KR100495616B1 - Alien substance cleaning apparatus of cooling device tube inner by using sea water - Google Patents

Abstract

The present invention relates to a debris cleaning device in a cooling device tube using seawater to facilitate the cleaning of various foreign matter accumulated in a cooling device tube using sea water as a cooling medium.

The present invention provides a device for cleaning foreign matter accumulated in a cooling device tube using sea water, comprising: a sand powder storage unit in which sand powder is charged and stored in a storage hopper; A sand powder transfer part for transferring sand in the sand powder storage part while the screw rotates as the motor is driven; A sand powder suction part for sucking sand transferred by the sand powder feed part; An ejector unit connected to the sand powder suction unit; An air supply unit connected to one end of the ejector unit and supplied with air through a flexible hose and a pipe; An air and sand powder supply part connected to the other end of the ejector part and supplied with air and sand to one end of the cooling device tube through an injection housing; Sand that is connected to the other end of the cooling device tube and completes the cleaning operation of the cooling device tube comprises a sand powder recovery unit is stored and discharged in the recovery hopper through the recovery housing.

Description

Alien substance cleaning apparatus of cooling device tube inner by using sea water}

The present invention relates to a debris cleaning device in a cooling device tube, and more particularly, to a foreign material in a cooling device tube using sea water so that various debris accumulated in the cooling device tube using sea water as a cooling medium can be easily cleaned. It relates to a cleaning device.

Generally, as shown in FIG. 1, the cooling device is divided into a tube side 33 and a cell side 32 so that a heating fluid is injected into the cell side 32 when a main fluid flows into the tube side 33. Alternatively, when the main fluid flows to the cell side 32, a cooling fluid is injected into the tube side 33 to increase or decrease the amount of heat of the main fluid.

In addition, in the cooling apparatus using seawater, cooling medium seawater is supplied to the tube side 33 as shown in FIG. 2, and the scale or sludge in the tube 30 is supplied by the seawater being supplied at a low pressure. And the accumulation of foreign matter 34 such as seaweed becomes severe, and various marine life, seaweed, shellfish, etc. contained in seawater are generated and propagated in the tube 30, thereby causing the phenomenon of closing the tube 30. .

Accordingly, the foreign matter cleaning work remaining in the cooling device tube 30 is periodically performed, and the worker cleans the foreign matter using a twisting rod 28 having a cylindrical brush 29 attached to each one of the tubes 30. According to the implementation, if the maintenance time is long, work efficiency is lowered, and the removal of foreign matter in the tube tube 30 is not easy due to the wear of the brush 29, the cooling efficiency of the cooling equipment is reduced and the life of the equipment is shortened. There was a problem.

The present invention was devised to solve the above-mentioned problems of the prior art, and as the cleaning work for a plurality of cooling tube tubes is carried out at a time, the maintenance time is shortened to improve the work efficiency and facility efficiency, and the efficiency of the maintenance work. The purpose of the present invention is to provide a debris cleaning device inside the cooling tube using sea water that can be planned.

An apparatus for cleaning foreign matter accumulated in a cooling device tube using sea water, to achieve the above object, the sand powder storage unit into which the sand powder is put and stored in the storage hopper; A sand powder transfer part for transferring sand in the sand powder storage part while the screw rotates as the motor is driven; A sand powder suction part for sucking sand transferred by the sand powder feed part; An ejector unit connected to the sand powder suction unit; An air supply unit connected to one end of the ejector unit and supplied with air through a flexible hose and a pipe; An air and sand powder supply part connected to the other end of the ejector part and supplied with air and sand to one end of the cooling device tube through an injection housing; Sand connected to the other end of the chiller tube and complete the cleaning work of the chiller tube comprises a sand dust recovery unit which is stored and discharged in the recovery hopper through the recovery housing tube using sea water Internal debris cleaning device is provided.

In the present invention as described above, the sand suction unit includes a suction pipe installed vertically through the storage hopper, a control valve connected to an upper portion of the suction pipe, and a nipple connected to the control valve.

In the present invention, the ejector unit includes an ejector having a plurality of vacuum chambers therein, a venturi tube disposed between the vacuum chambers, and an air compression and expansion chamber formed before and after the venturi tube. do.

