KR101631163B1 - Wet type sprinkler system for preventing metal pipe corrosion - Google Patents

Abstract

The present invention relates to a wet-type sprinkler system capable of preventing the corrosion of a metallic pipe capable of preventing the corrosion of a water supply pipe and a branched pipe made of a metallic materials such as copper and the like by preventing air from remaining inside the water supply pipe and the branched pipe. The wet-type sprinkler system capable of preventing the corrosion of the metallic pipe according to the present invention includes: a water supply device supplying fire water; the water supply pipe distinguished into a first water supply pipe in a front side of a check valve and a second water pipe in a rear side of the check valve; the branched pipe branched from one side of the second water supply pipe; a sprinkler head formed in one end of the branched pipe and injecting the fire water to the outside; a test pipe branched from one side of the branched pipe; a drain main pipe branched from one side of the second water supply pipe; and a drain pipe structure connected and formed to/in one side of the drain main pipe. The drain pipe structure includes a drain connection pipe connected to the drain main pipe and a vacuum pipe (or an inert gas supply pipe) branched from one side of the test pipe or branched from a spot of the drain connection pipe. A vacuum pump or an inert gas supply device is formed in one end of the vacuum pipe or the inert gas supply pipe. Air inside the second water supply pipe and the branch pipe is discharged by the operation of the vacuum pump or the inert gas supply device.

Description

[0001] The present invention relates to a wet type sprinkler system for preventing corrosion of a metal pipe,

The present invention relates to a wet sprinkler device capable of preventing corrosion of metal pipes, and more particularly, to a wet sprinkler device capable of preventing air from remaining in a water supply pipe and a branch pipe, Sprinkler device.

In high-rise buildings such as apartments, a sprinkler facility is mandatory for early fire suppression (see Korean Patent No. 1171949).

As shown in FIG. 9, the wet sprinkler facility of the sprinkler facility generally includes a water supply device 31 for supplying water for fire fighting, a water supply pipe and a water supply pipe, and a sprinkler head 35, (34). In addition, a check valve 36 selectively opened by a pressure difference is provided at one point of the water supply pipe, and a pressure gauge is provided at the front end and the rear end of the check valve 36, respectively. The water supply pipe is divided into a primary water supply pipe 32 between the water supply unit 31 and the check valve 36 and a secondary water supply pipe 33 between the check valve 36 and the branch pipe 34.

The principle of spraying the fire water through the sprinkler head 35 is as follows. When the sealing state of the sprinkler head 35 is released by the occurrence of fire in the state where the primary water supply pipe 32 and the secondary water supply pipe 33 are filled with the pressurized water of 6 to 10 atm and the secondary water supply pipe 33 and / The water for fire extinguishing that is filled in the branch pipe (34) is injected to the outside through the sprinkler head (35). A pressure difference is generated between the secondary side water supply pipe 33 and the primary side water supply pipe 32 as the fire water in the secondary side water supply pipe 33 is injected through the sprinkler head 35. Due to such a pressure difference, 36 are opened and the water for fire extinguishing water of the water supply device 31 is supplied to the secondary water supply pipe 33 through the primary water supply pipe 32 so that it is possible to continuously supply the water for fire extinguishing water to the sprinkler head 35.

On the other hand, when the wet sprinkler facility is newly installed or when the sprinkler head 35 is replaced after the occurrence of a fire, the process of filling the secondary water supply pipe 33 and the branch pipe 34 with digestion water, that is, the filling process, proceeds. The water supply device 31 is connected to the secondary water supply pipe 33 and the branch pipe 34 via the primary water supply pipe 32 in a state where the sprinkler head 35 in the sealed state is mounted on the branch pipe 34. [ As shown in FIG.

The air in the secondary side water supply pipe 33 and the branch pipe 34 is pushed by the high pressure water for digestion and is exhausted through an exhaust valve provided on one side of the secondary side water supply pipe 33, It is clogged with the head and can not be exhausted and remains in the branch pipe (34). The air remaining in the branch pipe 34 is pressurized by the high-pressure water for fire and is positioned on the upper side of the branch pipe 34 by the difference in specific gravity (see the "high-pressure air layer" in FIG.

