KR200488483Y1 - Chamber for pressure switch of fire extinguishment system - Google Patents

Abstract

The present invention relates to a chamber for a pressure switch mounted in a fire extinguishing system of a building. In particular, it is possible to improve the problem of loss of the shock buffer function caused by leakage of air in the chamber over a long period of time, And more particularly, to a chamber for a pressure switch of a fire extinguishing system capable of effectively suppressing a shock caused by a water hammer, thereby preventing a malfunction of the pressure switch and thus damage to the pump. For this purpose, the chamber of the pressure switch of the fire extinguishing system according to the present invention is connected to the pressure sensing pipe branched from the outlet pipe of the pump. The chamber is filled with water and air at a predetermined ratio and is transmitted along the pressure sensing pipe The siphon tube having a tubular shape is installed so as to be connected to the pressure switch in a state where the inlet side is immersed in water and the outlet side is penetrated to the outside, and the water introduced into the inlet side And a water hammer which flows along the pressure sensing pipe while being introduced into the pressure switch connected to the outlet side through a siphon action.

Description

Technical Field [0001] The present invention relates to a chamber for a pressure switch of a fire extinguishing system,

The present invention relates to a chamber for a pressure switch mounted in a fire extinguishing system of a building. More specifically, it can improve the problem of loss of the shock buffering function caused by leakage of air in the chamber over a long period of time, And more particularly, to a chamber for a pressure switch of a fire extinguishing system that effectively prevents a shock caused by a water hammer through a buffering action to prevent malfunction of the pressure switch and damage of the pump.

Generally, buildings are equipped with fire extinguishing facilities capable of extinguishing when a fire occurs. In order to secure the radiation pressure and the discharge amount of the fire extinguishing water necessary for suppressing the fire of the fire extinguishing object, the fire extinguishing water is pumped A stanby pump having a performance equal to or higher than that of the main pump in case of an emergency, and a pressure pump for supplementing the pressure due to leakage in the piping.

In addition, there are pressure chambers, starting pressure switches, and digital pressure switches, which are capable of automatically starting or stopping the pump by sensing pressure fluctuations in the piping of a fire extinguishing system in the event of a fire.

It is necessary to secure a space that is proportional to the installation capacity of the pressure chamber because the volume capacity of the pressure chamber to be installed is large, and the pressure control chamber using the conventional pressure chamber is essential. Center) is easily burned out, so that it is troublesome to check and check the operation state from time to time. In addition, the method of setting the pressure is complicated, the start point of the pump and the display scale are inaccurate, and the spring tension and the Bourdon tube are used, which causes an error due to fatigue accumulation. In addition, when the pressure chamber is used for a long period of time, the air is continuously discharged to the gasket portion and the safety valve portion at the upper end of the pressure chamber, so that the shock buffering effect by the air is lost. Therefore, There is a problem that the starting device of the pressure switch can not exert its function and the fire extinguishing system becomes useless.

Recently, a digital operated electronic pressure switch has been developed to overcome several usability problems with such pressure chambers. The electronic pressure switch is installed in a structure directly connected to the extinguishing facility piping, excluding the use of the pressure chamber having a large volume capacity as in the past, and the pressure change in the piping due to the operation of the head or opening of the hydrant valve at the time of fire occurrence or inspection The sensor is detected and the pump is started by an electronic signal or recorded in the pressure switch pressure display section so that it can be confirmed directly so that the engineer and the manager can always check the operation state of the extinguishing system and the pressure value can be finely adjusted .

According to the installation regulations of the fire fighting system, the pressure sensing pipe, which is part of the device that controls the automatic start and stop of the pump, is pulled out from the middle pipe between the check valve and the isolation valve installed at the outlet end of the pump, Even in the case of a fire extinguishing system employing the above-described electronic pressure switch, in order to reliably remove the influence of a water hammer phenomenon or a surging phenomenon that may occur when the pump is suddenly started and stopped, It is recommended to install an air chamber or a damper for relieving pressure fluctuations in the pressure sensing pipe if there is a possibility of malfunction of the electronic pressure switch due to pressure fluctuation of the water, and damage of the pump due to this.

