while ensuring a water supply duration of at least 30 minutes, a spray coefficient of at least 0.217.

A method using more productive irrigators involves the steps in which:

- Mount the distribution pipe under the shelves up to 2.6 m wide in one thread in the center of the rack;

- they install a distribution pipeline over paired racks with a total width of up to 3.5 m into two threads passing through the center of each rack, the sprinkler spacing from adjacent strings relative to each other is shifted by half a step (staggered order);

- mount sprinkler sprinklers on distribution pipelines from the top of the stored cargo by selecting irrigation diagrams for a specific type of sprinkler, taking into account at least 90% of the extinguishing agent dispersed from the sprinkler along the width of the rack, while the distance between the sprinklers along the length of the pipeline should be equal to the width of the rack;

- use sprinkler sprinklers with a response temperature of 68 ° with the diameter of the thermosensitive flask, taken from a number of 2.5 mm, 3.0 mm, 5.0 mm.

To implement the preferred method of protecting the shelving warehouse, an autonomous signal-starting device is proposed, capable of adapting to operating conditions using the controls, including adaptation of temperature sensors, capable of carrying out various fire extinguishing modes together with the device by the security control and fire alarm and remote control, having the ability to form extinguishing agent groups of different sizes, duplicate (reserve), and delay the controlled launch of fire extinguishing agents.

The implementation of the preferred method is achieved by the fact that a signal-starting autonomous device is implemented for implementing the method of fire protection of warehouses, in which an electronic module is made, connecting: an autonomous power source, sirens, the “Control” button to check the operability of the device and the “Programming” button to configure parameters, a microcontroller, while the module is equipped with connectors and pressure glands with the ability to connect to them: a fire alarm loop, c no more than four automatic locking and stopping start-up circuits, start-up circuits of the electric (their) actuator (s) for starting the sprinkler (s), remote start control circuits, communication circuits with external heat sensors

The most preferred embodiment of a signal-starting autonomous automatic device for protecting shelving warehouses is a case consisting of a cover and a base with three sealed cable entries and an electronic module mounted on the base, which is a printed circuit board, with the compartment with sources installed on it battery power supply, LED indicator, sound emitter, control buttons "Control" and "Programming", microcontrol eryom, electronic components of the electrical circuit, groups of screw connectors located near the corresponding sealed cable entries, with the ability to connect using the connectors and inputs: the corresponding external control circuits and alarm loop of the control and fire alarm device, control panel, start-up control circuits of the electric drive ( s) sprinkler (s) sprinkler (s) and communication circuits with external heat sensors in an amount of at least four, located in adjacent to the device four areas.

In addition, the electronic module is configured to program the temperature sensors corresponding to the operation of fire detectors using the “Control” and “Programming” buttons, depending on production conditions, characterized as: maximum heat detectors, or differential thermal, or maximum - differential, or thermal with differential characteristic.

In addition, the electronic module is configured to configure the following device parameters using the “Control” and “Programming” buttons under the necessary operating conditions:

- start delay time, sec .;

- maximum temperature of operation (start) С °;

- time of recording the history, min .;

- time of blocking sensors, sec .;

- type of actuator (electric igniter pyrotechnic drive or electric ball valve with sprinkler);

- the duration of the start pulse of the pyrotechnic drive, sec .;

- extinguishing time (open state of ball valve with sprinkler), min .;

- operation mode (single start or local group start, or general group start).

The device is explained in more detail using:

FIG. 1 is a block diagram of a device for forcing sprinklers;

FIG. 2 is a combined diagram of a preferred embodiment for rack warehouses of an irrigation forced-launch device;

FIG. 3 is a view from the transverse side of the rack with a width of 2.6 m;

FIG. 4 - layout of the distribution pipeline, sprinklers, alarm and start-up devices with sensors above the rack (2.6 m.);

FIG. 5 is a view from the transverse side of a twin rack with a width of 3.1 m;

FIG. 6 is an arrangement diagram of distribution pipelines, sprinklers, alarm and start-up devices with sensors above a paired rack.