When pressurized air at a high pressure of 6 to 10 atm is present on the upper side of the branch pipe, the dissolved oxygen concentration in the branch pipe becomes generally higher. In addition, as the dissolved oxygen concentration is proportional to the oxygen partial pressure, the dissolved oxygen concentration of the digestive water adjacent to the pressurized air layer has a relatively larger value than the dissolved oxygen concentration of the digestive water separated from the pressurized air layer. In the case where the branch pipe is made of a metal material such as copper (Cu), a difference in dissolved oxygen concentration depending on the position of the water for digestion induces the formation of an oxygen concentration cell action (refer to Non-Patent Documents 1 and 11 Reference). The oxygen reduction reaction (1 / 2O ₂ + H ₂ O + 2e → 2OH ^- ) takes place at the cathode, which is adjacent to the pressurized air layer and has a very high dissolved oxygen concentration. At the anode, the corrosion reaction (Cu → Cu ^{2 +} + 2e) occurs, resulting in corrosion of the branch pipe. Corrosion of the branch pipe is directly linked to leakage. FIG. 12 is a photograph and SEM photograph of the surface and the interior of the copper bifurcation which was corroded due to the difference in dissolved oxygen concentration by the pressurized air layer, showing that the inner surface of the branch was heavily corroded and the corroded hole was deep.

Korean Patent No. 1171949

Title; Introduction to Corrosion Science, author; Edward McCafferty, Year of Publication; 2010, Publisher; Springer Science & Business Media; 86-89.

The present invention has been devised in order to solve the above problems, and it is an object of the present invention to prevent the air from remaining in the water supply pipe and the branch pipe and to prevent the corrosion of the water supply pipe and the branch pipe due to the difference between the high dissolved oxygen concentration in the fire water and the local dissolved oxygen concentration And it is an object of the present invention to provide a wet sprinkler device capable of preventing corrosion of metal pipes which can be suppressed.

According to an aspect of the present invention, there is provided a wet type sprinkler device for preventing corrosion of a metal pipe, comprising: a water supply device for supplying water for fire fighting; A water supply pipe which transfers the fire water to the sprinkler head and divided into a primary water supply pipe at the front end and a secondary water supply pipe at the rear end based on the check valve; A water supply valve provided in the primary side water supply pipe; A branch pipe provided on one side of the secondary side water supply pipe in a branched form; A sprinkler head provided at one end of the branch pipe for spraying the water for fire externally; A drain main pipe branched from one side of the secondary side water supply pipe; A drain main valve provided in the drain main pipe; And a vacuum pump provided at one side of the drain main pipe, wherein the operation of the vacuum pump enables the air in the secondary side supply pipe and the branch pipe to be exhausted to the vacuum pump.

And a drain pipe structure connected to one side of the drain main pipe, wherein the drain pipe structure includes a drain connection pipe connected to the drain main pipe, and a drain connection pipe connected to one end of the drain connection pipe, And a vacuum pump is provided at one end of the vacuum pipe. With the operation of the vacuum pump, the air in the secondary pipe and the branch pipe can be exhausted to the vacuum pump.

Wherein the drain connection pipe is provided with a drain auxiliary valve and the vacuum pipe is provided with a vacuum valve, the water supply valve and the drain auxiliary valve are shut off, the drain main valve and the vacuum valve are opened, The secondary side water supply pipe and the branch pipe can be exhausted by the operation.

Further, the drain main valve and the vacuum valve are shut off, and the water supply valve is opened to enable water supply to the secondary water supply pipe and the branch pipe to be completed.

Wherein the check valve is selectively opened only in the direction of the secondary side water supply pipe and is provided with a first pressure gauge and a second pressure gauge in each of the primary side water supply pipe and the secondary side water supply pipe and the pressure difference between the first pressure gauge and the second pressure gage exceeds a set reference value The check valve is opened and the fire water of the primary water supply pipe is introduced into the secondary water supply pipe through the check valve by the pressure difference between the primary water supply pipe and the secondary supply water pipe.

A test pipe is further provided at one end of the branch pipe, one end of the test pipe is connected to a drain connection pipe of the drain pipe structure, a test valve is provided at one side of the test pipe, And the exhaust of the secondary side water supply pipe and the branch pipe is enabled by the operation of the vacuum pump with the drain main valve, the test valve and the vacuum valve being opened.

The drain main valve, the test valve, and the vacuum valve are shut off, and the water supply valve is opened to allow water to be added to the secondary water supply pipe and the branch pipe.

A wet sprinkler device capable of preventing corrosion of a metal pipe according to the present invention comprises a water supply device for supplying water for fire fighting; A water supply pipe which transfers the fire water to the sprinkler head and divided into a primary water supply pipe at the front end and a secondary water supply pipe at the rear end based on the check valve; A water supply valve provided in the primary side water supply pipe; A branch pipe provided on one side of the secondary side water supply pipe in a branched form; A sprinkler head provided at one end of the branch pipe for spraying the water for fire externally; A drain main pipe branched from one side of the secondary side water supply pipe; A drain main valve provided in the drain main pipe; And an inert gas supply device provided at one side of the drain main pipe. The inert gas supply device supplies an inert gas of high pressure to the secondary side water supply pipe and the branch pipe, So that the air in the chamber can be exhausted.

