KR101911825B1 - Oscillating device for fire extinguishing - Google Patents

Abstract

The present invention relates to a fire extinguisher which is provided in a ship, an oil refinery, a petrochemical plant, etc. handling crude oil, gas, chemical gas, etc., and which suppresses fire quickly by using high- To an oscillating device.
The present invention relates to a fire extinguishing apparatus for a fire extinguishing system together with a monitor device, the fire extinguishing system comprising: a fire extinguishing water supply pipe for supplying high-pressure fire extinguishing water flowing through a lower portion upward; A rotary connection pipe rotatably installed on an upper portion of the pressurized water supply pipe and connected to the monitor device at an upper portion thereof to supply the pressurized water to the monitor device; Power generating means provided at one side of the pressurized water supply pipe in communication with the inside of the pressurized water supply pipe and generating rotational power using a part of the pressurized water; And reciprocating means for connecting the power generating means and the rotary connection pipe to make the rotary connection pipe reciprocally rotate within the predetermined rotation radius by the rotary power, wherein the reciprocating means is directly connected to the monitor device And the monitor device is reciprocally rotated through the rotation connection pipe to spray the high-pressure quenching water at a constant rotation radius to suppress the fire. The present invention is directed to a fire extinguishing apparatus for fire extinguishing.

Description

[0001] Oscillating device for fire extinguishing [0002]

The present invention relates to a fire extinguisher which is provided in a ship, an oil refinery, a petrochemical plant, etc. handling crude oil, gas, chemicals, etc., and is capable of rapidly suppressing a fire by using high- To an oscillating device.

In general, fire, oil, gas, chemicals, and other vessels, oil refineries, and petrochemical plants will cause enormous personal and property damage, as well as outflows of oil, gas and chemicals. Pollution and destruction of ecosystems.

In order to minimize the damage caused by these fires, fire-fighting devices are installed in vessels handling crude oil, gas, and chemicals, refineries, petrochemical plants, etc. to enable quick suppression in the early stages of a fire.

As shown in FIG. 1, the fire suppression device is composed of a plurality of units corresponding to the scale of a ship, an oil refinery, a petrochemical plant, and the like. The fire suppressing unit is largely composed of an oscillating device 1 and a monitor device 2 .

The oscillating device 1 automatically supplies the monitor device 2 with a certain amount of pressure to the monitor device 2 while supplying the high pressure water such as seawater or water for fire extinguishing through the lower part to the monitor device 2 In the left-right direction.

The monitoring device 2 is connected to the upper part of the oscillating device 1 and injects the supplied high-pressure water to be sprayed while reciprocally rotating left and right automatically within a predetermined radius of rotation to suppress the fire.

At this time, the oscillating device (1) includes a back pressure water supply pipe (1a) to which the monitor device (2) is fastened at the upper portion, a power generation means And a reciprocating means 1c for connecting the power generating means 1b and the monitor device 2 and reciprocally rotating the monitor device 2 by the rotational power of the power generating means 1b .

On the other hand, in the oscillating device 1, since the reciprocating means 1c is directly connected to the monitor device 2, the oscillating device 1 is structurally and physically connected to only the monitor device 2, There is a limit.

That is, the third-party monitoring device 2 is not structurally compatible with the oscillating device 1 of a specific company, so that only the monitor device 2 of the company is required to be used.

Therefore, the conventional oscillating device 1 can not use other incompatible monitor devices 2, so that it is difficult to supply and receive when the monitor device 2 needs to be replaced due to aging or failure of the monitor device 2, There is a problem that it is very cumbersome and inefficient to replace the entire fire suppression device with a new one.

Korean Public Registration No. 20-2013-0002553, April 29, 2013.

It is an object of the present invention to provide an oscillating device for fire extinguishing which is compatible with a monitor device and can be connected to a monitor device having various structures and shapes.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood from the following description.

According to another aspect of the present invention, there is provided an apparatus for fire extinguishing a fire extinguishing system comprising a monitoring device and a fire extinguishing device, the fire extinguishing device comprising: ; A rotary connection pipe rotatably installed on an upper portion of the pressurized water supply pipe and connected to the monitor device at an upper portion thereof to supply the pressurized water to the monitor device; Power generating means provided at one side of the pressurized water supply pipe in communication with the inside of the pressurized water supply pipe and generating rotational power using a part of the pressurized water; And reciprocating means for connecting the power generating means and the rotary connection pipe to make the rotary connection pipe reciprocally rotate within the predetermined rotation radius by the rotary power, wherein the reciprocating means is directly connected to the monitor device And the monitor device is reciprocally rotated through the rotation connection pipe so as to spray the high-pressure quenching water at a constant rotation radius to suppress the fire.