However, when an air chamber or a damper is installed in the pressure sensing pipe as described above, it is possible to mitigate the phenomenon that the momentary impact due to the water hammer operation, which may be caused when the pump is suddenly started, is directly transmitted to the electronic pressure switch, The generated water hammer action is still transmitted to the pressure sensing pipe, so that the pressure fluctuation of the pressure sensing pipe can not be completely prevented from being transmitted to the pressure switch.

Practical Publication No. 1992-0016366 (Sep. 16, 1992)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for effectively suppressing a water hammer caused by sudden starting and stopping of a pump, And to provide a chamber for a pressure switch of a fire extinguishing system which can prevent the damage of the pump due to the damage of the pump.

Another technical problem to be solved in the present invention is to provide a chamber for a pressure switch of a fire extinguishing system which can prevent the air filled in the chamber from easily leaking out of the chamber for a long time, To provide.

Another technical problem to be solved in the present invention is to miniaturize the size of the chambers performing the shock buffering function, to reduce the installation space of the chambers, to facilitate the installation work of the chambers, And to provide a chamber for a pressure switch of a fire extinguishing system which can be reduced.

In order to solve the above-mentioned technical problem, a chamber for pressure switch of a fire extinguishing system according to the present invention is connected to a pressure sensing pipe branched from an outlet pipe of a pump, and filled with water and air at a predetermined ratio, A siphon tube having a tubular shape is installed so as to be connected to the pressure switch in a state where the inlet side is immersed in water and the outlet side is penetrated to the outside, The water introduced into the inlet side flows into the interior of the pressure switch connected to the outlet side through a siphon action, and the water hammer transmitted along the pressure sensing pipe is secondarily buffered.

Here, the pressure sensing pipe may be connected to the lower central portion of the chamber, and the inlet side of the siphon pipe may be disposed at a position eccentric to the center of the chamber.

At this time, the outlet side of the siphon tube may be configured to be hermetically sealed through the upper end of the chamber, and the pressure switch may be connected to the outlet side exposed through the upper end of the chamber by a screw fastening method.

The siphon tube may be formed in a curved shape having a curved shape.

A test valve may be provided between the chamber and the pressure switch to selectively open and close a flow path connecting the chamber and the pressure switch.

According to the present invention having the above-described configuration, impact due to the water hammer transmitted through the pressure sensing pipe can be buffered primarily through the volume change of the air layer filled in the upper part of the chamber, and water It is possible to prevent a large impact due to the water hammer from being directly transmitted to the pressure switch side, thereby preventing malfunction of the pressure switch, and it is possible to prevent a malfunction of the pressure switch, There is an effect that the damage of the piping can be prevented in advance.

In addition, since the upper end of the siphon tube connected to the pressure switch is fixed to the upper plate of the chamber through welding and thereby the air filled in the upper portion of the chamber is formed into a perfect sealing structure that can not escape to the outside, It is possible to prevent the air from leaking into the outside of the sea chart chamber so that the buffering function against the water hammer is lost.

In addition, since it is possible to buffer the first and second water shocks through the volume change of the air and the water filled in the siphon tube in one small chamber space, it is possible to miniaturize the size of the chamber, It is possible to reduce the degree of freedom of the layout design of the fire extinguishing system.

In addition, since the installation is completed only by a simple operation of screwing the miniaturized chamber to the pressure sensing pipe and the pressure switch respectively, it is very easy to install the chamber, and it is possible to reduce the time and cost for installation have.

Further, since the shape of the siphon tube in the chamber is formed in a curved shape, the resistance can be increased by changing the direction of movement of the water through the curved path of the siphon tube during the impact by the water hammer, There is an effect that the shock absorbing effect can be greatly increased.

The inlet of the pressure sensing pipe may be formed at the lower central portion of the chamber and the inlet of the siphon pipe into which the water stored in the chamber is introduced may be disposed at a position eccentric from the center of the chamber. It is possible to prevent the water pressure flowing into the lower center portion of the ride body from being directly transmitted to the inlet side of the siphon tube, so that the shock due to the water hammer can be attenuated to further increase the buffering effect.

