KR102215643B1 - Earthquake-resistant pipe joint device - Google Patents

Abstract

Provided is an earthquake-resistant pipe joint apparatus for extinguishing fire. According to the present invention, the earthquake-resistant pipe joint apparatus for extinguishing fire comprises: firefighting water supply pipes having earthquake resistance; and a connection unit which connects the firefighting water supply pipes to each other. The connection unit includes: an inner pipe connected to hollow parts of the firefighting water supply pipes, having a first flow path whose both ends are fastened with both ends of the firefighting water supply pipes; an outer pipe into which the inner pipe is inserted, and which elastically covers the outer circumference of both ends of the fire-fighting water supply pipes, forming a second flow path; and an auxiliary supply line whose one end is connected to the outer pipe to be connected to the second flow path and whose other end is fastened with preset positions of the firefighting water supply pipes to be connected to the first flow path. The present invention is able to prevent the firefighting water supply pipes from being damaged.

Description

Earthquake-resistant pipe joint device with earthquake resistance

The present invention relates to a fire-fighting pipe joint device having earthquake resistance, and more particularly, when leakage occurs due to an impact at a joint between fire water pipes, it is immediately supplied to the fire water flow path to reduce the pressure of the fire water due to leakage. It relates to a fire-fighting piping joint device having earthquake resistance to prevent.

Power cables are generally used for connecting steel pipes (pipes) installed in water and sewage, fire fighting, gas, electricity, communication, and various industrial plants. The ends of the pipes are welded against each other, or flanges formed at the ends of the pipes. With a gasket inserted in the gap, a bolt is inserted into a hole formed in the flange and fastened with a nut, or airtight parts are provided at both ends of the coupling body and a wedge-shaped ring-shaped packing is wedge-stitched to ensure airtightness. Dresser coupling method using Dresser coupling) is mainly used.

In recent years, high-intensity earthquakes frequently occur in various parts of the world, resulting in a lot of damage to people and property. Small earthquakes are frequently occurring in Korea, which was considered safe against earthquakes until now. (耐震) It was legalized to design. However, since most of the pipe joint structures so far do not consider earthquakes at all, it would be difficult to predict the damage if an earthquake of higher strength than so far in Korea occurs. In terms of shipbuilding, a seismic pipe joint structure or method capable of withstanding an earthquake of a certain intensity is urgently required.

For example, the technology emerged due to this need is patent registration No. 512467 "pipe connection device", patent registration No. 574745 "pipe joint device using flange", patent registration No. 904419 and No. 956766 "using packing. Pipe fittings", etc. Among them, when briefly describing Patent Registration No. 956766 with reference to FIG. 1, the elastic packing (1) in which a protrusion (1a) is formed in the joint to which the two pipes are connected, and the outer peripheral surface of the elastic packing are wrapped A clamp (2) for pressing and fixing the part, and a flange (3) having a groove (3a) into which the protrusion (1a) is inserted is formed at one end of the two pipes, and a fixing ring (5) at the end of the other pipe. It is a pipe joint device that is fastened by attaching a detachable flange (4) that is fixed to the outer peripheral surface of the pipe by ).

However, first, the structure of the pipe jointing device is complicated due to the large number of components that enter the pipe, and the detachable flange is mounted and fastened by a fixing ring at the end of one pipe, so if the vibration continues to occur, the detachable flange itself moves There is a problem that fluid may leak,

Second, in order to prevent the fluid from leaking when vibration occurs, the elastic packing needs to be closer to the flange as the vibration occurs.Because this point is not considered, it cannot absorb the vibration when continuous vibration occurs, and the fluid eventually leaks. There is a problem that it can be.

Conventionally, in order to solve this problem, a spring is used between the joint pipe and the pipe to be connected, and the outer end thereof is surrounded by an elastic rubber, thereby achieving damage due to impact and waterproofing between the joints.

However, if damage occurs due to an earthquake due to an earthquake in the joint part of the pipe, leakage occurs, and the pressure supplied to the sprinkler is reduced, thereby making it easier to extinguish the fire by achieving less than the injection pressure of the firefighter required to extinguish the fire. Not done.

