EA013858B1 - Alarm valve (embodiments) - Google Patents

Abstract

The invention relates to fire safety engineering, fire protection facilities, water and foam fire extinguishing automatic installations. The inventive purpose is to develop a shut-off, an alarm-starting control device. An alarm valve comprises a body with supplying, feeding, working cavities and a membrane mechanism. According to the first embodiment the feeding cavity directly contacts supplying and working cavities at 90° and also adapted to interact with the membrane mechanism sealing a seat arranged in the upper part of the supplying cavity. According to the second embodiment there provided two feeding cavities made coaxial, symmetrical along horizontal, with axes perpendicular to the supplying cavity axis, said feeding cavities directly contact at 90° with the supplying and working cavities and also adapted to interact with the membrane mechanism sealing a seat arranged in the upper part of the supplying cavity. According to the third embodiment there provided three feeding cavities two of them made coaxial, symmetrical along horizontal, and an axis of the third feeding cavity is perpendicular to axes of two said feeding cavities, wherein said feeding cavities directly contact at 90° with the supplying and working cavities and also adapted to interact with the membrane mechanism sealing a seat arranged in the upper part of the supplying cavity

Description

The technical field to which the object of the invention relates is fire fighting equipment, fire safety, automatic water and foam fire extinguishing installations. Appointment: locking, signal-starting control units.

The closest and only analogue is the BKM quick-acting membrane type sprinkler-deluge valve TU 2509-40-78 III [1], in which the supply and supply cavities of the valve are in the same vertical line (manufacturer of the Minsk Spetsavtomatika plant).

The set of features of the prototype type of signal valve: sprinkler-drencher;

type of control unit: sprinkler, deluge;

design parameters: supply cavity, supply cavity, shutter drive mechanism; cavity direction: straight (both cavities on the same axis).

Existing designs of the sprinkler-drencher type of signal valves in automatic fire extinguishing systems perform either a sprinkler or deluge type of fire extinguishing and provide the standard flow rate of a fire extinguishing substance in one pipeline.

The technical task set by the author of the invention is to develop a design of a device of reduced dimensions and reduced material consumption. The second technical task is to create a device design of reduced dimensions and reduced material consumption with new properties, namely the ability to simultaneously perform sprinkler-drencher type of automatic fire extinguishing.

The task in the first version of the signal valve, comprising a housing in which the supply, supply and working cavities and the membrane mechanism are made, is solved by the fact that the supply cavity is in direct contact at an angle of 90 ° with the supply and working cavities, and is also designed to interact with the membrane mechanism sealing the saddle mounted in the upper part of the supply cavity.

The tasks in the second version of the signal valve, comprising a housing in which the supply, supply and working cavities and the membrane mechanism are made, are solved by the fact that two supply cavities are made in its body, made coaxial, symmetrical horizontally, with axes perpendicular to the axis of the input cavity moreover, these feed cavities directly contact at an angle of 90 ° with the supply and working cavities, and are also designed to interact with a membrane mechanism that seals the saddle mounted in the upper parts of the delivery cavity.

The tasks in the third version of the signal valve, comprising a housing in which the supply, supply and working cavities and the membrane mechanism are made, are solved by the fact that three supply cavities with axes perpendicular to the axis of the input cavity, two of which are coaxial, symmetrical, are made in its body horizontally, and the axis of the third supply cavity is perpendicular to the axes of the two supply cavities, and these supply cavities directly contact at an angle of 90 ° with the supply and working cavities, as well as made for interaction with the membrane mechanism, which seals the saddle mounted in the upper part of the supply cavity.

The signal valve in all embodiments can be made with an additional supply cavity for operation, regardless of the membrane mechanism located in the lower part of the supply cavity.

Examples of the implementation of the inventive valve are presented in the drawings.

FIG. 1 is an example implementation of the first embodiment of the claimed invention with one supply cavity at an angle of 90 ° to the axis of the supply cavity.

FIG. 2 is an example implementation of a second embodiment of the claimed invention with two feed cavities.

FIG. 3 is an example of the implementation of the third variant of the claimed invention with three supply cavities, presented in the projection of the facade.