In addition, since the inlet of the siphon tube into which water is introduced is disposed in a state of being submerged in the water in the chamber, only water can be supplied to the upper pressure switch without inflow of air through the siphon tube, It is possible to prevent malfunctions in advance and to prevent the air filled in the upper portion of the chamber from being discharged to the outside through the siphon tube even when the test valve is opened,

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a configuration of a fire extinguishing system having a chamber for a pressure switch according to the present invention; FIG.
FIG. 2 is an enlarged view of a portion where the chamber and pressure switch shown in FIG. 1 are installed. FIG.
3 is an exploded perspective view showing a chamber for a pressure switch according to the present invention in detail.
4 is a perspective view showing a state in which the outlet of the siphon tube is welded to the upper plate of the chamber according to the present invention.
FIG. 5 is a view showing another embodiment of the present invention in which an inlet of a chamber into which water is introduced and an inlet of a siphon tube are arranged eccentrically.

Hereinafter, embodiments of a chamber for a pressure switch and a fire extinguishing system using the chamber according to the present invention will be described in detail with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

It is to be understood that the following terms are defined in consideration of functions in the present invention, and this may vary depending on the intention or custom of the producer producing the product, and therefore the definition should be based on the contents throughout this specification.

FIG. 1 shows a configuration of a fire extinguishing system equipped with a chamber for a pressure switch according to one embodiment of the present invention, and FIG. 2 is an enlarged view of a chamber and a pressure switch installation portion in FIG.

1 and 2, a fire extinguishing system according to an embodiment of the present invention includes a main component of a general fire extinguishing system, such as a fire extinguisher, the main pump 110 and the various valves are mounted on the chungap pump 120 to supplement the pressure of the leak in the pipe, a plurality of pipes connected to these that supply to pump the extinguishing be stored in a tank (not shown) As shown in FIG.

Specifically, the fire extinguishing system according to the present invention includes a pressure switch 140 for detecting the pressure fluctuation applied to the discharge side piping of the main pump 110 and the filling pump 120 to automatically start or stop the pumps 110 and 120 Respectively.

1, only the main pump 110 and the depressurization pump 120 are shown as an example of a fire extinguishing system. However, in order to prepare for emergency situations, a standby pump (stanby pump may be additionally installed.

The start and stop of the main pump 110 and the depressurization pump 120 are controlled through a single pressure switch 140 installed at the outlet end of the depressurization pump 120.

The pressure switch 140 is connected to the pressure sensing pipe 130 branched from the upper side of the gate valve OS & Y V / V installed on the discharge side pipe of the impregnation pump 120 as shown in FIG.

Here, the pressure switch 140, which can be installed in the pressure sensing pipe 130, may include a digital electronic pressure switch that can control the stop and start points of the pumps 110 and 120 by pressing the upper and lower push buttons provided on the front display unit, Can be applied.

The electronic pressure switch detects the change in the pressure in the pipe due to the operation of the head or the opening of the fire hydrant valve when the fire is generated or checked, and sends a control signal corresponding thereto to the pumps 110 and 120, So that the operator can check the operation state of the fire extinguishing system at any time by making it possible to directly check the state of the fire extinguishing system.

A chamber 200 is provided under the pressure switch 140. The chamber 200 is a shock buffering means for preventing sudden pressure fluctuations occurring at the outlet end when the pumps 110 and 120 suddenly start or stop.

The chamber 200 according to the present invention is detachably mounted on the pressure sensing pipe 130 to the pressure switch 140.

That is, the lower end of the chamber 200 is connected to the pressure sensing pipe 130 branched from the discharge side pipe of the pumps 110 and 120, and the upper end is connected to the pressure switch 140.

The water W and the air A are filled in the chamber 200 at a predetermined ratio. Particularly, the water W filled in the chamber 200 is introduced into the chamber 200 through a siphon, A siphon tube 210 for supplying the siphon tube 210 to the upper pressure switch 140 is fixedly installed.

Therefore, when a water shock generated when the pumps 110 and 120 suddenly start and stop is transmitted to the inside of the chamber 200 along the pressure sensing pipe 130, the pressure of the water W in the chamber 200 And then the water W is caused to flow to cause a change in volume with respect to the upper air layer to thereby primarily alleviate the water impact. Subsequently, the primary attenuated water impact is applied to the siphon pipe 210 A secondary shock absorption is performed in the process of being transmitted to the inside of the switch 140, so that a large impact due to the water hammer is not transmitted to the pressure switch 140.