In addition, if leakage occurs due to damage to the joint and the pipe itself, the situation cannot be solved immediately.

Korean Patent Registration No. 10-1341838

The present invention was conceived to solve the above-described problems, and the object of the present invention is as follows.

First, when leakage occurs due to an impact at the joint between the fire water pipes, it is immediately supplied to the fire water flow path to prevent a decrease in the pressure of the fire water due to the leakage.

Second, the outer periphery of the firefighter pipes is wrapped, and a space using bulkheads is formed inside, and in the event that a wobble shock is applied to the firefighter pipes and connections through an earthquake, this vibration can be attenuated. Try to avoid breakage.

In order to achieve the above objects, the present invention provides a fire-fighting pipe joint device having earthquake resistance.

The fire-fighting pipe jointing device having the earthquake resistance includes fire water supply pipes; And, a connection portion connecting between the fire water supply pipes; including,

The connection part,

An inner tube having a first flow path connected to the hollow of the fire water supply pipes, and having both ends connected to both ends of the fire water supply pipes,

The inner tube is inserted inside, both ends elastically surround the outer peripheries of both ends of the fire water supply pipes, and an outer tube forming a second flow path,

One end is connected to the outer pipe so as to be connected to the second passage, and the other end has an auxiliary supply line connected to the first passage by being fastened to a set position of the fire water supply pipes.

Here, in the outer tube,

A moisture sensor for detecting moisture is installed in the second flow path,

When moisture is sensed in the second flow path through the moisture sensor, a pump installed on the second auxiliary supply line is driven to force the moisture formed in the second flow path into the first flow path through the auxiliary supply line. It is better to have a supply controller.

And the inner tube,

A connecting pipe forming the first passage,

A pair of elastic pipes formed of an elastic material connected to both ends of the connection pipe,

A pair of connecting rings rotatably coupled to both ends of the pair of elastic tubes,

It is rotatably fastened to each of the pair of connecting rings, and has a pair of fastening pipes fastened to one end of the fire water supply pipes,

Each of the pair of fastening pipes,

One end of each of the fire water supply pipes screw-fastened at a plurality of locations periphery,

Seals are preferably installed between the plurality of positions on the inner periphery of each of the pair of fastening pipes.

In addition, a pair of cover pipes are formed at both ends of the outer pipe,

In the pair of cover tubes,

Each of the firefighter pipes is fitted,

At the ends of the pair of cover tubes,

An airtight ring in close contact with the outer periphery of each of the fire water pipes is installed,

The outer diameter of the outer periphery of one end of each of the fire water pipes,

An extension section that gradually expands along the other end side from one end of each of the firefighter pipes is formed,

The extended section is preferably placed inside the pair of cover pipes.

In particular, in the pair of cover pipes,

The supply tube is connected,

The supply tube is connected to the foam material feeder,

When a leak is detected from the leak sensor,

The controller supplies the foam material to the inside of the pair of cover pipes using the foam material feeder.

In addition, wires are bound between the ends of the pair of cover pipes and the outer circumferences of each of the firefighter pipes disposed on both sides of the connection part.

In addition, each of the wires is connected to the winding machines.

Each of the fire water pipes is provided with an impact sensor. The impact sensor transmits the measured impact to the controller. When the measured impact reaches a preset impact corresponding to an earthquake, the controller unwinds the wires to a predetermined length using the winders.

In addition, vacuum layers forming multiple layers are formed inside the inner tube and the outer tube.

Each of the vacuum layers achieves a predetermined vacuum by receiving a vacuum through a vacuum provider. When the impact reaches a certain level or more, the controller controls to achieve a set vacuum in the vacuum layers using the vacuum provider.

As described above, according to the present invention, when leakage occurs due to an impact at a joint between fire water pipes, it is immediately supplied to the fire water flow path to prevent a decrease in fire water pressure due to the leakage,

It covers the outer periphery of the firefighter pipes, forms a space using bulkheads inside, and reduces the vibration when a wobble impact is applied to the firefighter pipes and connections through earthquakes, thereby preventing damage to the connection and firefighter pipes according to the vibration. Can be prevented.

