KR102265736B1 - Chamber for fire-fighting equipment pressure switch - Google Patents

Abstract

The chamber for fire-fighting equipment pressure switch according to the present invention is provided with an impact prevention connection part with a "T"-shaped movement path perforated so that the fire water flowing into the chamber is branched in both directions, and the shock pressure of the fire water flowing into the pressure switch is provided. to prevent the failure of the pressure switch in advance by offsetting or blocking the pressure switch, a tool groove is formed on the lower surface of the shock-resistant body for convenient separation or connection during maintenance and cleaning, and a branching projection is formed at the upper end of the fire-fighting water inlet groove, There is an effect that the flow of fire water can be moved more smoothly by forming an inclined inflow path inclined at a predetermined angle.

Description

Chamber for fire-fighting equipment pressure switch }

The present invention relates to a chamber for a pressure switch for firefighting equipment, and more particularly, a "T"-shaped movement to offset or block the shock pressure of the fire water flowing into the pressure switch by branching the fire water flowing into the chamber in both directions. It relates to a chamber for a fire-fighting equipment pressure switch provided with a perforated shock-resistant connection.

In general, buildings, etc. are equipped with fire extinguishing equipment that can extinguish a fire in case of fire, and in such fire extinguishing equipment, fire extinguishing water is pumped according to the operation of the pressure switch in order to secure the radiation pressure and discharge amount of the fire extinguishing water required for extinguishing the fire. A main pump that supplies the system, a standby pump that has the same or higher performance as the main pump in case of an emergency, and a pressure pump that supplements the pressure caused by water leakage in the pipe are installed.

In addition, there are a pressure chamber, a starting pressure switch, a digital pressure switch, etc. as hydraulic switchgear that can automatically start or stop the pump by detecting the pressure fluctuation in the pipe of the fire extinguishing facility in case of a fire.

Here, the conventional digital electronic pressure switch excludes the use of a pressure chamber with a large volumetric capacity as in the prior art, and is installed in a structure directly connected to the fire extinguishing facility pipe, so that when a fire occurs or inspection, the operation of the head or the opening of the fire hydrant valve By detecting the pressure change in the pipe with a sensor and starting the pump with an electronic signal or recording it on the pressure display part of the pressure switch to check it directly, engineers and managers can check the operation status of the fire extinguishing system at all times and finely adjust the pressure value. have the advantage that

On the other hand, according to the installation regulations of firefighting equipment, the pressure sensing pipe, which is a part of the device that controls the automatic start and stop of the pump, is drawn out from the middle pipe between the check valve and the isolation valve installed at the outlet end of the pump, and then connected to the pressure switch. However, even in the case of fire extinguishing facilities employing electronic pressure switches as described above, in order to reliably remove the effects of water hammer or surging that may occur during sudden start and stop of the pump. It is recommended to install an air chamber or a damper to relieve pressure fluctuations in the pressure sensing pipe if there is a possibility of malfunction of the electronic pressure switch and damage to the pump due to the pressure fluctuation of the fire extinguishing water.

As a technical document on such a conventional chamber for a pressure switch, Korean Utility Model No. 20-2018-0001470 was disclosed.

At this time, as shown in FIG. 1, the conventional chamber for pressure switch is provided with a curved siphon tube inside in order to solve the water hammer or surging phenomenon that occurs at the time of sudden start and on-time in the chamber, and is inserted into the chamber. It was a technical configuration to minimize the water hammer or surging phenomenon by separating the positions of the inlet pipe and the siphon pipe through which water is introduced by a predetermined distance.

However, the conventional chamber for a pressure switch cannot directly block the pressure of water flowing in through the inlet pipe, so that the water filled in the chamber shakes irregularly, making it difficult to operate or a predetermined hydraulic force that cannot be offset. There was a problem that it was introduced into the siphon tube and caused a malfunction in the pressure switch.