2, the inlet 211 of the siphon tube 210 is inclined at a predetermined angle with the outlet 213 fixed in a direction perpendicular to the upper center of the chamber 200, As shown in FIG. Accordingly, the inlet 211 of the siphon tube 210 is arranged in a form eccentric by a predetermined distance in the horizontal direction from the inlet of the central portion of the chamber 200 into which water is introduced from the pressure sensing pipe 130.

As a result, since the water impact introduced into the central inlet of the chamber 200 by the pressure sensing pipe 130 is not directly transmitted to the inlet 211 of the siphon tube 210, the siphon tube 210 The lower part of the inlet 211 may have a lower level of water impact at which the impact amount is attenuated to enhance the buffering effect.

Meanwhile, the chamber 200 according to the present invention is similar to the conventional pressure chamber in buffering the water hammer occurring when the pump is started and stopped. However, the conventional pressure chamber has a large volume capacity, Switches, and a plurality of piping connected to each of them. In contrast, the chamber 200 of the present invention has a small volume capacity, and has a primary buffer function by the air filled therein and a siphon tube 210 can significantly attenuate the impact of the water by the second buffering action, so that the chamber 200 can be downsized. In addition, since a variety of accessories such as valves, piping, and the like are apparently manufactured in a simple cylindrical structure without being installed separately, the installation space can be easily installed without being limited by a small space.

Further, in the case of a conventional pressure chamber, a safety valve and a flange structure are provided, and a gasket serving as a sealing member is installed at an upper end portion of the pressure chamber to prevent leakage of air in the chamber to the outside. The durability of the gasket gradually decreases, and the air leakage from the portion where the gasket and the safety valve are installed is continuously leaked, resulting in the loss of the water hammer prevention performance. Therefore, if proper measures can not be taken, there is a problem that the pressure switch can not exert its function and the fire extinguishing system becomes useless.

However, the chamber 200 of the present invention completely isolates the siphon tube 210 installed in the inner space from the upper air layer so that the air can not flow into the siphon tube 210 at all. That is, the inlet 211 of the siphon tube 210 is kept isolated from the upper air and is immersed in the water W, and the outlet 213 is completely closed with the inner space of the chamber 200, The water W flowing into the inlet 211 of the siphon tube 210 is connected to the outlet 213 through a siphon action. The pressure switch 140 is connected to the outlet 213 of the siphon tube 210. The pressure of the water introduced through the siphon tube 210 And controls the start-up of the pumps 110 and 120. Particularly, since all the structures coupled to the upper and lower ends of the chamber 200 are formed to have a completely closed structure through welding, the external leakage of the air filled in the chamber 200 is not performed even after a long time, Can be prevented from being lowered. The concrete air leakage preventing structure of the chamber 200 will be described later.

FIG. 3 shows the detailed structure of the chamber 200 according to the present invention. FIG. 4 shows that the outlet 213 of the siphon tube 210 is welded to the top plate 202 of the chamber 200, And a sealed structure.

3 and 4, the chamber 200 according to the present invention includes a body 201 having upper and lower openings, an upper plate 202 and a lower plate 202 coupled to upper and lower ends of the body 201, respectively, And a siphon tube 210 fixed to the bottom surface of the upper plate 202 in a state of being accommodated in the body 201.

The body 201 has a cylindrical shape with upper and lower openings. An upper plate 202 and a lower plate 203, which are disc-shaped, are welded to the upper and lower openings of the body 201, respectively.

At this time, the upper plate 202 is combined with the siphon tube 210 before being assembled to the body 201, and then assembled with the body 201.

4, a portion of the outlet 213 located at the upper end of the siphon tube 210 is passed through the hole 204 formed at the center of the upper plate 202, The outer surface of the upper portion of the chamber 213 and the peripheral portion of the upper plate 202 are welded to each other to form a rigid sealing structure capable of completely shutting out the air into and out of the chamber 200.

After the connection between the siphon tube 210 and the upper plate 202 is completed in this manner, the upper plate 202 coupled with the siphon tube 210 is welded to the open top of the body 201 And perform the combining operation.