The device for forced start of irrigators (see Fig. 1) has an electronic module A1, in which an autonomous power supply source 1, a light indicator 2, a sound emitter 3 are connected to the microcontroller 4, which is connected to the “Control” button SB1 and the SB2 “button Programming ”, at the same time, the locking control circuit and the start stop, the fire alarm loop circuit of the alarm control and fire alarm device A2 of the fire extinguishing device can be connected to the electronic module by means of the hermetic input 5 and connectors X1.1 ... X1.10 Nation, to the electronic module through the pressure gland 6 and connectors X2.1 ... X2.m, the starting circuits of the start-up electric drives B1, ... Bm with the corresponding sprinkler sprinklers СО1, ... COm can be connected to the electronic module through the pressure input 7 and the connectors X3.1 ... X3 .10 the A3 remote control and the group of remote heat sensors BK1, ... BK4 can be connected.

The choice of the number of forcedly controlled irrigators and their corresponding electric drives in each specific case is determined by the design decision for the fire extinguishing installation, while the necessary energy consumption of the autonomous power supply source and the output power of the electronic keys of the microcontroller supplying the electric drive are specified.

The device operates as follows.

In standby mode, in the absence of fire after a certain period of time, the microcontroller automatically checks the operability of the device. When it is operational, the microcontroller gives a light notification with the help of indicator 2, a one-time light signal informing that the device is in standby mode. In the event of a malfunction, the microcontroller uses the light indicator 2 and the sound emitter 3 to periodically display signals (“Failure”), in addition, these signals are transmitted through connectors X1 to device A2.

When the SB1 (“Control”) button is pressed, the microcontroller checks the condition of source 1, remote sensor circuits BK1, ... BK4, and start-up circuits of the electric drive (s).

Depending on their condition, when detecting temperature changes in the protected object that are characteristic of a fire, the microcontroller sets the fire hazard levels (“Standby mode”, “Fire 1”, “Fire 2”). If a fire is detected in the protected object (if the temperature of the protected object exceeded the maximum normal and reached the level of fire danger “Fire 2”, the device generates a signal “Fire 2” (intermittent sound and intermittent light) and with a time delay of 5 s. (Or 30 s. ) generates the Start control signal to the actuator (electric drive B1, ... Bm).

The control signal is generated by issuing the inrush current by the microcontroller to the output contacts of the screw connector X2 to connect the electric drives B1, ... Bm.

To remotely control or lock the device, voltage must be applied to the “remote control” input of connector X3 or to the “BL” input of connector X1.

Consideration of a preferred embodiment of a signal-starting autonomous automatic device (see FIG. 2) allows us to show in detail the device design and external communications characterizing the device’s functionality.

The device has a housing consisting of a cover 8, a base 9, a printed circuit board 10 mounted on the base, an autonomous power supply battery compartment 1 made on a printed circuit board, a siren indicator 2 LED and a siren emitter 3, control buttons SB1 ("Control" ) and SB2 (“Programming”), microcontroller 4, electronic components 11 boards, a group of screw connectors XI with a pressure input 5 for connecting to the device A2, a group of screw connectors X2 with a pressure input 6 for connecting to an electric drive B1 from a sprinkler m sprinkler CO1, a group of screw connectors X3 with a pressure gland 7 for connecting a remote control A3 and external heat sensors BK1, ... BK4.

It should be noted that the proposed design allows using the combined pressing of the SB1 button (“Control”) and the SB2 button (“Programming”) to configure the device parameters such as:

- start delay time, sec .;

- maximum temperature of operation (start) С °;

- time of recording the history, min .;

- time of blocking the sensors by pressing the buttons SB1 and SB2, sec .;

- formation of a differential thermal channel;

- type of actuator (electric igniter pyrotechnic drive or electric ball valve with sprinkler);

- the duration of the start pulse of the pyrotechnic drive, sec .;

- extinguishing time (open state of ball valve with sprinkler), min .;

- operation mode (single start or local group start, or general group start).

Thus, the proposed device will allow using the controls (buttons SB1, SB2) to adapt to the operating conditions and carry out various fire extinguishing modes together with the fire alarm and remote control panel, having the ability to form extinguishing groups of different sizes and duplicate ( reserve) controlled launch of extinguishing media.

The above new features increase the reliability and efficiency of the device and the entire fire extinguishing installation in which the proposed device is used.

