KR101557135B1 - Apparatus for operating cleaning balls - Google Patents

Abstract

Provided is a device for operating cleaning balls for eliminating internal scale from the inside of a heat exchanger. The device for operating cleaning balls comprises: i) a three-way valve for discharging cleaning balls to a discharging line, wherein the three-way valve is connected to a discharging line; ii) a cleaning ball collecting container for collecting cleaning balls inputted through a collection line, wherein the cleaning ball collecting container is connected to the collection line; iii) a first pipe for connecting the three-way valve with the cleaning ball collecting container; and iv) a second pipe for connecting the three-way valve with the cleaning ball collecting container in addition to the first pipe. A cleaning ball collecting net blocks a connection unit between the second pipe and the cleaning ball collecting container.

Description

{APPARATUS FOR OPERATING CLEANING BALLS}

The present invention relates to a cleaning ball operating apparatus. More particularly, the present invention relates to an apparatus for operating a cleaning ball for removing scale within a heat exchanger.

The heat exchanger is a device for maximizing the thermal efficiency by heating the low temperature fluid while cooling the high temperature fluid through heat exchange between the high temperature fluid and the low temperature fluid, and is used in most industrial facilities. The heat transfer efficiency of the heat exchanger is deteriorated because the heat transfer pipe or the heat transfer plate of the heat exchanger is contaminated with time. Therefore, the operation of the apparatus is stopped in order to remove the contamination, and the heat exchanger is disassembled to remove pollutants by hand-brushing with a brush or high-pressure water or immersing them in a chemical agent.

However, such a decontamination method is disadvantageous in that, when the decontamination is stopped, the operation of the apparatus must be stopped and the heat exchanger is disassembled to remove the contamination of the heat transfer plate and reassemble. Therefore, a device for removing contamination by passing the cleaning ball through a tube in a heat exchanger is widely used.

And to provide a cleaning ball operating apparatus capable of efficiently using a cleaning ball for efficiently removing scales and the like inside the heat exchanger.

A cleaning ball operating apparatus according to an embodiment of the present invention includes: i) a three-way valve connected to a discharge line for discharging cleaning balls to a discharge line, ii) a collection valve connected to the collection line to collect cleaning balls flowing through the collection line Iii) a first pipe connecting the three-way valve and the cleaning ball collector, and iv) a second pipe connecting the three-way valve and the cleaning ball collector separately from the first pipe. A cleaning ball collecting net blocking the connection between the second pipe and the cleaning ball collecting box is installed.

The length of the second pipe may be greater than the length of the first pipe, and the second pipe may include the bending portion. The diameter of the second pipe may be more than the diameter of the first pipe. The ratio of the diameter of the second pipe to the diameter of the first pipe may be from 1.000 to 1.875.

The apparatus for operating a cleaning ball according to an embodiment of the present invention may further include a pump installed in the collection line to apply the cleaning balls to the cleaning ball collection case. When the cleaning balls are discharged from the cleaning ball collecting cylinder to the discharge line side through the first pipe, the three-way valve can block the communication with the second pipe. When the cleaning balls are collected from the collection line into the cleaning ball collection cylinder, the three-way valve can cut off communication with the first pipe.

When the cleaning balls are removed from the cleaning ball collection cylinder, the three-way valve may block communication with the discharge line. The cleaning ball collecting cylinder includes a cleaning ball collecting body installed in the inside thereof and rotated, and when the cleaning balls collect from the collecting line into the cleaning ball collecting cylinder, the cleaning ball collecting body is driven so as to block the cleaning ball collecting cylinder . The cleaning ball collector includes i) a cleaning ball collecting portion, ii) a cover provided on the cleaning ball collecting portion and adapted to open and close the cleaning ball collecting portion, and having a transparent window, and iii) a cover And may include a plurality of fixing portions. The plurality of fixing portions may include: i) a body portion extended in one direction, ii) a first end connected to the body portion and hinged to the side of the cleaning ball collecting portion, and iii) a bolt is provided to fix the cover on the cleaning ball collecting portion The second end portion of the second end portion.

The cleaning ball operating apparatus according to another embodiment of the present invention includes: i) a recovery line provided with a first gate valve; ii) a cleaning ball collecting tube connected to the collection line to collect cleaning balls flowing through the collection line; iii) A first pipe connected to a ball collecting passage and provided with a second gate valve and connected to a discharge line, and iv) a second pipe connected to the cleaning ball collecting barrel separately from the first pipe, And piping. A cleaning ball collecting net blocking the connection between the second pipe and the cleaning ball collecting box is installed.