At this time, a pressure switch 140 is detachably connected to an outlet 213 of the siphon tube 210 exposed to the upper side of the upper plate 202. A female screw is formed on the inner circumferential surface of the outlet 213, A male screw portion is formed on the outer circumferential surface of the connection portion 144 protruding from the lower end of the switch 140 so that the pressure switch 140 is coupled to the outlet 213 of the siphon tube 210 in a screw- .

In the case of the lower plate 203, as in the case of the upper plate 202, the lower portion of the hole 206 formed at the center of the lower plate 203 before the assembling operation with the body 201, The lower plate 203 coupled with the socket 214 is welded to the lower open end of the body 201 and assembled.

At this time, the socket 214 fixed to the lower surface of the lower plate 203 has a structure in which threads are formed on the inner circumferential surface, and the upper end thereof is fixed to the lower portion of the hole 206 formed at the center of the lower plate 203 through welding Thereby forming a tight sealing structure between the lower plate 203 and the socket 214.

The socket 214 fixed to the lower surface of the lower plate 203 is screwed to the elbow 132 connected to the end of the pressure sensing pipe 130 and connected to each other.

As described above, the chamber 200 of the present invention is configured such that the lower end portion and the upper end portion thereof can be connected to the pressure sensing pipe 130 and the pressure switch 140 by a screw fastening method, respectively, The chamber 200 can be easily separated from the pressure sensing pipe 130 and the pressure switch 140 and the pressure sensing pipe 130 and the pressure switch 140 can be separated from the pressure sensing pipe 130 The assembly of the chamber 200 can be carried out easily and the disassembling work can be performed very easily.

2, the water W and the air A are filled in the inner space of the chamber 200 at a predetermined ratio, and the water W filled in the lower part of the chamber 200 is siphon A siphon tube 210 for supplying the siphon tube 210 to the inside of the pressure switch 140 disposed at the upper part.

Here, the siphon tube 210 allows the water W in the chamber 200 to be introduced into the pressure switch 140 by a siphon action, and at the same time, the shock due to the water hammer transmitted along the pressure sensing pipe 130 And serves as a damper for buffering.

3, the intermediate portion 212 of the siphon tube 210 is bent in a coil shape so as to increase the damping effect of the siphon tube 210, .

As a part of the siphon tube 210 is formed in the shape of a curved tube, the direction of movement of the water through the curved path of the siphon tube 210 is changed during impact by the water hammer Since the resistance due to the water hammer can be further increased, the shock absorption effect according to the water hammer can be greatly increased.

In this case, a curved tube shape applied to the siphon tube 210 may be a curved tube shape other than the coil shape, and a siphon tube having a straight shape other than the curved tube shape may be applied.

The siphon tube 210 having a curved shape as described above is disposed at a predetermined distance from the upper side of the lower plate 203 of the chamber 200 while the inlet 211 is locked in the water W, The outlet 213 is connected to the upper pressure switch 140 in a state where the outlet 213 passes through the upper plate 202 of the chamber 200 and is exposed upward.

The water introduced through the inlet 211 of the siphon tube 210 immersed in the water W is then introduced into the chamber 200 through a pressure switch 140 connected to the outlet 213 at the top of the chamber 200 by siphon action The pressure switch 140 senses the pressure of the water flowing into the inside of the pressure switch 140 and determines whether or not the pressure at the outlet end of the pumps 110 and 120 is formed at an appropriate pressure. Then, the pumps 110 and 120 are operated Or stop.

Between the chamber 200 and the pressure switch 140, there is provided a test valve 150 for selectively opening and closing a flow path connecting the chamber 200 and the pressure switch 140.

The test valve 150 is kept in a normally closed state so that the water W in the chamber 200 flows into the pressure switch 140 through the siphon tube 210 so that the chamber 200 can be replaced or repaired The test valve 150 is opened when the water W in the chamber 200 needs to be taken out to the outside or the water W in the chamber 200 for the pressure test needs to be introduced into the external equipment.

When the test valve 150 is opened, since the inlet 211 of the siphon tube 210 is immersed in the water W and kept isolated from the upper air A, the test valve 150 The air A filled in the chamber 200 does not escape to the outside through the test valve 150 to prevent the water hammer prevention performance from being lost due to leakage of air.