Fire protection methods are illustrated by drawings, where in FIG. 3-7 schematically illustrates the equipment of shelving warehouses.

The drawings indicate: a screen 12, a distribution pipe 13, a sprinkler sprinkler 14 with a thermal bulb with an electrically controlled pyrotechnic actuator installed next to it, which is made according to the patent of the Russian Federation No. 155310, temperature sensors 15, a self-starting automatic signaling device 16, a rack 17 , stored cargo 18.

The protection method is designed for use under a working pressure distribution pipe 13 with installed sprinkler sprinklers with controlled start-up 14, each sprinkler having its own signal-starting autonomous automatic 16 along with temperature sensors 15, which are installed under the screen 12 and are located close to the device moreover, four temperature sensors 15 of each device monitor four areas adjacent to the sprinkler. The screen is designed to accumulate heat fluxes (and / or combustion products) that occur during a fire. When the automatic alarm trigger device is activated, the corresponding sprinkler is forcedly launched and a signal is sent to respond to the fire alarm loop through the fire alarm loop (or to the control panel). At the same time, over distribution racks with a width of 2.6 m, the distribution pipeline is mounted in one string, and sprinklers are distributed in increments of 2.5 m evenly over the entire length. Above the twin racks with a total width of 3.1 m, the pipeline is mounted in two threads, and the sprinklers in each thread are evenly distributed in increments of 2.5 m, but the sprinklers in one thread are shifted half a step relative to the sprinklers in the other thread.

Based on the analysis of a new method of fire protection of shelving warehouses and a new device for its implementation, it can be argued that the proposed method and device can expand the arsenal of means for fighting fires, reduce the time to detect a fire by using more sensitive and adapted to operating conditions thermal sensors, increase effectiveness of fire protection of the protected facility.

Claims (38)