FIG. 4 is a plan view from above of the claimed invention.

FIG. 5 is a diagram of the operation of the claimed valve as part of a control unit.

FIG. 6 is a design diagram of the operation of the control unit with the claimed valve as part of the fire extinguishing system.

FIG. 7 is an example implementation of a second embodiment of the claimed invention with an additional supply cavity.

In FIG. 1-4 and 7 are examples of the implementation of the variants of the claimed device in statics. In FIG. 5 shows the control unit in standby and operating mode when the device performs the declared purpose and in FIG. 6 obtaining a technical result as part of automatic fire extinguishing.

In FIG. 1 shows a first embodiment of a device in which a drive housing 3 is fixed to a valve body 1 with an inlet cavity 2 (the bodies are made, for example, of cast iron VCh50-2). Sealed with a membrane 4 made, for example, of rubber and having discs 5 (made in its turn

- 013858 radish, made of steel St40X), they form a working cavity 6. In the housing 1, a supply cavity 7 is made, directly contacting at an angle of 90 ° with the supply 2 and the working 6 cavities. The supply cavity 7 interacts with the shutter 8 (made, for example, of cast iron VCh50-2), sealing the seat 9, made, for example, of bronze in the upper part of the supply cavity 2. The shutter 8 is connected to the disk 5 through the stop 10, the rod 11, made with the possibility of reciprocating movement inside the stop 10, and the rod 12, made with the possibility of reciprocating movement along the guide bushings 13 of the seat 9, for sealing and depressurization of the seat 9. The emphasis and rods are made, for example, of steel St40X.

In the first embodiment of the claimed device, the fire extinguishing agent encounters an obstacle in the form of a disk 5 of the membrane 4 on the way from the cavity 2 and the valve already directs the working medium (fire extinguishing agent) to the flow rate through the cavity at a volume of O l / s equal to the supplied volume. The stop 10 and the shutter under the influence of increased hydraulic pressure or its decline in the cavity 6 make movements that control the flow of the working medium through the cavity 7. Thus, with obviously smaller dimensions and less material consumption, the claimed first variant of the valve functions in the same way as the known valve.

In FIG. 2 shows a variant of the device, in which, in its housing 1, a second supply cavity 14 is additionally made, made coaxially horizontal symmetrical with the supply cavity 7, with an axis perpendicular to the axis of the input cavity 2. The supply cavities 7 and 14 interact with the shutter 8 of the membrane mechanism, sealing seat 9, made in the upper part of the supply cavity 2.

The emphasis 10 and the shutter 8 under the influence of increased hydraulic pressure or its decline in the cavity 6 make movements that control the flow of the working medium through the cavities 7 and 14. The extinguishing agent encounters the same obstacle in the way - the disk 5 of the membrane 4, and according to the laws of hydrodynamics, the arrival of cavity 2 in a volume of 20 l / s symmetrically at an angle of 90 ° to the disk 5 splits into two equivalent volumes of O l / s and goes through cavities 7 and 14 at the same time or separately to the flow rate into the supply pipelines (not shown in the drawing).

In FIG. Figures 3 and 4 show a variant of the device in which a third supply cavity 15 is additionally made in its housing 1, the axis of which is perpendicular to both the axes of the two supply cavities 7 and 14 and the axis of the input cavity 2. The supply cavities 7, 14 and 15 are also as in the first and second embodiments, they interact with the shutter 8 of the membrane mechanism sealing the seat 9, made in the upper part of the supply cavity 2 (not shown in Figs. 3 and 4).

The emphasis 10 and the shutter 8 under the influence of increased hydraulic pressure or its decline in the cavity 6 make movements that control the flow of the working medium through the cavities 7, 14 and 15. The extinguishing agent encounters the same obstacle in the way - the disk 5 of the membrane 4, and according to the laws of hydrodynamics the arrival from cavity 2 in a volume of 30 l / s symmetrically at an angle of 90 ° to the disk 5 splits into three equivalent volumes of O l / s and goes through cavities 7, 14 and 15 at the same time or separately to the flow rate into the supply pipelines 16, 17 and 18, respectively (see Fig. 4).