According to the structure of the chamber 200 of the present invention having the above-described configuration, the shock due to the water hammer transmitted through the pressure sensing pipe 130 can be detected primarily through the volume change of the air layer filled in the chamber 200 And can be absorbed by the damping action of the water filled in the inside of the siphon tube 210 so that it is possible to absorb the large water impact toward the pressure switch 140, It is possible to prevent malfunction of the pressure switch 140 and to prevent damage to the pump and piping due to malfunction of the pressure switch 140. [

The damping force of the siphon tube 210 may vary depending on the shape and the installation position of the siphon tube 210. The damping force of the siphon tube 210 may be varied depending on the water hammer transmitted to the pressure switch 140 The amount of impact can also vary.

5 shows another embodiment of the shape structure and installation position of the siphon tube 210 according to the present invention.

The inlet 213 of the siphon tube 210 is positioned at the center CL of the chamber 200 and the inlet 211 of the siphon tube 210 is connected to the outlet 213 And a predetermined inclination angle.

The siphon tube 210 according to the second embodiment of the present invention is formed in such a manner that the inlet 211 and the outlet 213 are parallel to each other and fixed to the upper end of the chamber 200 The portion of the outlet 213 is fixed on a position spaced a certain distance in the horizontal direction from the central portion CL of the chamber 200.

5, the inlet 211 of the siphon tube 210 is disposed at a predetermined distance D from the center portion CL where the inlet of the chamber 200 is located.

The inlet of the chamber 200 into which the water flows from the pressure sensing pipe 130 is formed in the lower central portion CL of the chamber 200 and the siphon tube The inlet 211 of the chamber 210 is disposed at a position eccentric from the center CL of the chamber 200 by a predetermined distance D, Since the water impact can be prevented from being directly transmitted to the inlet 211 portion of the siphon tube 210, the water impact introduced into the inlet 211 of the siphon tube 210 can be attenuated to a lower level It is possible to prevent the pressure switch 140 from malfunctioning due to the impact.

While the preferred embodiments of the present invention have been described above, it should be understood that the scope of the present invention is not limited to these specific embodiments. Those skilled in the art will understand that various changes and modifications within the scope of the claims It will be possible.

110: main pump 120:
130: Pressure sensing pipe 140: Pressure switch
144: connection part 150: test valve
200: chamber 201: body
202: top plate 203: bottom plate
204, 206: hole 210: siphon tube
211: entrance 213: exit
214: Socket

Claims (4)

A chamber is connected to a pressure sensing pipe branched from an outlet side pipe of a pump. The chamber is filled with water and air at a predetermined ratio, and a water hammer, which is conveyed along the pressure sensing pipe, And,
A siphon tube having a tubular shape is installed in the chamber so that the inlet side thereof is immersed in water and the outlet side is connected to the pressure switch in a state where the outlet side is penetrated to the outside, The pressure sensing pipe is configured to be capable of secondarily buffering the water hammer transmitted along the pressure sensing pipe while being introduced into the pressure switch connected to the outlet side,
The pressure sensing pipe is connected to the lower central portion of the chamber
The chamber includes a body having upper and lower openings, a top plate coupled to an upper portion of the body, and a lower plate coupled to a lower portion of the body,
The siphon tube is formed in a curved shape with a part bent,
The outlet of the siphon tube is fixed at a position spaced apart from the center of the upper plate by a predetermined distance, the inlet of the siphon tube is disposed at a position spaced apart from the center of the chamber,
Wherein the inlet and outlet of the siphon tube are disposed eccentrically equidistant from the center of the chamber to prevent direct transfer of the water hammer carried along the pressure sensing pipe to the inlet side, The pressure switch chamber of the fire extinguishing system [2] The apparatus according to claim 1, wherein the outlet side of the siphon tube is coupled to be hermetically sealed through the upper end of the chamber, and the pressure switch is connected to the outlet side exposed to the upper end of the chamber by a screw- The pressure switch chamber of the fire extinguishing system The pressure switch of claim 1, wherein a test valve is provided between the chamber and the pressure switch. A fire extinguishing system having a chamber for a pressure switch according to any one of claims 1 to 3

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