And a drain pipe structure connected to one side of the drain main pipe, wherein the drain pipe structure includes a drain connection pipe connected to the drain main pipe, and a drain connection pipe connected to one end of the drain connection pipe, And an inert gas supply device is provided at one end of the inert gas supply pipe, and inert gas is supplied to the secondary supply pipe and the branch pipe by the operation of the inert gas supply device So that the air in the secondary side water supply pipe and the branch pipe can be exhausted.

Wherein the drain connection pipe is provided with a drain auxiliary valve, the inert gas supply pipe is provided with an inert gas supply valve, the water supply valve and the drain auxiliary valve are shut off, and the drain main valve and the inert gas supply valve are opened Pressure inert gas is supplied to the secondary side supply pipe and the branch pipe via the drain connection pipe and the drain main pipe by the operation of the inert gas supply device and the drain connection pipe and the drain main pipe 2 The air in the main supply pipe and the branch pipe is exhausted. Further, a vent valve is provided on one side of the secondary side water supply pipe, and air in the secondary side water supply pipe and the branch pipe is exhausted through the vent valve.

The drain main valve and the inert gas supply valve are shut off, and the water supply valve is opened to allow water to be added to the secondary water supply pipe and the branch pipe.

A test pipe is further provided at one end of the branch pipe, one end of the test pipe is connected to a drain connection pipe of the drain pipe structure, a test valve is provided at one side of the test pipe, The secondary main supply pipe and the air in the branch pipe are exhausted by the high-pressure inert gas supplied from the inert gas supply device while the drain main valve, the test valve and the inert gas supply valve are opened.

The drain main valve, the test valve, and the inert gas supply valve are shut off, and the water supply valve is opened to allow water to be added to the secondary water supply pipe and the branch pipe.

A wet sprinkler device capable of preventing corrosion of a metal pipe according to the present invention includes a water supply device for supplying water for fire fighting; A water supply pipe which transfers the fire water to the sprinkler head and divided into a primary water supply pipe at the front end and a secondary water supply pipe at the rear end based on the check valve; A water supply valve provided in the primary side water supply pipe; A drain main pipe branched from one side of the secondary side water supply pipe; A drain main valve provided in the drain main pipe; And a branch pipe provided in a form branched on one side of the secondary side water supply pipe; A sprinkler head provided at one end of the branch pipe for spraying the water for fire externally; A test pipe provided in a branched form at one end of the branch pipe; A test valve provided in the test pipe; And a vacuum pump selectively connected to one end of the test pipe. By the operation of the vacuum pump, the air in the secondary supply pipe and the branch pipe can be exhausted to the vacuum pump.

The water supply valve and the drain main valve are shut off while the vacuum pump is connected to the test pipe and the vacuum pump is allowed to exhaust the secondary water supply pipe and the branch pipe by the operation of the vacuum pump when the test valve is opened Do.

The drain main valve and the test valve are shut off, and the water supply valve is opened to allow water to be added to the secondary water supply pipe and the branch pipe.

In addition, a wet sprinkler device capable of preventing corrosion of a metal pipe according to the present invention includes a water supply device for supplying fire water; A water supply pipe which transfers the fire water to the sprinkler head and divided into a primary water supply pipe at the front end and a secondary water supply pipe at the rear end based on the check valve; A water supply valve provided in the primary side water supply pipe; A drain main pipe branched from one side of the secondary side water supply pipe; A drain main valve provided in the drain main pipe; And a branch pipe provided in a form branched on one side of the secondary side water supply pipe; A sprinkler head provided at one end of the branch pipe for spraying the water for fire externally; A test pipe provided in a branched form at one end of the branch pipe; A test valve provided in the test pipe; And an inert gas supply device selectively connected to one end of the test pipe. By the operation of the inert gas supply device, high-pressure inert gas is supplied to the secondary-side water supply pipe and the branch pipe, Another characteristic is that air in the engine can be exhausted.

The inert gas is supplied to the secondary side supply pipe and the branch pipe through the test pipe by the action of the inert gas supply device in a state in which the drain main valve and the test valve are opened, The inert gas can cause the air in the secondary side water supply pipe and the branch pipe to be exhausted through the drain main valve.

The drain main valve and the test valve are shut off, and the water supply valve is opened to allow water to be added to the secondary water supply pipe and the branch pipe.

The wet sprinkler device capable of preventing corrosion of the metal pipe according to the present invention has the following effects.

In the exhausting of the water existing in the water supply pipe and the branch pipe of the wet sprinkler device, it is possible to completely exhaust the water pipe and the branch pipe by applying the vacuum pump or the method using the pressurized inert gas. Accordingly, it is possible to prevent the formation of the pressurized air layer in the branch pipe during the addition of the digestion water, thereby suppressing the oxygen concentration difference cell phenomenon caused by the difference in the dissolved oxygen concentration in the digestion water.