When the cleaning balls are collected from the collection line into the cleaning ball collector, the second gate valve can be closed. When the cleaning balls are removed from the cleaning ball collection cylinder, the first gate valve can be closed.

By using a three-way valve, circulation, collection and replacement of cleaning balls can be efficiently performed. Therefore, since the scale inside the heat exchanger can be efficiently removed by using the cleaning ball, the service life of the heat exchanger can be greatly extended.

1 is a schematic perspective view of a cleaning ball operating apparatus according to a first embodiment of the present invention.
2 is a schematic front view of the cleaning ball operating apparatus of FIG.
3 is a schematic use state diagram of the cleaning ball operating apparatus of FIG.
FIGS. 4 to 6 are views schematically showing the use states of the cleaning ball operating apparatus of FIG. 1 according to the liver stages.
7 is a schematic front view of a cleaning ball operating apparatus according to a second embodiment of the present invention.
8 is a schematic front view of a cleaning ball operating apparatus according to a third embodiment of the present invention.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the invention. The singular forms as used herein include plural forms as long as the phrases do not expressly express the opposite meaning thereto. Means that a particular feature, region, integer, step, operation, element and / or component is specified, and that other specific features, regions, integers, steps, operations, elements, components, and / And the like.

Terms representing relative space, such as "below "," above ", and the like, may be used to more easily describe the relationship to another portion of a portion shown in the figures. These terms are intended to include other meanings or acts of the apparatus in use, as well as intended meanings in the drawings.

For example, when inverting a device in the figures, certain portions that are described as being "below" other portions are described as being "above " other portions. Thus, an exemplary term "below" includes both up and down directions. The device can be rotated by 90 degrees or rotated at different angles, and terms indicating relative space are interpreted accordingly.

Unless otherwise defined, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Commonly used predefined terms are further interpreted as having a meaning consistent with the relevant technical literature and the present disclosure, and are not to be construed as ideal or very formal meanings unless defined otherwise.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

1 schematically shows a cleaning ball operating apparatus 100 according to a first embodiment of the present invention. The structure of the cleaning ball driving apparatus 100 of FIG. 1 is merely for illustrating the present invention, and the present invention is not limited thereto. Therefore, the structure of the cleaning ball driving apparatus 100 can be modified in other forms.

1, the cleaning ball operating apparatus 100 includes a three-way valve 10, a cleaning ball collecting cylinder 20, a first pipe 30, and a second pipe 50. As shown in FIG. In addition, the cleaning ball operating apparatus 100 may further include a pump 40 as occasion demands.

The three-way valve 10 is connected to the first pipe 30, the second pipe 50 and the discharge line 92. The three-way valve 10 is connected to the cleaning ball collecting cylinder 20 through the first pipe 30 and the second pipe 50. Thus, the three-way valve 10 opens or closes the first pipe 30 and the second pipe 50 to adjust the flow directions of the cleaning balls. When the three-way valve 10 is in communication with the first line 30 and the discharge line 92, the cleaning balls can be discharged to the discharge line 92. The three-way valve 10 may be pneumatically or electromagnetically actuated and may be used to interconnect two or more of the three directions to allow fluid flow, or fluid flow in any direction, Can be blocked. The detailed internal structure of the three-way valve 10 will be easily understood by those skilled in the art, and thus a detailed description thereof will be omitted.

The cleaning ball collecting bin 20 is connected to the collecting line 90 to collect the cleaning balls flowing through the collecting line 90. Therefore, the cleaning ball collecting bin 20 is designed such that its length in the height direction, i.e., the z-axis direction, is greater than the length in the width direction, i.e., the length in the xy plane direction. As a result, a large amount of cleaning balls can be accommodated in the cleaning ball collecting container 20. Accordingly, a large amount of cleaning balls can be collected or replaced by using the cleaning ball collecting container 20. On the other hand, the pump 40 is installed in the recovery line 90 to introduce the cleaning balls into the cleaning ball collecting cylinder 20. That is, the pump 40 sucks the cooling water from the recovery line 90 to introduce the cleaning balls contained in the cooling water into the cleaning ball collecting cylinder 20 along the recovery line 90.

The first pipe 30 connects the three-way valve 10 and the cleaning ball collecting cylinder 20. When the three-way valve 10 is opened and the first pipe 30 is connected to the discharge line 92, the cleaning balls collected in the cleaning ball collecting tank 20 are discharged to the outside through the discharge line 92 .