The oscillating device for fire extinguishing according to the present invention having the above-mentioned configuration can ensure compatibility with monitor devices having various structures and shapes, and when it is necessary to replace due to aging or breakdown of the monitor device, It can be replaced with another monitor device, so maintenance management is very convenient.

1 is a photograph of a conventional digester oscillating device.
2 is a photograph of one side of the digester oscillating device according to the present invention.
FIG. 3 is a photograph of the other side of the digester oscillating device according to the present invention. FIG.
4 is a plan view photograph of the digester oscillating device according to the present invention.
FIG. 5 is a photograph of a bottom surface of a digesting oscillator according to the present invention. FIG.
6 is an exploded bottom view of the digester's oscillating device according to the present invention.
FIG. 7 is a cross-sectional view of the other side of the digesting oscillator according to the present invention
8 is a cross-sectional view of one side of the digester's oscillating device according to the present invention.
9 is a plan sectional view of an apparatus for fire extinguishing according to the present invention.

FIELD OF THE INVENTION The present invention relates to a fire extinguishing apparatus for a fire extinguishing system which is installed in a fixed structure such as a ship, an oil refinery, a petrochemical factory, etc. handling crude oil, gas,

In particular, the fire extinguishing oscillator according to the present invention is compatible with a monitor device constituting a fire suppression device, and can be used by connecting monitor devices having various structures and shapes.

In this aspect, a rotary connection pipe connected to the monitor device is rotatably installed on the upper part of the suppression water supply pipe, and a reciprocating means for reciprocatingly rotating the monitor device within a predetermined radius of rotation is provided between the pressure water supply pipe and the rotary connection pipe Structure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a fire extinguishing apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 to 9, the oscillating apparatus for fire extinguishing according to the preferred embodiment of the present invention is provided with a pressurized water supply pipe 10, a rotary connection pipe 20, a power generating means 30 and a reciprocating means 40, .

First, the pressurized water supply pipe 10 is vertically fixed to an installation site provided at a ship, an oil refinery, a petrochemical factory, and the like, and supplies the high pressure water to a monitor device (not shown).

To this end, the pressurized water supply pipe 10 is formed in the form of a pipe, and a lower flange 11 is provided for connection with a supply pipe (not shown) for supplying pressurized water to the lower portion.

However, the suppression water can be seawater or fire water depending on the installation site.

Next, the rotary connection pipe 20 is rotatably fastened to the upper portion of the backwash water supply pipe 10 to supply the high-pressure backwash water to the monitor device, and at the same time, the monitor device can be reciprocally rotated.

To this end, the rotary connection pipe 20 is formed in the shape of a pipe, and a connection flange 21 for connection with the monitor device is installed on the upper part. The lower portion of the rotary connection pipe 20 is connected to the upper portion of the pressurized water supply pipe 10 with the rotary fastening means interposed therebetween so as to be rotatably connected to the pressurized water supply pipe 10.

7, the rotation fastening means comprises a connecting ring 22, a first guide ring 23, a second guide ring 24, fastening means 25, and a plurality of ball bearings 26 .

The connection ring 22 is fixed to the outer side of the lower end of the rotary connection pipe 20 and has a ball bearing groove 221 formed on the outer peripheral surface of the lower end.

The first guide ring 23 is fixed to the outside of the upper end of the decompression water supply pipe 10.

The second guide ring 24 is installed on the upper side of the first guide ring 23 and is extruded to the lower end of the connecting ring 22 and has a ball bearing groove 241 formed on the inner circumferential surface thereof.

The fastening means 25 fastens the first guide ring 23 and the second guide ring 24.

The ball bearings 26 are arranged at predetermined intervals along the ball bearing grooves 221 of the connecting ring 22 and the ball bearing grooves 241 of the second guide ring 24.

The rotary connecting pipe 20 together with the connecting ring 22 is rotatable on the pressurized water supply pipe 10 by the ball bearing 26 disposed between the connecting ring 22 and the second guide ring 24 .