1 is a view showing a conventional firefighter joint member.
2 is a view showing a fire fighting pipe joint device having earthquake resistance of the present invention.
3 is a view showing an example in which the cover tube is further installed on the outer tube according to the present invention.
4 is a view showing an example in which the cover pipe according to the present invention is connected to a foam material feeder.
5 is a view showing an example in which the end of the cover pipe and each of the firefighter pipes according to the present invention are connected through wires.
6 is a view showing an example in which vacuum layers are formed on the outer tube and the inner tube according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those of ordinary skill in the art may easily implement the present invention.

The present invention may be implemented in various different forms and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description have been omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

Hereinafter, it means that an arbitrary configuration is provided or arranged on the "upper (or lower)" or "upper (or lower)" of the substrate, wherein the arbitrary configuration is provided or arranged in contact with the upper (or lower) surface of the substrate. Means that.

In addition, it is not limited to not including other configurations between the substrate and any configuration provided or disposed on (or under) the substrate.

Next, the present invention will be described with reference to the accompanying drawings.

2 is a view showing a fire fighting pipe joint device having earthquake resistance of the present invention.

Referring to FIG. 2, the fire fighting pipe jointing device having earthquake resistance includes a fire fighting water supply pipe 100 and a connection part 200 connecting between the fire water supply pipes 100.

The connection part 200 is connected to the hollow of the fire water supply pipes 100, and has an inner tube 210 having a first flow path connected to both ends of the fire water supply pipes 100, and the internal The pipe 210 is inserted, and both ends elastically surround the outer circumferences of both ends of the fire water supply pipes 100, the outer pipe 220 forming a second flow path, and one end is connected to the second flow path. It has an auxiliary supply line 300 connected to the outer pipe 220, the other end is fastened to the set position of the fire water supply pipes 100 and connected to the first passage.

Here, in the outer tube 220, a moisture sensor 230 for sensing moisture in the second flow path is installed.

When moisture is detected in the second passage through the moisture sensor 230, the pump 310 installed on the second auxiliary supply line 300 is driven to supply the moisture formed in the second passage A controller 320 forcibly supplying the first flow path through the line 300 is provided.

And the outer pipe 220, a connection pipe 221 forming the second flow passage, a pair of elastic pipes 222 formed of an elastic material connected to both ends of the connection pipe 221, and the It is rotatably coupled to both ends of the pair of elastic pipes 222, and has a pair of fastening pipes 223 fastened to one end of the fire water supply pipes 100.

Each of the pair of fastening pipes 223 is screw-fastened at a plurality of positions at one end of each of the fire water supply pipes 100.

Seals 224 are installed between the plurality of positions on the inner periphery of each of the pair of fastening pipes 223.

3 is a view showing an example in which the cover tube is further installed on the outer tube according to the present invention.

Referring to FIG. 3, a pair of cover tubes 250 are formed at both ends of the outer tube 220.

Each of the firefighter pipes 100 is fitted to the pair of cover pipes 250.

At the ends of the pair of cover pipes 250, an airtight ring 260 in close contact with the outer periphery of each of the fire water pipes 100 is installed.

The outer diameter of the outer circumference of one end of each of the firefighter pipes 100 is formed with an extension section 110 gradually extending from one end of the firefighter pipes 100 to the other end,

The extension section 110 is placed inside the pair of cover pipes 250, and is coupled to the outer surface of the extension section in close contact with the inner circumference of the cover tube 250 in a screw manner.

4 is a view showing an example in which the cover pipe according to the present invention is connected to a foam material feeder.

Referring to FIG. 4, a supply tube 410 is connected to the pair of cover tubes 250.

The supply tube 410 is connected to the foam material feeder 400.

When the leak is detected from the leak sensor 230, the controller 320 supplies the foam material to the inner space of the pair of cover pipes 250 using the foam material feeder 400.

5 is a view showing an example in which the end of the cover pipe and each of the firefighter pipes according to the present invention are connected through wires.