The present invention was created to solve the problems of the prior art as described above, and an object of the present invention is to provide an anti-impact connection part with a perforated "T"-shaped movement path so that the fire water flowing into the chamber is branched in both directions. to offset or block the shock pressure of the fire water flowing into the pressure switch to prevent the failure of the pressure switch in advance, and a tool groove is formed on the lower surface of the shock prevention body to conveniently disengage or fasten during maintenance and cleaning. An object of the present invention is to provide a chamber for a pressure switch for firefighting equipment capable of more smoothly moving the flow of firefighting water by forming a branching protrusion at the upper end of the inlet groove and forming an inclined inflow path at a predetermined angle.

The chamber for pressure switch for firefighting equipment according to the present invention for achieving the above object is a chamber for pressure switch that is connected to a pressure switch used for firefighting equipment and minimizes water hammer and surging phenomenon. , an upper connection pipe provided on the upper part of the chamber body and fastened to a lower end of a connection pipe connected to the pressure switch, an upper connection screw formed on an inner circumferential surface of the upper connection pipe, and a lower part of the chamber body provided with fire water flowing a lower connection pipe connected to the upper part of the fire-fighting pipe, and a main body made of a lower connection screw formed on an inner circumferential surface of the lower connection pipe; A cylindrical shock-resistant body fastened to the inside of the lower connection pipe, a fire-fighting water inlet groove recessed to a predetermined height on the lower surface of the shock-resistant body, and a fire water inlet formed at the upper end of the fire-fighting water inlet groove and introduced into the fire water inlet groove It is characterized in that it is composed of a deceleration inlet perforated in both directions so as to reduce the flow rate, and an anti-impact connection part made of an anti-impact screw formed to be screwed into the lower connecting pipe on the outer circumferential surface of the anti-impact body.

The lower surface of the shock-resistant body is characterized in that the tool groove into which the tool is inserted so as to detach or fasten the shock-resistant connection part inside the lower connection pipe is characterized in that it is formed.

It is characterized in that the upper end of the fire water inlet groove is formed with a triangular branch protrusion protruding downward so that the fire water introduced into the fire water inlet groove is branched to both sides.

It is characterized in that the deceleration inflow path is formed with an inclined inflow path inclined at a predetermined angle so that the fire water introduced into the fire water inlet groove is more smoothly branched.

It is characterized in that a ring-shaped sealing ring is provided on the outer circumferential surface of the shock-resistant body to block the leakage of fire water flowing from the fire-fighting pipe.

As described above, the effect of the chamber for the fire-fighting equipment pressure switch according to the present invention is as follows.

First, by providing an anti-impact connection part with a perforated movement path in a "T" shape so that the fire water flowing into the lower part of the chamber is branched in both directions, the shock pressure of the fire water flowing into the pressure switch is offset or blocked, thereby reducing the pressure of the pressure switch. failure can be prevented,

Second, by forming a tool groove into which the tool is inserted on the lower surface of the impact-resistant body, the impact-resistant body can be easily fastened or separated during maintenance and cleaning of the impact-resistant body,

Third, by forming a triangular branch protrusion protruding in the downward direction at the upper end of the fire water inlet groove, it is possible to smoothly branch the fire water moving vertically in both directions, so that the impact caused by the collision of the fire water inside the shock prevention body can be prevented in advance,

Fourth, there is an effect that the flow of the fire water flowing into the fire water inlet groove can be more smoothly branched by forming the deceleration inflow path as an inclined inflow path inclined at a predetermined angle.