In addition, since the drain pipe structure connected to the vacuum pump or the inert gas supply device can be selectively applied to the wet sprinkler device, it is possible to easily solve the problem of the installed wet sprinkler device in which the pressurized air layer is formed.

1 is a configuration diagram of a wet sprinkler device according to a first embodiment of the present invention;
FIG. 2A and FIG. 2B are reference views for explaining an evacuation process and an appendage process of the wet type sprinkler device according to the first embodiment of the present invention. FIG.
3 is a configuration diagram of a wet sprinkler device according to a second embodiment of the present invention;
4A and 4B are reference views for explaining an evacuation process and an appendage process of the wet type sprinkler device according to the second embodiment of the present invention.
5 is a configuration diagram of a wet sprinkler device according to a third embodiment of the present invention;
6A and 6B are reference views for explaining an evacuation process and an appendage process of the wet sprinkler device according to the third embodiment of the present invention.
7 is a configuration diagram of a wet sprinkler device according to a modified example of the third embodiment of the present invention.
8A and 8B are reference views for explaining an evacuation process and an appendage process of a wet sprinkler device according to a modified example of the third embodiment of the present invention.
9 is a schematic view of a wet sprinkler facility according to the prior art;
10 is a reference view showing a pressurized air layer formed in a branch of a wet sprinkler facility according to the prior art.
11 is a reference view showing an oxygen concentration difference cell phenomenon generated by a pressurized air layer.
FIG. 12 is a photograph showing a branch tube corroded by the development of an oxygen concentration cell. FIG.

The present invention makes it possible to completely exhaust the water supply pipe and the branch pipe of the wet type sprinkler device, thereby preventing the formation of a pressurized air layer during the filling process, thereby allowing the dissolved oxygen concentration of the fire fighting water to be low and uniform in the fire fighting water Oxygen Concentration The technology that can suppress the corrosion of the supply pipe and the branch pipe due to the development of the secondary battery is presented.

The present invention relates to a method for evacuating a water supply pipe and a branch pipe by evacuating a water supply pipe and a branch pipe to exhaust air from a water pipe and a branch pipe and a method of purging a water pipe and a branch pipe with a high pressure inert gas, An embodiment of a method for evacuating air in a room is proposed.

Hereinafter, a wet sprinkler device capable of preventing corrosion of a metal pipe according to an embodiment of the present invention will be described in detail with reference to the drawings. In the first and second embodiments of the present invention, the secondary side water supply pipe and the branch pipe are evacuated, and the third embodiment is a method of injecting and discharging high pressure inert gas.

Referring to FIG. 1, a wet type sprinkler device capable of preventing corrosion of a metal pipe according to the first embodiment of the present invention includes a water supply device 110 and a water supply pipe 120. The water supply device 110 stores digestion water and supplies digestion water to the water supply pipe 120 and the water supply pipe 120 transfers the digestion water to the sprinkler head 160.

A check valve 130 is provided at one point of the water supply pipe 120 and a water supply pipe 120 at a front end of the check valve 130, that is, a water supply device 110 and a check valve 130 And the water supply pipe 120 at the rear end of the check valve 130 is referred to as a secondary water supply pipe 122. The water supply pipe 120, The check valve 130 is selectively opened only in the direction of the secondary side water supply pipe 122 and the opening and closing of the check valve 130 is interlocked with the pressure difference between the primary side water supply pipe 121 and the secondary side water supply pipe 122 . That is, the first pressure gauge 141 and the second pressure gauge 142 are provided in the primary side water supply pipe 121 and the secondary side water supply pipe 122, respectively, and the pressure difference between the first pressure gauge 141 and the second pressure gauge 142 And the check valve 130 is opened when the reference value is exceeded. One side of the primary side water supply pipe 121 is provided with a water supply valve 123 for selectively opening and closing the supply of water for fire extinguishing water from the water supply device 110 to the water supply pipe 120.

A branch pipe 150 branched from the secondary pipe 122 is provided at one end of the secondary pipe 122 and a sprinkler head 160 is installed at one side of the branch pipe 150 to discharge the pipe water . The branch pipe 150 may be composed of a combination of the main pipe 151 and the auxiliary pipe 152, if necessary. Further, the secondary side water supply pipe 122 may be extended and connected to the test pipe 180. The test pipe 180 is used for checking whether the wet sprinkler device is operating normally, and is connected to the water pipe 190. A test valve 181 and a test pressure gauge 182 are provided on one side of the test pipe 180.