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

3 is a block diagram of a foreign material cleaning device inside the cooling device tube using sea water according to the present invention, Figure 4 is an installation state diagram of the present invention, the foreign material cleaning device according to the sand dust storage unit; A sand powder feeder for transporting sand in the sand powder storage part; A sand powder suction part for sucking sand transferred by the sand powder feed part; An ejector unit connected to the sand powder suction unit; An air supply unit through which air is supplied through the flexible hose and the pipe; An air and sand powder supply unit for supplying air and sand to one end of the cooling device tube; The sand having completed the cleaning of the cooling device tube is composed of a sand powder recovery unit is stored and discharged in the recovery hopper through a recovery housing.

The sand dust storage unit is fixed to the storage hopper (1) having a predetermined storage space therein so that a predetermined amount of sand can be stored on the upper portion of the base (2), the upper side of the storage hopper (1) The sand inlet 3 is formed, and one side surface of the storage hopper 1 is provided with a see-through window 4 to visually observe the amount of sand inside.

The sand powder conveying part is provided with a drive motor 5 on one side of the base 2, and the shaft 5-1 of the drive motor 5 penetrates through the storage hopper 1 and is screwed ( 6) is connected to the formed screw shaft 6-1.

The sand dust suction part is attached to the lower end of the suction pipe 8 having a pipe shape at the distal end of the screw shaft 6-1, and the upper end of the suction pipe 8 vertically penetrates the storage hopper 1 vertically. It is installed, and the sand control valve 15 is connected to the upper end of the suction pipe (8).

In addition, a nipple 14 is connected to an upper portion of the sand control valve 15.

The ejector unit has two vacuum chambers 17 formed inside the ejector 16, a venturi tube 13 is installed between the vacuum chambers 17, and the venturi tube 13 is interposed therebetween. Air compression and expansion chambers 11 and 12 are respectively formed before and after.

The air supply part is connected to a high pressure air generating equipment (not shown), and the front end of the flexible hose 9 to which air is supplied is connected to one end of the pipe 19 through the socket 20, and the pipe 19 The other end of) is connected to one side of the ejector 16.

The air and sand powder supply part is connected to the other end of the ejector 16, one end of the pipe 22, the other end of the pipe 22 is connected to the flexible hose 18 through the socket 20 The flexible hose 18 is connected to the injection housing 21 having a conical shape having a predetermined thickness through the socket 20.

In addition, the flange portion 21-1 of the injection housing 21 is connected to one end of the cooling device tube 30, as shown in FIG.

The sand dust recovery part has a flange portion 23-1 of the recovery housing 23 having the same shape as the injection housing 21 is connected to the other end of the tube 30, and the recovery housing 23 is It is connected to one end of the flexible hose 18-1, and the other end of the flexible hose 18-1 is connected to the sand recovery port 25 through the socket (20).

The flange portions 21-1 and 23-1 of the injection housing 21 and the recovery housing 23 are configured to have the same diameter as the tube 30.

In addition, the sand recovery port 25 is embedded in the recovery hopper 26 having a predetermined storage space therein, and the sand outlet 27 having a hinge structure is rotatable in the lower part of the recovery hopper 26. It is installed so as to open and close, and one side of the recovery hopper 26 is provided with a viewing window 4-1 so that the amount of sand inside can be observed.

In the drawings, reference numeral 3-1 denotes a cover, 10 an air valve, 19-1 and 22-1 to a pressure gauge, and 24 to a flange portion.

Hereinafter, the operation of the present invention having the configuration as described above.

When the foreign matter 34 such as various scales, sludges and seaweeds is accumulated in the tube 30 and is to be cleaned, the plan of the spray housing 21 and the recovery housing 23 as shown in FIGS. 3 and 4. After connecting branches 21-1 and 23-1 to both ends of the cooling device tube 30, respectively, a predetermined amount of sand powder is introduced into the storage hopper 1 through the sand inlet 3, and then the cover ( As the shaft 5-1 and the screw shaft 6-1 rotate as the 3-1) is closed and the drive motor 5 is operated, sand powder is caused by the screw 6 toward the lower portion of the suction pipe 8. Transferred.