It is to be noted that the pressure of water that has passed through the pressurized water supply pipe 10 between the connection ring 22 and the second guide ring 24 and between the first guide ring 23 and the second guide ring 24, And an O-ring 27 is installed so as not to flow out into the gap when flowing into the pipe 20.

Next, the power generating means 30 is connected to one side of the pressurized water supply pipe 10, and a part of the pressurized water passing through the inside of the pressurized water supply pipe 10 is branched to one side to generate it as rotational power.

To this end, the power generating means 30 is constituted by a branch pipe 31, an injection nozzle 32, a turbine wheel 33 and a rotary plate 34, as shown in Figs.

The branch pipe 31 is provided at one side of the submerged water supply pipe 10 so as to communicate with the inside of the submerged water supply pipe 10 and branches part of the submerged water passing through the inside of the submerged water supply pipe 10 to one side.

 The injection nozzle 32 is provided at an end of the branch pipe 31 and injects the pressurized water branched by the branch pipe 31 at a high pressure.

The turbine wheel 33 is rotatably installed on one side of the branch pipe 31 and has a rotation induction groove 332 formed on its outer surface to rotate at a high speed .

The rotating plate 34 is connected to the rotating shaft 331 of the turbine wheel 33 and is rotated by the turbine wheel 33.

That is, the quenching water branched by the branch pipe 31 is injected into the injection nozzle 32 to rotate the turbine wheel 33 at a high speed and the rotating plate 34 is rotated at a constant speed by the turbine wheel 33, .

When the injection nozzle 32 is welded to the end of the branch pipe 31, the branch pipe 31 is sprayed so as to be sprayed toward the rotation induction groove 332 of the turbine wheel 33, So that the installation angle of the nozzle 32 is easily adjusted.

A high speed rotation of the turbine wheel 33 is decelerated by a predetermined ratio between the rotation axis 331 of the turbine wheel 33 and the rotation axis 341 of the rotation plate 34 and is transmitted to the rotation axis 341 of the rotation plate 34 A speed reducer 35 is provided.

The power generating means 30 further includes a protective collecting box 36 for preventing safety accidents caused by exposure of the turbine wheel 33.

The protective collecting box 36 is installed at an end of the spray nozzle 32 and outside the turbine wheel 33 and has a cylindrical shape surrounding the turbine wheel 33 from outside and has a drain hole 361 at a lower portion thereof.

Therefore, the protective housing 361 prevents the turbine wheel 33 from being exposed to the outside, and the number of pressurized water sprayed by the turbine wheel 33 is not scattered in all directions, And the slip accident that occurs due to the freezing of the suppressed water scattered.

At this time, a blocking plate 37 is installed on the upper side of the turbine wheel 33 as shown in FIG. However, the blocking plate 37 has a size corresponding to or larger than the turning radius of the turbine wheel 33.

Therefore, the blocking plate 37 prevents the rotating shaft 331 and the decelerator 35 from being corroded by the quenching water by preventing the quenching water hitting the turbine wheel 33 from splashing onto the upper portion of the turbine wheel 33, Even if the jetting angle of the water is slightly changed, the repelling water is reflected to the rotation inducing groove 332 of the turbine wheel 33 so that the rotational power is smoothly generated.

However, the blocking plate 37 may be installed on the upper side of the turbine wheel 33 in a separate configuration without any clearance, or may be integrally formed with the turbine wheel 33 on the upper side of the turbine wheel 33.

Finally, the reciprocating means 40 is installed between the power generating means 30 and the rotary connection pipe 20, and uses the rotary power generated by the power generating means 30 to connect the rotary connection pipe 20 And reciprocally rotates within a predetermined rotation radius.

To this end, the reciprocating means 40 is composed of a fastening hole 41, a fastening hole 42, a connecting bar 43 and a connecting hole 44 as shown in FIGS.

The coupling bar 42 is inserted into the coupling hole 41 and the coupling bar 43 is inserted into the coupling hole 42. The coupling bar 42 is inserted into the coupling hole 42, And the end of the connection bar 43 is rotatably connected to one side of the connection ring 22 of the rotary connection pipe 20. [

That is, when the rotary plate 34 is rotated by the rotational power of the power generating means 30, the connecting bar 43 reciprocates correspondingly and reciprocates, The connection ring 22 is automatically reciprocated left and right within a predetermined radius of rotation.