The principle of operation of the claimed valve as part of a control unit is described with reference to FIG. 5.

In FIG. 5 shows a diagram of the operation of the claimed valve 19 as part of a control unit, and the claimed valve is shown in partial cross section, as an example of its implementation with two supply cavities. The control unit contains, for example, a sprinkler-drencher supply line 20, a sprinkler system actuation line 21, a bypass line 22, the lines being provided with respective valves 23, 24, 25, and a manual gate valve 26. These lines are equipped with electrical contact pressure gauges (ECM) 27, 28 , 29, 30. The alarm valve 31 is installed on the starting line 32 of the pumps. The sprinkler system contains a distribution line 33 with sprinkler drivers 34, a deluge system includes a solenoid valve (ZE) 35, and an actuation line 36 with its own driver 37. Bypass line 22 is designed for conducting small pressure increases bypassing the shutter 8 to the supply and distribution system. To protect against large pressure surges, a relief valve 38 is provided with its drain line 39.

Shown in FIG. 7, the implementation of the inventive valve with an additional supply cavity is presented as an example of a second embodiment. The valve shown is made with an additional supply cavity 45 located in the lower part of the supply cavity and connected to the drinking water supply (not shown in the drawing) through a normally open solenoid valve 46 and bypass 47.

The inventive valve in the control unit operates as follows.

I. Standby sprinkler-deluge mode. Working and standby pressure in the system is set by the project.

Bringing the control unit into a static, standby mode begins with the closure of all locking devices, only the purge valve (not shown in the drawings) is open, located at a point as far as possible in height from the declared valve.

Open the valves 23, 24 and 25 on the sprinkler-drencher supply line 20, on the line 21 of the sprinkler system, on the bypass line 22 and open the manual valve 26 so that it is

- 2 013858 a murmuring, not stormy, stream of water is heard. This must be strictly performed so as not to create air cavities with air compression in the distribution network of pipelines, which are a prerequisite for false positives and backwash from hydroshocks at the moment of switching on the fire fighting pumps. As the system fills with water, the pressure on the EKM27 and EKM30, EKM28 and EKM29 is equalized, the purge valve is closed and the pressure is completely equalized throughout the system, as a result of which the shutter 8 closes the seat 9 under its own weight.

The alarm valve 31 on line 32 is opened to start the sensors of pressure signaling devices (CDS) 44. Cavity 7 and 14 are under pressure extinguishing agent from the cavity 2.

The sprinkler flow stopped at its drivers - irrigators 34 of the distribution line, the deluge flow stopped in front of the shutter of the ZE 35 valve and in front of its driver 37 on the line 36 of the deluge system.

Bypass line 22 bypassing the shutter 8 allows small pressure increases in the water supply network to freely transfer water to the supply and distribution system. At high pressures, the safety valve 38 with its drain line 39 will bring the pressure in the system back to normal.

The safety valve 38 performs the same function when there is a pressure surge from hydroshocks, when switching on and other pump problems.

The control node is ready to act as intended.

II. Drencher, sprinkler and sprinkler-drencher type of automatic fire fighting in action. Work mode.

Presented in FIG. 5, the standby mode of the control unit sprinkler-drencher type contains elements of the deluge and sprinkler type of automatic fire extinguishing and the impact of their inducement systems on the cavity 7 and 14 put into operation one of the types of fire extinguishing.

The working cavity 6 is universal, it works in deluge, sprinkler and sprinkler-deluge types of automatic fire extinguishing. Cavity 6 is filled with water from the supply chamber the supply conduit via the connection P _1, closed valve supplying water to nozzle B ₁ and tightly closed manual gate valve 26. Under the influence of the working pressure in the cavity 6 to the disk 5 and the membrane 4, the shutter 8 closes the seat 9. Manual gate valve 26 is fully open, and the system is in standby deluge mode. The area of the disk 5 and the pressure force on it are 20% larger than the area of the shutter 8, causing a corresponding decrease in back pressure from the side of the shutter 8.

Drencher type of fire fighting.