On the other hand, a drain main pipe 170 is provided at one side of the secondary side water supply pipe 122. The drain main pipe 170 is branched from the secondary supply pipe 122 in the same manner as the branch pipe 150. The drain main pipe 170 is basically configured to adjust the water pressure in the secondary pipe 122 And drains water for fire extinguishing water in the secondary water supply pipe 122 or discharges water for fire extinguishing water in the secondary water supply pipe 122 for cleaning the check valve 130. The drain main pipe 170 is extended and connected to the drain pipe 190. A drain main valve 171 is provided at one side of the drain main pipe 170 adjacent to the secondary side water pipe 122, A drain auxiliary valve 13 is provided at one side of the adjacent drain main pipe 170.

In the present invention, the drain main pipe 170 serves as a component for exhausting the secondary water supply pipe 122 and the branch pipe 150, in addition to the above-described water pressure adjustment and cleaning of the check valve 130. A vacuum pipe 12 is provided at one side of the drain main pipe 170 for exhausting the secondary side water supply pipe 122 and the branch pipe 150. A vacuum pipe 12 is provided at one side of the vacuum pipe 12, A pump 20 is provided. A point of the drain main pipe 170 to which the vacuum pipe 12 is connected is located between the drain main valve 171 and the drain auxiliary valve 13 and is connected to the drain main valve 171 and the drain auxiliary valve 13, A pressure gauge 15 for measuring the degree of vacuum may be provided at one side of the drain main pipe 170 between the main pipe 170 and the drain main pipe 170.

When the vacuum pump 20 is operated while the drain main valve 171 is opened and the drain auxiliary valve 13 is shut off, the air in the secondary side water supply pipe 122 and the branch pipe 150 is discharged to the vacuum pump (20). In the state where the air in the secondary side water supply pipe 122 and the branch pipe 150 are exhausted as described above, the pressurized air layer formation can be prevented by advancing the water supply of the fire water for the secondary side water supply pipe 122 and the branch pipe 150. The exhausting and filling process of the secondary-side water supply pipe 122 and the branch pipe 150 will be described later in detail.

The piping structure including the drain main pipe 170, the vacuum pipe 12, the drain auxiliary valve 13, and the like (hereinafter referred to as a drain pipe structure (hereinafter, referred to as " 10) may be manufactured as a single product and applied to the drain main pipe 170.

Particularly, a portion of the drain main pipe 170 may be replaced with a drain pipe structure 10. 1, the drain piping structure 10 includes a drain connection pipe 11. One end of the drain connection pipe 11 is connected to a drain main pipe 170 on the side of the drain main valve 171 And the other end is connected to the drain main pipe 170 on the side of the drain pipe 190. A vacuum piping 12 is branched at one point of the drain connection pipe 11. The vacuum piping 12 is connected to the vacuum pump 20 and the vacuum piping 12 is connected to a vacuum valve 14 are provided. A pressure gauge 15 and a drain auxiliary valve 13 are provided at one side of the drain connection pipe 11 and a point where the drain auxiliary valve 13 is provided is located at a position behind the point where the vacuum pipe 12 is provided do. In the above configuration, the connection between the drain connection pipe 11 and the drain main pipe 170, and the connection between the vacuum pipe 12 and the vacuum pump 20 can be designed in the form of a flange connection.

In the case of the drain piping structure 10 of the single product type as described above, a part of the drain main piping 170 provided is cut, and the drain piping structure 10 described above is replaced with the cut drain main piping 170 , Which can easily solve the problem of formation of the pressurized air layer of the installed wet sprinkler device.

In the wet sprinkler device according to the first embodiment as described above, an alternative embodiment in which the vacuum pump 20 is directly connected to the drain main pipe 170 without passing through the drain pipe structure 10 is also possible. In this case, the evacuation process proceeds with the drain main valve 171 open, and the drain main valve 171 is shut off. The operation of all the valves other than the drain main valve 171 is the same as the exhaust process and the filling process of the first embodiment.

In addition to the above-described method of connecting the vacuum pump 20 to the drain main pipe 170 or the drain pipe structure 10, the vacuum pump 20 may be replaced with the vacuum pump 20 according to another modified embodiment of the wet spring device according to the first embodiment. May be directly connected to the test pipe 180 at the lower end of the test valve 181. In this case, the evacuation process is performed while the drain main valve 171 is shut off, the test valve 181 is opened, and the inserting process is performed while shutting off the drain main valve 171 and the test valve 181 . Operations of all the valves other than the drain main valve 171 and the test valve 181 are the same as those of the exhaust process and the filling process of the first embodiment.

The construction of the wet type sprinkler device according to the first embodiment of the present invention has been described above. Hereinafter, the process of exhausting and filling the wet sprinkler device according to the first embodiment of the present invention will be described.