Accordingly, the monitor device automatically rotates left and right in a predetermined radius of rotation, and injects the high-pressure suppressing water, thereby rapidly suppressing the fire. At this time, a plurality of fastening holes 41 are formed at predetermined intervals along the radial direction of the rotary plate 34, and the rotation radius of the monitor device can be adjusted by changing the installation position of the fastening holes 42.

Since the reciprocating means 40 is directly connected to the rotary connector 20 which is not connected to the monitor device but connects the monitor device and the decompression water supply pipe 10, the reciprocating means 40 is compatible with the monitor device having various structures and shapes .

Therefore, it is very convenient to maintain the maintenance because it is not necessary to replace the whole fire extinguisher even if it is difficult or impossible to supply the monitor device when the monitor device needs to be replaced due to aging or breakdown.

The above-described embodiments are merely illustrative, and various modifications may be made by those skilled in the art without departing from the scope of the present invention.

Therefore, the true technical protection scope of the present invention should include not only the above embodiments but also various other modified embodiments according to the technical idea of the invention described in the following claims.

10: Suppression water supply pipe
11: Lower flange
20: Rotary connector
21: Connecting flange
22: Connecting ring
221: Ball bearing groove
23: first guide ring
24: second guide ring
241: Ball bearing groove
25: fastening means
26: Ball Bearing
27: O ring
30: Power generating means
31: Branch organization
32: injection nozzle
33: Turbine wheel
331:
332:
34:
341:
35: Reducer
36: Protection Collector
361: Sewer
37:
40: reciprocating means
41: fastening ball
42: fastener
43: Connection bar
44: Connector

Claims (5)

A fire extinguishing system for a fire extinguishing system together with a monitor device,
A backwash water supply pipe (10) for supplying high pressure backwash water flowing through the lower portion to the upper portion;
A rotary connection pipe (20) rotatably installed on an upper portion of the pressurized water supply pipe (10) and connected to the monitor device at an upper portion thereof to supply the pressurized water to the monitor device;
Power generating means (30) provided at one side of the pressurized water supply pipe (10) so as to communicate with the inside of the pressurized water supply pipe (10) and generating rotational power using a part of the pressurized water; And
And reciprocating means (40) for connecting the power generating means (30) and the rotary connection pipe (20) and reciprocatingly rotating the rotary connection pipe (20) with the rotary power within a predetermined rotation radius,
The reciprocating means 40 is not directly connected to the monitor device but is connected through the rotary connection pipe 20 so as to reciprocally rotate the monitor device to spray the high- In addition,
The rotary connection pipe (20)
A connection ring 22 fixed to the lower end of the rotary connection pipe 20 and formed with a ball bearing groove 221 at the lower end peripheral surface thereof and a first guide ring 23 fixed to the outside of the upper end of the suppression water supply pipe 10 And a ball bearing groove 241 formed on an inner peripheral surface of the first guide ring 23 so as to be extruded at a lower end of the connecting ring 22 and a first guide ring 23 And a plurality of ball bearings (241) provided at predetermined intervals in the ball bearing grooves (221) of the connecting ring (22) and the ball bearing grooves (241) of the second guide ring (24) 26) is rotatable on the pressurized water supply pipe (10)
The power generating means (30)
A branch nozzle 31 branched from one side of the suppression water supply pipe 10; an injection nozzle 32 provided at an end of the branch pipe 31; A turbine wheel 33 which rotates by the branching tube 31 and the jetting nozzle 32 by the quenching water partially branched from the quenching water and a rotary plate 33 connected to the rotary shaft 331 of the turbine wheel 33, And a protective collecting box 36 installed at an end of the injection nozzle 32 and the outside of the turbine wheel 33 and having a drain hole 361 formed at a lower portion thereof,
The reciprocating means (40)
A plurality of fastening holes 41 formed at upper and lower portions of the rotary plate 34 at regular intervals along the radial direction of the rotary plate 34 and a fastening hole 42 through which the lower portion is inserted into the fastening hole 41, Wherein the rotation radius of the monitor device is adjustable by varying the mounting position of the monitor device. delete The method according to claim 1,
An O-ring 27 is provided between the connection ring 22 and the second guide ring 24 and between the first guide ring 23 and the second guide ring 24, respectively A device for fire extinguishing. delete The method according to claim 1,
On the upper side of the turbine wheel 33
Wherein a blocking plate (37) having a size larger than the turning radius of the turbine wheel (33) is installed.

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