In the cavities 7 and 14 there is no extinguishing agent, since the deluge system is dry pipe, therefore, the shutoff solenoid valve 35 can be removed from the control unit circuit and replaced with valves according to clause 5.47 of the SNB 2.02.05-04. The actuation of the stimulator 37 in the actuation line 36 of the deluge system is enough and the extinguishing agent will be delivered to the fire source through the distribution cavities 7 and 14.

Sprinkler type of fire fighting.

Filling cavities 7 and 14 with open valves 23 of the sprinkler-drencher supply line 20 and a slightly open manual valve 26 through bypass 22 and fittings P1 and B1 creates a sprinkler type of fire fighting. The ZE 35 valve can be removed from the control unit circuit without or with the replacement of valves according to clause 5.47 of SNB 2.02.05-04 [2]. When triggering sprinklers 34, the sprinkler system in cavities 7 and 14 is activated.

Sprinkler-drencher type of fire fighting.

The sprinkler-deluge system can only function if there is a fire extinguishing system in the control unit circuit on the ZE 35 valve feed line and 36 deluge motive line with an ECM 30 as a sensor for starting the ZE 35, creating a controlled independent dry pipe line separated from the water-filled cavity 14.

The water-filled cavity 7 and the distribution line 33 with sprinklers 34 create a controlled sprinkler system independent of the dry tube cavity 14.

The triggering of the stimulants in their pipelines, independently of each other, simultaneously or at different times automatically puts the claimed valve into action in the sprinkler-deluge form of automatic fire extinguishing.

In all operating modes of the claimed valve, the additional cavity 45 functions independently of the shutter 8, and water from the specified cavity is supplied round-the-clock through a normally open solenoid valve 46. During fire extinguishing periods, the valve 46 is closed and water from the specified cavity is supplied through bypass 47, which is reduced by two times water supply.

A brief description of the operation of the device in an automatic fire extinguishing installation is given with reference to FIG. 6.

In addition to the claimed valve 19 described above with a working cavity 6 and in this example, two supply cavities 7 and 14, a sprinkler distribution line 33 with sprinkler drivers 34, a deluge system with a response line 36 with its own actuator 37, a shut-off

- 3 013858 by an electromagnetic valve (ZE) 35 and an electrocontact pressure gauge (ECM) 30 in FIG. 6 shows a stream-connected water source 40, a pump-feeder 41 and a supply pipe 42, as well as a distribution pipe of a deluge system with corresponding sprinklers 43.

In general, such an automatic fire extinguishing installation operates as follows.

The inducer 37, located at the explosive focus of the protected object, will melt as a result of the explosion and ignition of a flammable liquid. A fire extinguishing agent will begin to flow out of this inducer 37 on the valve actuation line 36 under pressure from the cavity 6, while reducing the pressure on the seat 9 of the locking mechanism. The operating pressure of the standby mode of the automatic water feeder 41 will ensure the opening of the shutter 8, the supply of fire extinguishing agent to the fire extinguishing system and the signal-starting line for switching on pressure signaling sensors (CDS) 44 and pumps of the main water sources (not shown in the drawings).

The sprinkler-drencher type of automatic fire extinguishing is functional if the control unit has a shut-off solenoid valve ZE 35.

Upon opening the inducer 37 in the line 36 of the actuation of the deluge system and the pressure drop in it, the ECM 30 will open the ZE 35 and the dry pipe line of the cavity 14 will be filled with fire extinguishing agent. The shutter 8 will open, the pumps will turn on and a deluge fire extinguishing stream is formed. The second water-filled highway 33 of the cavity 7, regardless of the cavity 14, is in standby mode until there is no fire.

In the event of a one-time fire exposure of the drivers 37 and the drivers-irrigators 34 of the distribution lines of the cavities 14 and 7, respectively, the device will enable automatic fire fighting in deluge and sprinkler modes simultaneously.

This is precisely the criterion of the inventive step of the claimed device, which carries out automatic fire extinguishing of three types: simultaneously in two directions of cavities 7 and 14 or in one of the directions of cavities 7 or 14, from its proponents.

The work and the technical result obtained in the case of a valve with three supply cavities 7, 14 and 15 are similar to the described example.