1 is a front cross-sectional view showing a conventional chamber for a pressure switch,
2 is a front sectional view showing a chamber for a pressure switch according to the present invention,
3 is an exploded perspective view showing a chamber for a pressure switch according to the present invention;
Figure 4 is a perspective view showing the lower surface of the impact prevention connection for the present invention,
5 is another embodiment of the present invention, (a) is a front sectional view showing a branching projection, (b) is a front sectional view showing an inclined inflow path,
6 is a partially enlarged cross-sectional view showing the sealing ring of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The chamber for a pressure switch for firefighting equipment according to the present invention is connected to the pressure switch (S) used for firefighting equipment as shown in FIGS. 2 to 3 to minimize the water hammer and surging phenomenon. A cylindrical chamber body 11 having a space formed therein, and an upper connection pipe 12 provided on the upper portion of the chamber body 11 and fastened to the lower end of the connection pipe P connected to the pressure switch S; The upper connection screw 13 formed on the inner circumferential surface of the upper connection pipe 12, and the lower connection pipe 14 provided at the lower part of the chamber body 11 and connected to the upper part of the fire pipe P1 through which the fire water W flows ) and a body portion 10 comprising a lower connection screw 15 formed on the inner circumferential surface of the lower connection pipe 14; A cylindrical shock-resistant body 21 fastened to the inside of the lower connection pipe 14, a fire-fighting water inlet groove 22 recessed to a predetermined height on the lower surface of the shock-resistant main body 21, and the fire-fighting water inlet groove ( 22) and formed at the upper end of the fire-fighting water inlet groove 22, the speed reduction inlet 23 perforated in both directions so that the flow rate of the fire-fighting water (W) introduced into the inlet groove 22 is reduced, and on the outer circumferential surface of the shock-resistant body 21, the It consists of an anti-shock connection part 20 made of an anti-impact screw 24 formed to be screwed into the lower connecting pipe 15 .

On the other hand, the chamber body 11 is manufactured by overlapping and sealing the hemispherical body divided into two upper and lower parts by welding, and the upper connecting pipe 12 and the lower connecting pipe 14 are of the chamber body 11 . It is preferable to be embedded in the upper and lower surfaces or attached by welding or the like.

And, on the lower surface of the shock-resistant body 21, as shown in FIG. 4, the tool D is fitted to the inside of the lower connection pipe 14 to separate or fasten the shock-resistant connection part 20. A groove 25 is formed.

On the other hand, the tool groove 25 is preferably formed in any one of the shape of a groove in which an existing tool, such as a screwdriver or a wrench, can be seated, such as a straight line, a cross, a star, or a hexagon.

In addition, at the upper end of the fire-fighting water inlet groove 22, as shown in Fig. 5(a), a triangular branch protrusion 26 protruding downward so that the fire water W introduced into the fire-fighting water inlet groove 22 is branched to both sides. is formed

In addition, as shown in FIG. 5(b), an inclined inflow path 27 inclined at a predetermined angle is formed in the deceleration inlet 23 so that the fire water W flowing into the fire water inlet groove 22 is more smoothly branched. do.

In addition, a ring-shaped sealing ring 28 is provided on the outer circumferential surface of the shock-resistant body 21 so that the water (W) flowing in from the fire-fighting pipe (P1) is blocked from leaking.

On the other hand, it is preferable that a seating groove (not shown) in which the sealing ring 28 is seated is formed on the outer circumferential surface of the shock-resistant body 21 and the inner circumferential surface of the lower connection pipe 14 .

The operation of the fire-fighting equipment pressure switch chamber according to the present invention configured as described above is as follows.

As shown in Figs. 2 to 3, the chamber for pressure switch for fire fighting equipment according to the present invention is connected to the pressure switch (S) used for fire fighting equipment to minimize water hammer and surging phenomenon.

That is, it is connected between the lower part of the pressure switch (S) and the fire-fighting pipe (P1) to relieve the water hammer and surging phenomenon generated in the fire-fighting pipe (P1). The cylindrical body part 10 is formed with a space therein. ), the internal space of the main body 10, that is, the fire pipe P1, increases the impact pressure generated when the first movement or stop of the fire water W in the fire pipe P1 is greater than the area of the chamber By reducing the impact pressure through the internal space of the body 11, it is possible to prevent in advance that the pressure switch S is broken through the impact pressure.

At this time, the lower portion of the main body portion 10, that is, the inside of the lower connection pipe 14, the fire water (W) flowing in both directions is a deceleration drilled on both sides from the upper end of the fire water inlet groove 22 in the vertical direction so that it is branched in both directions. By forming the inflow path 23, when the fire water (W) flows into the main body portion 10, it does not flow directly, but is blocked by the deceleration inflow path 23 and then flows in both directions. It is possible to offset the shock pressure generated in

Through this, it is possible to prevent the failure of the pressure switch (S) in advance by blocking the inflow of the shock pressure of the fire fighting water (W) into the inside of the pressure switch (S) in advance.