First, the exhaust process will be described as follows. The water supply valve 123 and the drain auxiliary valve 13 are shut off and the vacuum main valve 171 and the vacuum valve 14 are opened to operate the vacuum pump 20. The air inside the secondary connection pipe 122 and the branch pipe 150 as well as the drain connection pipe 11 and the drain main pipe 170 is exhausted to the vacuum pump 20 by the operation of the vacuum pump 20 Reference). At this time, the air in the check valve 130 connected to the secondary side water supply pipe 122 is also exhausted, and the vacuum valve 14 can adjust the opening speed by adjusting the opening degree as necessary. The vacuum pressure of the secondary side water supply pipe 122 and the branch pipe 150 is measured by a pressure gauge 15 provided at one side of the drain connection pipe 11. When the vacuum pump 20 reaches the set vacuum pressure, .

When the evacuation process is completed, the appendage process proceeds. The drain main valve 171 and the vacuum valve 14 are shut off and the water supply valve 123 is opened to fill the secondary water supply pipe 122 and the branch pipe 150 with fire water. As described above, the check valve 130 is opened when a pressure difference between the primary side water supply pipe 121 and the secondary side water supply pipe 122 is generated. When the water supply of the secondary water supply pipe 122 is completed, the primary side water supply pipe 121 and the secondary side water supply pipe 122 become equal and the check valve 130 is shut off. The pressures in the primary side water supply pipe 121 and the secondary side water supply pipe 122 are measured by the first pressure gauge 141 and the second pressure gauge 142, respectively. The drain auxiliary valve (13) can be opened before proceeding with the addition process. In addition, when the vent valve 124 and the test valve 181 are provided, the vent valve 124 and the test valve 181 are both shut off during the evacuation process and the filling process.

The wet sprinkler device capable of preventing corrosion of the metal pipe according to the first embodiment of the present invention, and the exhaust process and the filling process have been described above. Next, a wet sprinkler device capable of preventing corrosion of a metal pipe according to a second embodiment of the present invention will be described.

The wet sprinkler device according to the second embodiment of the present invention is characterized in that one end of the test pipe 180 is connected to the drain connecting pipe 11 of the drain pipe structure 10 under the basis of the first embodiment. The second embodiment is characterized in that it is possible to exhaust the test pipe 180 as well as the secondary side water supply pipe 122 and the branch pipe 150.

3, the wet type sprinkler device according to the second embodiment of the present invention includes the same water supply device 110, the water supply pipe 120 (the primary water supply pipe 121 and the secondary water supply pipe 122) A drain main pipe 170, and a drain pipe structure 10, as shown in FIG. Also, as in the first embodiment, the test pipe 180 is provided at one end of the secondary side water supply pipe 122.

The other end of the test pipe 180 is connected to the drain connection pipe 11 of the drain pipe structure 10 without being connected to the drain pipe 190. In the second embodiment, That is, in the second embodiment, the secondary side water supply pipe 122, the test pipe 180, the drain connection pipe 11, and the drain main pipe 170 form a closed circuit. The test pipe 180 is connected to the drain connection pipe 11 so that it is possible to exhaust the test pipe 180 in addition to the secondary supply pipe 122 and the branch pipe 150 during the exhaust process.

The exhaust process and the filling process of the second embodiment will be described as follows. First, in the evacuation process, the water supply valve 123 and the drain auxiliary valve 13 are shut off and the drain main valve 171, the test valve 181 and the vacuum valve 14 are opened in the vacuum pump 20, Lt; / RTI > The air in the secondary side water supply pipe 122, the test pipe 180, the drain connection pipe 11 and the drain main pipe 170 constituting a closed circuit is exhausted to the vacuum pump 20 by the operation of the vacuum pump 20 4A). As the exhaust progresses in both directions of the drain main pipe 170 and the test pipe 180, the exhaust efficiency and the speed can be improved.

At this time, as in the first embodiment, air in the check valve 130 connected to the secondary side water supply pipe 122 is also exhausted, and the vacuum valve 14 can regulate the opening speed by adjusting the degree of opening as required. The vacuum pressure of the secondary side water supply pipe 122 and the branch pipe 150 is measured by a pressure gauge 15 provided at one side of the drain connection pipe 11. When the vacuum pump 20 reaches the set vacuum pressure, .

After the evacuation process, the appendage process proceeds as follows. The drain main valve 171 and the test valve 181 and the vacuum valve 14 are shut off and the water supply valve 123 is opened to fill the secondary water supply pipe 122 and the branch pipe 150 with fire water 4b). As in the first embodiment, the check valve 130 is opened when a pressure difference between the primary side water supply pipe 121 and the secondary side water supply pipe 122 is generated. When the water supply of the secondary water supply pipe 122 is completed, The pressure in the secondary side water supply pipe 121 and the pressure in the secondary side water supply pipe 122 become equal and the check valve 130 is shut off. When the vent valve 124 is provided at one side of the secondary supply pipe 122 or the test pipe 180, the vent valve 124 is kept shut off during the evacuation process and the filling process.