1. A method of fire protection of warehouses with shelf storage, comprising stages in which: - carry out early fire detection by using at least four spatially separated temperature sensors in one monitored area protected by one fire extinguishing device, which are connected to a signal-starting autonomous automatic device installed in the zone, while using the device’s microcontroller they generate a fire warning provided that at least two of the four sensors are triggered simultaneously, in addition, previously each temperature sensor in the device by programming the microcontroller of the device, depending on the specific production conditions, forms a certain type of fire detector having the property of maximum thermal, or differential thermal, or maximum differential thermal, or thermal with a differential characteristic; - identify the place of occurrence of a fire by turning on the light and sound siren of a signal-starting autonomous automatic device with the formation of a fire notification transmitted via a fire alarm loop to a fire alarm control panel (or to a dispatcher's console); - they automatically form the Start command by the signal-starting autonomous automatic control device and transmit it via the signal line to the corresponding fire extinguishing device, while the fire extinguishing device can be: sprinkler sprinkler with pyrotechnic electrically controlled drive, or sprinkler (spray) deluge with valve which has an electromechanical drive, or a powder fire extinguishing module, or an aerosol fire extinguishing module; - provide, through the remote control and the signal-starting autonomous automatic device, manual remote control of the “Start” operation for all fire extinguishing devices; - provide, by means of a signal-starting autonomous device, a delay in the automatic start of the fire extinguishing means; - provide, through the control circuit for blocking and stopping the start-up, a signal-starting autonomous automatic delay of starting the fire extinguishing means from the device of the security control and fire alarm device; - provide automatic triggering of a group of signal-starting autonomous automatic devices and starting their corresponding fire extinguishing devices; - provide, by means of a signal-starting autonomous automatic device, control of an alarm loop and fire-extinguishing device start circuits. 2. The method according to p. 1, characterized in that it further comprises stages in which: - Mount the distribution network directly above the racks along the entire length of the rack; - Mount the distribution pipeline over the shelves with a width of 2.6 m in one thread in the center of the rack; - mount sprinkler nozzles at a distance of 1.7 ± 0.1 m from the top of the stored goods, while the distance between the nozzles along the length of the pipeline should be 2.5 ± 0.1 m; - install the distribution pipe over the racks with a width of 3.1 m in two threads in the center of each paired rack, the row of nozzles in each thread is made in uniform increments of 2.5 ± 0.1 m, while the row in one thread relative to the row in the other thread is shifted by half step (checkerboard pattern); they install parallel screens of the floor over distribution pipelines of galvanized profiled steel with a thickness of at least 0.5 mm (or other non-combustible materials), while the screen is U-shaped and does not go beyond the dimensions of the rack and the side walls have a height of at least 200 mm each ; - sprinkler nozzles are placed on distribution pipelines under the screen, while using nozzles with a temperature of operation of 68 ° C, the diameter of the thermosensitive flask is not more than 3 mm; - install pyrotechnic electrically controlled drives, consisting of an arm with a pyro cartridge, on the sprinkler nozzles, the electric igniter of which is connected to the corresponding signal-starting autonomous automatic device located nearby; - mount the signal-starting autonomous automatic devices in the immediate vicinity of the corresponding atomizer, while the thermosensitive sensors of the device should be distributed evenly in the four areas adjacent to the atomizer. 3. The method according to p. 1, characterized in that it contains stages in which: - Mount the distribution pipe under the shelves up to 2.6 m wide in one thread in the center of the rack; - they install a distribution pipeline over paired racks with a total width of up to 3.5 m into two strings extending in the center of each rack, the sprinkler spacing from adjacent strings relative to each other is shifted by half a step (checkerboard pattern); - mount sprinkler sprinklers on distribution pipelines from the top of the stored cargo by selecting irrigation diagrams for a specific type of sprinkler, taking into account at least 90% of the extinguishing agent dispersed from the sprinkler along the width of the rack, while the distance between the sprinklers along the length of the pipeline should be equal to the width of the rack; - use sprinkler sprinklers with a response temperature of 68 ° with the diameter of the thermosensitive flask, taken from a number of 2.5 mm, 3.0 mm, 5.0 mm. 4. The method according to p. 2, characterized in that it further comprises stages in which: - provide a minimum pressure of the dictating sprinkler nozzle in the operating mode of at least 0.6 MPa; - determine the estimated water flow from the condition of the simultaneous operation of four sprinkler nozzles located in the "dictating" zone (at the point of the room that is farthest from the pump station), while ensuring a water supply duration of at least 30 minutes, a spray rate of at least 0.217. 5. The automatic signal-starting device for implementing the method of fire protection of warehouses contains an electronic module that connects: an autonomous power source, sirens, a “Control” button for checking the device’s operability and a “Programming” button for setting parameters, a microcontroller, while the module is equipped with connectors and hermetic inputs with the ability to connect to them: a fire alarm loop, automatic blocking and stopping start circuits, electric starting circuits (and x) drive (s) for starting the sprinkler (s), remote start control circuits, communication circuits with external heat sensors in an amount of at least four. 6. Autonomous signal-starting device for fire protection of warehouses according to claim 5, characterized in that it is a housing consisting of a cover and base with three sealed cable entries and an electronic module mounted on the base, which is a printed circuit board, with installed on it: compartment with battery power sources, LED indicator, sound emitter, control buttons "Control" and "Programming", microcontroller, electronic components electrical circuit, by groups of screw connectors located near the corresponding hermetic cable entries, with the possibility of connecting with the connectors and inputs: the corresponding external control circuits and alarm loop of the control and fire alarm device, control panel, start-up control circuits of the electric sprinkler drive (s) ( s) sprinkler (s) and communication circuits with external heat sensors in an amount of at least four, located in four areas adjacent to the device. 7. Autonomous signal-starting automatic device for fire protection of warehouses according to claim 6, characterized in that the electronic module is additionally configured to use the “Control” and “Programming” buttons to program the temperature sensors parameters corresponding to the operation of fire detectors, depending on production conditions characterized as: maximum thermal detectors, or differential thermal, or maximum differential, or thermal with differential characteristic . 8. Autonomous signal-starting device for fire protection of warehouses according to claim 6, characterized in that the electronic module is additionally configured to configure the following device parameters using the “Control” and “Programming” buttons: - start delay time, s; - maximum temperature of operation (start), ° C; - time to record the history, min; - time blocking sensors, s; - type of actuator (electric igniter pyrotechnic drive or electric ball valve with sprinkler); - the duration of the start pulse of the pyrotechnic drive, s; - extinguishing time (open state of a ball valve with a sprinkler), min; - operation mode (single start-up, or local-group start-up, or general group start-up).

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