The second pipe 50 connects the three-way valve 10 and the cleaning ball collecting container 20 separately from the first pipe 30. That is, since the second pipe 50 functions as a bypass pipe, its length is larger than the length of the first pipe 30. The cleaning ball can be collected in the cleaning ball collecting cylinder 20 by using the second pipe 50. The second pipe 50 includes a pair of bending portions 501, 503.

Fig. 2 schematically shows the frontal state of the cleaning ball operating apparatus 100 of Fig. Fig. 2 shows a state in which the cleaning ball operating device 100 of Fig. 1 is viewed in the y-axis direction, and the second piping 50 is disassembled for the sake of explanation.

2, the cleaning ball collection net 60 is installed at a connection portion between the second pipe 50 (shown in FIG. 1 and the following) and the cleaning ball collecting box 20. Here, the connection means the position between the second pipe 50 and the cleaning ball collecting cylinder 20, and may be interpreted as being located in the second pipe 50 and the cleaning ball collecting cylinder 20.

The cleaning balls can be collected in the cleaning ball collecting cylinder 20 by the cleaning ball collecting net 60 when the second piping 50 and the discharge line 92 are communicated with each other using the three way valve 10 . That is, the cleaning balls are introduced into the cleaning ball collection cylinder 20 from the collection line 90 according to the operation of the pump 40 (shown in FIG. 1, the same applies hereinafter) and blocked by the cleaning ball collection net 60 They can not flow into the second pipe 50 and are collected in the cleaning ball collecting container 20. Therefore, the cleaning balls can be efficiently recovered from the collection line 90 in the cleaning-ball collecting cylinder 20.

2, the cleaning ball collecting container 20 includes a cleaning ball collecting portion 201, a cover 203, and a fixing portion 205. As shown in Fig. In addition, if necessary, the cleaning bowl 20 may further include other components.

The cover 203 is installed on the cleaning ball collecting unit 201. The cover 203 opens and closes the cleaning ball collecting unit 201. Therefore, the cover 203 can be opened and the cleaning balls can be taken out from the cleaning ball collecting unit 201. That is, when it is necessary to take out the cleaning balls and confirm or replace them, the cover 203 is opened and used. Since the cover 203 is provided with a transparent window, the inside of the cleaning ball collecting unit 201 can always be visually confirmed. Therefore, the operating state of the cleaning ball collecting container 20 can be detected. The hinge portion 209 connects the cover 203 and the cleaning ball collecting portion 201 so that the cover 203 is rotated from the cleaning ball collecting portion 201 and fixed.

The plurality of fixing portions 205 includes a body portion 2051, a first end portion 2053, and a second end portion 2055. The body portion 2051 is elongated in one direction. The first end portion 2053 is connected to the body portion 2051 and is hinged to the side surface of the cleaning ball collecting portion 201. The second end portion 2055 can be disposed on the cover 203 by rotating the body portion 2051 about the first end portion 2053. Since the second end portion 2055 is provided with a bolt, the cover 203 can be fixed on the cleaning ball collecting portion 201 by rotating the bolt. The cover 203 is tightly fixed on the cleaning ball collecting unit 201 so that the cooling water and the cleaning balls flowing from the collection line 90 during operation of the cleaning ball operating apparatus 100 leak from the cleaning ball collecting cylinder 20 . At the same time, the inner state of the cleaning ball collecting cylinder 20 can be observed through the cover 203.

Fig. 3 schematically shows the use state of the cleaning ball operating apparatus 100 of Fig. The use state of the cleaning ball operating apparatus 100 of FIG. 3 is merely for illustrating the present invention, and the present invention is not limited thereto. Therefore, the use state of the cleaning ball driving apparatus 100 may be changed to another form.

As shown in Fig. 3, the cooling water flows from the cooling water inflow line 97 to the cooling water discharge line 98. Therefore, the hot fluid flowing along the inside of the heat exchanger 95 can be used again after being cooled by the cooling water. For example, the heat exchanger 95 may be a condenser for use in a power plant.

In this case, the cleaning ball driving apparatus 100 is connected to the cooling water inflow line 97 and the cooling water discharge line 98 located at both ends of the heat exchanger 95, respectively. More specifically, the recovery line 90 of the cleaning ball operating apparatus 100 is connected to a cooling water discharge line 98, and the discharge line 92 of the cleaning ball operation apparatus 100 is connected to the cooling water inflow line 97 do. Accordingly, the cleaning balls B discharged through the discharge line 92 flow into the heat exchanger 95, and the scale can be removed by the frictional force by colliding with a scale or the like attached to the outer wall of the tube through which the cooling water passes. The cleaning balls B having passed through the heat exchanger 95 are again collected by the cleaning ball collection net 99 and collected into the cleaning ball operating device 100 through the collection line 90. The cleaning ball driving apparatus 100 can be used in this manner.