In the wet sprinkler device according to the second embodiment as described above, the vacuum pump 20 is directly connected to each of the drain main pipe 170 and the test pipe 180 without passing through the drain pipe structure 10 Examples are possible. In this case, the evacuation process proceeds while the drain main valve 171 and the test valve 181 are opened, and the process of adding is proceeded with the drain main valve 171 and the test valve 181 being shut off. The operation of all the valves other than the drain main valve 171 and the test valve 181 is the same as that of the second embodiment.

Next, a wet sprinkler device capable of preventing corrosion of a metal pipe according to a third embodiment of the present invention will be described.

The wet sprinkler device according to the third embodiment of the present invention is characterized in that the vacuum pump 20 is replaced with an inert gas supply device 20a in the configuration of the first embodiment or the second embodiment. In the first and second embodiments, the air in the secondary side water supply pipe 122 and the branch pipe 150 is exhausted to the vacuum pump 20 by using the vacuum pump 20, Injects high-pressure inert gas into the secondary-side water supply pipe 122 and the branch pipe 150 to exhaust the air in the secondary pipe 122 and the branch pipe 150 through the vent valve 124.

The construction of the wet type sprinkler device according to the third embodiment is the same as that of the first embodiment or the second embodiment as shown in Figs. 5 and 7, and the vacuum pump 20 of the first embodiment or the second embodiment, Is replaced with an inert gas supply device 20a. In addition, the vacuum pipe 12 and the vacuum valve 14 of the first embodiment or the second embodiment are replaced by an inert gas supply pipe 12a and an inert gas supply valve 14a, respectively. In addition, in the case of the third embodiment, a vent valve 124 is necessarily provided at one side of the secondary side water supply pipe 122 or the branch pipe 150.

The exhaust process and the filling process of the third embodiment are as follows.

The vent valve 124 and the drain main valve 171 and the inert gas supply valve 14a are inactivated in the open state And operates the gas supply device 20a. At this time, when the wet sprinkler device is in the form of the second embodiment, the inert gas supply device 20a is operated while the test valve 181 is also opened with the drain main valve 171 and the vacuum valve 14 opened .

Pressure inert gas is supplied to the secondary side supply pipe and the branch pipe 150 via the drain connection pipe 11 and the drain main pipe 170 by the operation of the inert gas supply device 20a, Air in the drain connection pipe 11, the drain main pipe 170, the secondary supply pipe, and the branch pipe 150 is exhausted through the vent valve 124 (see FIGS. 6A and 8A). Further, when the wet sprinkler apparatus is in the form of the second embodiment, the high-pressure inert gas is also supplied to the test pipe 180.

When the evacuation process is completed, the appendage process proceeds. The vent valve 124 and the drain main valve 171 and the inert gas supply valve 14a are shut off and the water supply valve 123 is opened to enter the secondary water supply pipe 122 and the branch pipe 150 with fire water (See Figs. 6B and 8B). If the wet sprinkler device is in the form of the second embodiment, the test valve 181 is in the shut off state and the appendage process proceeds.

In the filling process according to the third embodiment, a high-pressure gas layer may be formed in the branch pipe 150 after completion of the filling process as in the conventional wet sprinkler device. However, since the high-pressure gas layer is an inert gas, Even if a high pressure gas layer is formed due to the inert gas remaining in the branch pipe 150, the concentration of dissolved oxygen in the digesting water in the branch pipe 150 is not affected, and the cell generation phenomenon due to the difference in dissolved oxygen concentration does not occur.

In the wet sprinkler device according to the third embodiment as described above, the inert gas supply device 20a may be directly connected to the drain main pipe 170 without passing through the drain pipe structure 10, or may be connected to the test pipe 180 Alternative embodiments in which direct connection is possible are also possible. In this case, the evacuation process proceeds with the drain main valve 171 and the test valve 181 open. In the modified embodiment in which the inert gas is supplied to the secondary side supply pipe 122 and the branch pipe 150 through the drain main pipe 170, air is exhausted through the test valve 181, In the modified embodiment in which gas is supplied to the secondary side water supply pipe 122 and the branch pipe 150, air is exhausted through the drain main valve 171. When the vent valve 124 is provided in the two modified embodiments, the vent valve 124 is shut off and the vent is exhausted. The appendage process proceeds with the drain main valve 171 and the test valve 181 blocked. The operation of all the valves other than the drain main valve 171, the test valve 181 and the vent valve 124 is the same as that of the third embodiment.