When designing automatic fire extinguishing installations with valves of a sprinkler-type fire extinguishing type, the application of the regulatory framework and calculation methodology for UE in accordance with SNB 2.02.05-04 - Fire automatics is provided without changes and additions.

The set of essential features, logically connected and justified by the laws of hydraulics, is embodied in the design for its intended purpose: to a specialist in the field of fire fighting technology, for identification, it is obvious that with a weight of 50% less, the claimed device fully performs the functions of two analogues.

As a result, the following properties of the claimed valve exceed the level of conventional design.

1. The performance by one valve of the functions of two, of any kind, signal valves controlling the sprinkler or deluge sections and sprinkler sections with 12 or more fire hydrants without second inputs with valves.

2. The implementation of a new type of automatic fire extinguishing sprinkler-deluge based on a new design property.

3. Double and triple arrival and standard consumption of extinguishing agent in supply pipelines.

4. The mass and dimensions of the signal valve device do not exceed the mass and dimensions of any similar valve of foreign manufacture.

5. Reducing the area of fire extinguishing stations to accommodate control units equipped with the declared signal valves.

6. Decrease in material consumption of control units, main ring and deadlock pipelines at fire extinguishing stations.

The implementation of the claimed options 1, 2 and 3 of the invention was carried out by checking prototypes for compliance with fire safety standards recognized as valid, and was drawn up by the Act of 03/10/08 with signatures of the members of the selection committee, the head of the Quality Department of the plant and approved by the Chief Designer of the plant.

The design of devices of options 2 and 3 allows you to perform a sprinkler or deluge type of fire extinguishing through two or three supply pipelines, or at the same time, or separately, sprinkler and deluge types of automatic fire extinguishing with a standard consumption of extinguishing agent through its supply pipe.

The claimed device exceeds the level of technology in the field of automatic fire extinguishing and for the first time ensures the implementation of new properties based on the performance of a technical task. The technical result is justified by the following causal relationship: the configuration of the prototype design in terms of hydraulics is the knee, in the same field of technology there are also tees, crosses, etc., which are used by the author to form the design of a more advanced device.

- 4 013858

As a result, the invention has acquired new technical features that provide the expected technical result, namely, a new type of automatic fire extinguishing - sprinkler and deluge simultaneously from one control unit.

Information sources.

1. Valve high-speed membrane type BKM - TU 2509-40-78 III. Catalog Technical means of automatic fire extinguishing installations. Issue 2, Moscow, 1986.

2. SNB 2.02.05-04. Fire automatics. Minsk, 2005

Claims (6)

CLAIM 1. Valve signal, comprising a housing in which the supply, supply and working cavities and membrane mechanism are made, characterized in that the supply cavity directly contacts at an angle of 90 ° with the supply and working cavities, and is also designed to interact with the membrane mechanism sealing the saddle installed in the upper part of the inlet cavity. 2. Valve signal, comprising a housing in which the supply, supply and working cavities and a membrane mechanism are made, characterized in that two supply cavities are made in its casing, made coaxial, symmetrical horizontally with axes perpendicular to the axis of the input cavity, and the specified supply the cavities are directly in contact at an angle of 90 ° with the inlet and working cavities, and also made to interact with a membrane mechanism that seals a saddle installed in the upper part of the inlet cavity. 3. Valve signal, comprising a housing in which the supply, supply and working cavities and a membrane mechanism are made, characterized in that three supply cavities with axes perpendicular to the axis of the input cavity are made in its housing, two of which are coaxial, symmetrical horizontally, and the axis of the third supply cavity is perpendicular to the axes of these two supply cavities, and these supply cavities directly contact at an angle of 90 ° with the supply and working cavities, and are also designed to interact with the membranes an early mechanism for sealing the saddle installed in the upper part of the inlet cavity. 4. The signal valve according to claim 1, characterized in that in the lower part of the inlet cavity an additional feeding cavity is made to operate independently of the membrane mechanism. 5. The signal valve according to claim 2, characterized in that in the lower part of the inlet cavity an additional supply cavity is made to operate independently of the membrane mechanism. 6. The signal valve according to claim 3, characterized in that in the lower part of the inlet cavity an additional feeding cavity is made to operate independently of the membrane mechanism.