FIGS. 4 to 6 schematically show the use states of the cleaning ball operating apparatus 100 of FIG. 1, respectively. More specifically, FIG. 4 shows the circulation state of the cleaning balls, FIG. 5 shows the collection state of the cleaning balls, and FIG. 6 shows the replacement state of the cleaning balls. 4 to 6 are merely illustrative of the present invention, and the present invention is not limited thereto. Therefore, the use state of each step of the cleaning ball driving apparatus 100 can be modified in other forms. Hereinafter, the use states of the cleaning ball operating apparatus 100 will be described with reference to FIGS.

First, FIG. 4 shows a state in which the cleaning balls B are circulated by using the cleaning ball operating device 100. 1), the cleaning balls B pass from the collection line 90 along the direction of the arrow through the cleaning ball collection cylinder 20 to the discharge line (not shown) 92, respectively. That is, the cleaning balls flow from the cleaning ball collecting cylinder 20 through the first pipe 30 to the discharge line 92 side. Accordingly, while the cleaning balls B are continuously circulated, contaminants inside the tubes such as heat exchangers located outside the cleaning ball driving apparatus 100 can be removed. In this case, the three-way valve 10 interrupts the communication with the second pipe 50, so that the cleaning balls B can continuously flow from the collection line 90 to the discharge line 92.

On the other hand, FIG. 5 shows a state in which the cleaning balls B are collected using the cleaning ball operating device 100. That is, when the cleaning balls B are collected from the collection line 90 into the cleaning ball collection cylinder 20, the three-way valve 10 blocks the communication with the first piping 30. [ As a result, the cooling water flows from the recovery line 90 to the discharge line 92 through the cleaning ball collecting cylinder 20 and the second pipe 50 along the arrow direction. In this case, the cleaning balls B are not allowed to flow into the second pipe 50 due to the cleaning ball collection net 60, and are collected in the cleaning ball collecting container 20. Therefore, the cleaning balls B can be collected in the cleaning ball collecting container 20. That is, the cleaning ball operating apparatus 100 may not always be operated simultaneously during operation of the external heat exchanger, but may be operated only once a day for cleaning in some cases. Therefore, when it is desired to stop the operation of the cleaning ball driving apparatus 100, the cleaning balls B collected in the heat exchanger are all collected in the cleaning ball collecting cylinder 20, and then the operation of the cleaning ball driving apparatus 100 is stopped .

5, the movement of the cleaning balls B is blocked by the cleaning ball collection net 60, the cleaning balls B are positioned in front of the cleaning ball collection net 60, May not be easily discharged to the second pipe (50) through the collection net (60). In this case, there is a possibility that the cooling water contained in the cleaning ball collecting cylinder 20 will overflow. Accordingly, the diameter D50 of the second pipe 50 is adjusted so that the cooling water can be discharged through the second pipe 50 well. In this case, the diameter D50 of the second pipe 50 can be made to be equal to or larger than the diameter D30 of the first pipe 30. For example, the ratio of the diameter D50 of the second pipe 50 to the diameter D30 of the first pipe 30 may be 1.000 to 1.875. More preferably, the ratio of the diameter D50 of the second pipe 50 to the diameter D30 of the first pipe 30 may be 1.000 to 1.250.

Fig. 6 shows a state in which the cleaning balls B are removed using the cleaning ball operating apparatus 100. Fig. That is, when all the cleaning balls B are collected by the cleaning ball collecting cylinder 20 and the cleaning balls B are to be removed from the cleaning ball collecting cylinder 20, the three-way valve 10 is connected to the discharge line 92 ). Then, the operation of the pump 40 is stopped. Therefore, the cooling water introduced from the recovery line 90 can not be discharged to the discharge line 92, and the flow thereof is cut off. As shown in FIGS. 4 to 6, the cleaning ball driving apparatus 100 may be operated to stop the operation after completion of cleaning.

7 schematically shows a cleaning ball operating apparatus 200 according to a second embodiment of the present invention. Since the cleaning ball operating device 200 of FIG. 7 is similar to the cleaning ball operating device 100 of FIG. 2, the same reference numerals are used for the same parts, and a detailed description thereof will be omitted.