110: water supply device 120: water supply pipe
121: Primary supply pipe 122: Secondary supply pipe
123: water supply valve 124: vent valve
130: check valve 141: first pressure gauge
142: second pressure gauge 150:
151: main branch 152: auxiliary branch
160: Sprinkler head 170: Drain main piping
171: drain main valve 180: test piping
181: Test valve 182: Test pressure gauge
190: Water pipe
10: drain pipe structure 11: drain connection pipe
12: Vacuum piping 12a: Inert gas supply piping
13: Drain auxiliary valve 14: Vacuum valve
14a: inert gas supply valve 15: pressure gauge
20: Vacuum pump 20a: Inert gas supply device

Claims (13)

A water supply device for supplying fire water;
A water supply pipe which transfers the fire water to the sprinkler head and divided into a primary water supply pipe at the front end and a secondary water supply pipe at the rear end based on the check valve;
A water supply valve provided in the primary side water supply pipe;
A branch pipe provided on one side of the secondary side water supply pipe in a branched form;
A sprinkler head provided at one end of the branch pipe for spraying the water for fire externally;
A drain main pipe branched from one side of the secondary side water supply pipe;
A drain main valve provided in the drain main pipe;
An inert gas supply device provided on one side of the drain main pipe; And
And a drain pipe structure connected to one side of the drain main pipe,
Wherein the drain pipe structure comprises:
A drain connection pipe connected to the drain main pipe,
And an inert gas supply pipe branched at one point of the drain connection pipe,
Wherein the drain connection pipe is provided with a drain auxiliary valve,
The inert gas supply pipe is provided with an inert gas supply valve,
And the inert gas supply device is operated by the operation of the inert gas supply device so that the high pressure inert gas flows through the drain connection pipe and the drain main pipe to the second main pipe And a wet sprinkler device capable of preventing corrosion of the metal pipe, which is supplied to the main water supply pipe and the branch pipe, and the drain connection pipe, the drain main pipe, the secondary pipe, and the branch pipe are exhausted by a high- .
delete delete The wet type sprinkler according to claim 1, wherein a vent valve is provided on one side of the secondary side water supply pipe, and air in the secondary side water supply pipe and the branch pipe is exhausted through the vent valve. Device.
2. The water treatment system according to claim 1, wherein the drain main valve and the inert gas supply valve are shut off, and the water supply valve is opened to allow water to be introduced into the secondary water supply pipe and the branch pipe, Wet sprinkler device.
2. The apparatus according to claim 1, further comprising a test pipe branched at one end of the branch pipe,
One end of the test pipe is connected to a drain connection pipe of the drain pipe structure,
A test valve is provided on one side of the test pipe,
The water supply valve and the drain auxiliary valve are shut off and the drain main valve, the test valve, and the inert gas supply valve are opened, and the inert gas is supplied from the inert gas supply device to the secondary side water supply pipe and the branch pipe And the air is exhausted. The wet sprinkler device according to claim 1,
7. The method as claimed in claim 6, wherein the drain main valve, the test valve, and the inert gas supply valve are shut off, and the water supply valve is opened to allow the secondary water supply pipe and the branch pipe to be filled with fire extinguishing water. A wet sprinkler device that can be used.
delete delete delete A water supply device for supplying fire water;
A water supply pipe which transfers the fire water to the sprinkler head and divided into a primary water supply pipe at the front end and a secondary water supply pipe at the rear end based on the check valve;
A water supply valve provided in the primary side water supply pipe;
A drain main pipe branched from one side of the secondary side water supply pipe;
A drain main valve provided in the drain main pipe; And
A branch pipe provided on one side of the secondary side water supply pipe in a branched form;
A sprinkler head provided at one end of the branch pipe for spraying the water for fire externally;
A test pipe provided in a branched form at one end of the branch pipe;
A test valve provided in the test pipe; And
And an inert gas supply unit selectively connected to one end of the test pipe,
By the operation of the inert gas supply device, it is possible to supply a high-pressure inert gas to the secondary side water supply pipe and the branch pipe to exhaust air in the secondary pipe and the branch pipe,
The high-pressure inert gas is supplied to the secondary-side water supply pipe and the branch pipe through the test pipe by the operation of the inert gas supply device in a state in which the drain main valve and the test valve are open, Characterized in that the secondary side water supply pipe and the air in the branch pipe can be exhausted through the drain main valve by an inert gas, thereby preventing corrosion of the metal piping.
delete 12. The wet type sprinkler according to claim 11, wherein the drain main valve and the test valve are closed, and the water supply valve is opened to allow water to be added to the secondary water supply pipe and the branch pipe. Device.

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