Subsequently, when the air valve 10 is opened and air is supplied into the ejector 16 through the flexible hose 9 and the pipe 19, the air opens the air compression chamber 11 and the venturi tube 13. While passing through the air at high speed, the air is expelled into the expansion chamber 12. At this time, a vacuum is formed in the vacuum chamber 17 to generate a suction pressure.

At this time, when the sand control valve 15 is opened, sand powder is introduced into the ejector 16 through the nipple 14 by the suction pressure of the ejector 16, and the sand powder is mixed with air to form the pipe 22. Foreign matter on the inner wall of the tube 30 while colliding with various foreign matter 34 accumulated in the tube 30 while passing through the plurality of tubes 30 through the flexible hose 18 and the spray housing 21. (34) is separated, and the foreign matter (34) thus separated is passed through the tube (30) by the high-speed air to the recovery housing (23), flexible hose (18-1) and sand recovery port ( 25 is dropped into the recovery hopper 26 and stored.

As described above, when the removal of the foreign matter 34 in the tube 30 is completed, the operation of the driving motor 5 is stopped, and when the sand control valve 15 is closed, sand powder is no longer supplied and only pure air is supplied. When the inside of the tube 30 through the ejector 16 is supplied to discharge the sand remaining in the tube 30 to the recovery hopper 26, when the removal of the foreign matter 34 in the tube 30 is completed The flanges 21-1 and 23-1 of the injection housing 21 and the recovery housing 23 are separated from the tube 30, and sand and foreign matter 34 in the recovery hopper 26 are separated from the sand outlet. Through the outside.

As described above, according to the present invention, since the cleaning of foreign matter in the plurality of cooling device tubes is easily performed at a time, the maintenance time is shortened, the working efficiency and the cooling efficiency of the equipment are improved, and the life of the cooling equipment is extended. It is effective.

1 is a schematic view showing a chiller tube using sea water.

Figure 2 is a schematic diagram showing the removal of foreign matter in the conventional chiller tube.

Figure 3 is a block diagram of a foreign material cleaning device inside the cooling device tube using sea water according to the present invention.

Figure 4 is an installation of the present invention.

<Explanation of symbols for main parts of drawing>

1: Storage Hopper 2: Base

3: sand inlet 4,4-1: see-through window

6: screw 8: suction tube

10 air valve 13 venturi tube

14: nipple 15: sand control valve

16: ejector 17: vacuum chamber

21: injection housing 23: recovery housing

26: recovery hopper 30: tube

Claims (3)

In the device for cleaning the accumulated foreign matter inside the cooling tube using sea water, A sand powder storage unit in which sand powder is injected into and stored in the storage hopper; A sand powder transfer part for transferring sand in the sand powder storage part while the screw rotates as the motor is driven; A sand powder suction part for sucking sand transferred by the sand powder feed part; An ejector unit connected to the sand powder suction unit; An air supply unit connected to one end of the ejector unit and supplied with air through a flexible hose and a pipe; An air and sand powder supply part connected to the other end of the ejector part and supplied with air and sand to one end of the cooling device tube through an injection housing; When the cleaning of the chiller tube by sand is completed by being connected to the other end of the chiller tube, the suction of the sand powder by the sand dust suction unit is stopped and the air is continuously supplied by the air supply unit, thereby remaining the sand in the tube. Sand dust recovery unit is stored and discharged in the recovery hopper through the recovery housing; Debris cleaning device inside the cooling device tube using sea water, characterized in that comprises a. The method of claim 1, wherein the sand dust suction portion is installed through the storage hopper vertically, the suction pipe through which sand powder is suction flow, and a control valve connected to the upper portion of the suction pipe to control the supply and blocking of sand, The foreign material cleaning device inside the cooling device tube using sea water, characterized in that it comprises a nipple connected to the control valve. The method of claim 1, wherein the ejector unit comprises an ejector having a plurality of vacuum chambers therein, a venturi tube disposed between the vacuum chambers, and an air compression and expansion chamber formed before and after the venturi tube. Decontamination device inside the cooling tube using sea water.