Referring to FIG. 5, wires 500 are bound between the ends of the pair of cover pipes 250 and the outer circumferences of each of the firefighter pipes 100 disposed on both sides of the connection part 200.

In addition, one end of each of the wires 500 is connected to the winding machines 510. The winding machines 510 are installed in a plurality on the outer periphery of the ends of each cover tube 250 disposed on both sides of the connection part.

In addition, the other end of each of the wires 500 is connected to a ring 501 formed on the outer periphery of the firefighter pipes 100.

Each of the fire water pipes 100 is provided with an impact sensor 150. The impact sensor 150 transmits the measured impact to the controller 320. When the measured impact reaches a preset impact corresponding to an earthquake, the controller 320 releases the wires 500 to a predetermined length using the winders 510.

6 is a view showing an example in which vacuum layers are formed on the outer tube and the inner tube according to the present invention.

Referring to FIG. 6, vacuum layers 10 forming multiple layers are formed inside the inner tube 210 and the outer tube 220.

Each of the vacuum layers 10 is provided with a vacuum through a vacuum provider 20 to achieve a predetermined vacuum. The controller 320 controls to achieve a vacuum set in the vacuum layers 10 using the vacuum provider 20 when the impact reaches a certain level or more. The vacuum in the vacuum layers 10 is measured by a vacuum sensor 30, and the measured vacuum is transmitted to the controller 320. Accordingly, the controller 320 controls the driving of the vacuum provider 20 so that the transmitted vacuum achieves a set vacuum.

According to the above configuration and operation, according to the present invention, when water leakage occurs due to an impact at the joint between the fire water pipes, it is immediately supplied to the fire water flow path to prevent a decrease in the pressure of the fire water due to the leakage.

In addition, the present invention surrounds the outer periphery of firefighter pipes, forms a space using bulkheads therein, and can attenuate the vibration when a wah-bu impact is applied to the firefighter pipes and connections through an earthquake. It is possible to prevent damage to the pipe.

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

100: firefighter piping
200: connection
300: auxiliary supply line

Claims (4)

Fire water supplies; And,
Including; a connection part connecting between the fire water supply pipes,
The connection part,
An inner pipe connected to the hollow of the fire water supply pipes, and having a first flow passage connected at both ends of the fire water supply pipes,
The inner tube is inserted inside, and both ends elastically surround the outer circumference of both ends of the fire water supply pipes, and an outer tube forming a second flow path,
One end is connected to the outer pipe so as to be connected to the second passage, and the other end has an auxiliary supply line connected to the first passage by being fastened to a set position of the fire water supply pipes,
In the outer tube,
A moisture sensor for detecting moisture is installed in the second flow path,
When moisture is sensed in the second flow path through the moisture sensor, a pump installed on the auxiliary supply line is driven to forcibly supply the moisture formed in the second flow path to the first flow path through the auxiliary supply line. Provided with a controller,
The inner tube,
A connecting pipe forming the first passage,
A pair of elastic pipes formed of an elastic material connected to both ends of the connection pipe,
A pair of connecting rings rotatably coupled to both ends of the pair of elastic tubes,
It is rotatably fastened to each of the pair of connecting rings, and has a pair of fastening pipes fastened to one end of the fire water supply pipes,
Each of the pair of fastening pipes,
One end of each of the fire water supply pipes screwed at multiple locations on the outer periphery,
Seals are installed between the plurality of positions on the inner periphery of each of the pair of fastening pipes,
Fire-fighting piping joints with earthquake resistance.
delete delete The method of claim 1,
A pair of cover pipes are formed at both ends of the outer pipe,
In the pair of cover tubes,
Each of the fire water supply pipes are fitted,
At the ends of the pair of cover tubes,
An airtight ring in close contact with the outer periphery of each of the fire water supply pipes is installed,
The outer diameter of one end of each of the fire water supply pipes,
An extension section that gradually expands along the other end from one end of each of the fire water supply pipes is formed,
The extended section is placed inside the pair of cover pipes,
Fire-fighting piping joints with earthquake resistance.

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