On the other hand, by forming an anti-impact screw 24 formed to be screwed with the lower connection pipe 15 on the outer peripheral surface of the shock-resistant body 21, the impact-resistant body 21 is inserted into the lower connection pipe 15. ) can be concluded.

At this time, as shown in FIG. 4 on the lower surface of the anti-impact body 21, the tool D is inserted to separate or fasten the anti-impact connecting part 20 to the inside of the lower connecting pipe 14. Since the groove 25 is formed, the tool D can be conveniently rotated after being inserted into the tool groove 25, so that the impact prevention body 21 can be removed during maintenance and cleaning of the impact prevention body 21. It can be easily fastened or disconnected.

On the other hand, at the upper end of the fire-fighting water inlet groove 22, as shown in Fig. 5(a), a triangular branch protrusion 26 protruding downward so that the fire water (W) introduced into the fire-fighting water inlet groove 22 is branched to both sides. By being formed, it is possible to smoothly branch the fire-fighting water (W) moving vertically in both directions, so that the impact caused by the fire-fighting water (W) collides inside the impact prevention body 21 can be prevented in advance there will be

Here, as another embodiment, the deceleration inlet 23 is inclined at a predetermined angle so that the fire water W flowing into the fire water inlet groove 22 is more smoothly branched as shown in FIG. 5(b). By consisting of (27), it is possible to smoothly branch the fire water (W) moving vertically in both directions.

In addition, a ring-shaped sealing ring 28 is provided on the outer circumferential surface of the shock prevention body 21 as shown in FIG. 6, so that the fire water W flowing in from the fire pipe P1 can be prevented from leaking in advance. do.

The present invention is not limited to the specific preferred embodiments described above, and without departing from the gist of the present invention claimed in the claims, anyone with ordinary skill in the art to which the invention pertains can implement various modifications Of course, such modifications are intended to be within the scope of the claims.

<Explanation of symbols for main parts of the drawing>
S : Pressure switch P : Connection pipe
P1 : Fire pipe W : Fire pipe
1: chamber 10: body part
11: chamber body 12: upper connection pipe
13: upper connection screw 14: lower connection pipe
15: lower connection screw 20: anti-shock connection part
21: shock prevention body 22: fire water inlet groove
23: reduction inlet 24: anti-shock screw
25: tool groove 26: branch projection
27: inclined inlet 28: sealing ring

Claims (5)

In the chamber (1) for a pressure switch that is connected to the pressure switch (S) used in the firefighting equipment to minimize the water hammer and surging phenomenon,
A cylindrical chamber body 11 having a space formed therein, an upper connection pipe 12 provided on the upper portion of the chamber body 11 and fastened to the lower end of a connection pipe P connected to the pressure switch S, and , an upper connection screw 13 formed on the inner circumferential surface of the upper connection pipe 12, and a lower connection pipe provided in the lower part of the chamber body 11 and connected to the upper part of the fire pipe P1 through which the fire water W flows ( 14) and a body portion 10 comprising a lower connection screw 15 formed on an inner circumferential surface of the lower connection pipe 14;
A cylindrical shock-resistant body 21 fastened to the inside of the lower connection pipe 14, a fire-fighting water inlet groove 22 recessed to a predetermined height on the lower surface of the shock-resistant main body 21, and the fire-fighting water inlet groove ( 22) and formed on the outer peripheral surface of the anti-shock body 21 and formed at the upper end of the fire-fighting water inlet groove 22 and perforated in both directions to reduce the flow rate of the fire water (W). composed of an anti-shock connection part 20 made of an anti-impact screw 24;
A tool groove 25 is formed on the lower surface of the shock-resistant body 21, into which the tool D is inserted so as to detach or fasten the shock-resistant connection part 20 to the inside of the lower connection pipe 14;
At the upper end of the fire-fighting water inlet groove 22, a triangular branch protrusion 26 protruding downward so that the fire water (W) introduced into the fire-fighting water inlet groove 22 branches to both sides is formed;
A chamber for pressure switch for firefighting equipment, characterized in that a ring-shaped sealing ring 28 is provided on the outer circumferential surface of the shock-resistant body 21 so that the fire water (W) flowing in from the fire-fighting pipe (P1) is blocked from leaking. . delete delete delete delete

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