As shown in Fig. 7, the cleaning ball collecting cylinder 22 includes a cleaning ball collecting body 221 therein. The cleaning ball collecting body 221 is rotationally driven in the direction of the arrow by the hinge portion 223 attached to the inner wall of the cleaning ball collecting cylinder 22. That is, the cleaning balls B can be collected more easily by driving the cleaning ball collecting body 221. For example, when a failure occurs in the three-way valve 10, a cleaning ball collecting body 221 is provided in order to collect the cleaning balls B introduced from the collection line 90 into the cleaning ball collecting tank 22, Is driven to be positioned in a blocking position in the cleaning bowl 2. Therefore, the cleaning balls can be collected on the cleaning ball collecting body 221.

8 schematically shows a cleaning ball operating apparatus 300 according to a third embodiment of the present invention. The cleaning ball operating device 300 of FIG. 8 is similar to the cleaning ball operating device 100 of FIG. 3, and thus the same reference numerals are used for the same parts, and a detailed description thereof will be omitted.

8, the cleaning ball operating device 300 includes a recovery line 90, a cleaning ball collecting cylinder 20, a first pipe 33, and a second pipe 53. As shown in FIG. A first gate valve 93 is provided on the recovery line 90 and a second gate valve 13 is provided on the first pipeline 33. A check valve 55 is provided in the second pipe 53. Here, the gate valves 13 and 93 are valves which can be simply opened and closed, and can be operated by pneumatic, hydraulic, electric or the like. In addition, the check valve 55 prevents the reverse flow of the cooling water flowing through the second pipe 53. Since the internal structures of the gate valves 13 and 93 and the check valve 55 can be easily understood by those skilled in the art, detailed description thereof will be omitted.

3, the cleaning balls are circulated by using the first gate valve 93, the second gate valve 13 and the check valve 55, or the cleaning balls are collected in the cleaning ball collecting container 20 . 8), the first gate valve 93 and the second gate valve 13 are both opened so that the cooling water is supplied to the recovery line 90, the cleaning ball 90, To the collection tube 20, the first pipe 33, and the discharge line 92. Further, the cooling water can flow through the cleaning ball collecting cylinder 20 and along the second pipe 53 and the discharge line 92. The cleaning balls can not move through the second pipe 53 due to the cleaning ball collection net 60 and circulate through the first pipe 33. [

On the other hand, when the cleaning balls are collected from the collection line 90 into the cleaning ball collection cylinder 20, the second gate valve 13 is closed. As a result, the cooling water flowing into the cleaning ball collecting cylinder 20 can not pass through the first pipe 33 and flows to the discharge line 92 through the second pipe 53. Therefore, since the cooling water flows through the second pipe 53, the cleaning balls contained in the cooling water are caught in the cleaning ball collection net 60 and collected in the cleaning ball collection bin 20.

When the cleaning balls are removed from the cleaning ball collecting cylinder 20, the first gate valve 93 is closed. Therefore, the cooling water can no longer flow into the cleaning ball collecting cylinder 20, and the flow of the cooling water is stopped, so that the cleaning balls can be well removed from the cleaning ball collecting cylinder 20. As described above, the cleaning ball driving apparatus 300 can be efficiently driven by using the first gate valve 93, the second gate valve 13 and the check valve 55.

Hereinafter, the present invention will be described in more detail with reference to experimental examples. These experimental examples are only for illustrating the present invention, and the present invention is not limited thereto.

Experimental Example

A cleaning ball operating device having the same structure as in Fig. 1 was manufactured. In this case, the collection state of the cleaning balls in the cleaning ball collector was observed while making the diameter of the second pipe different from the diameter of the first pipe. The cleaning ball operating device was connected to the condenser of the power plant, and the number of cleaning balls used was 150. The cleaning balls were made of a sponge-like porous structure and had a diameter of 22 mm. The height of the cleaning bowl collector was 750 mm, and its diameter was 400 mm. The height difference between the recovery line and the first pipe was 500 mm. The first pipe and the second pipe were located at the same height. A cleaning ball collecting net with a hole size of 10 mm was installed in the connection portion of the second pipe through which cleaning balls were collected. The diameter of the first pipe used was 80 mm. Cleaning balls were collected in a cleaning ball collector while varying the diameter of the second tubing. An electrically operated ball valve is used for the three-way valve.

Experimental Example 1

The diameter of the second pipe was 50 mm. The second pipe was connected to a cleaning ball collector and a three-way valve. The remaining experimental procedure was the same as the above-mentioned experimental example.

Experimental Example 2

The diameter of the second pipe was 65 mm. The second pipe was connected to a cleaning ball collector and a three-way valve. The remaining experimental procedure was the same as the above-mentioned experimental example.

Experimental Example 3

The diameter of the second pipe was 80 mm. The second pipe was connected to a cleaning ball collector and a three-way valve. The remaining experimental procedure was the same as the above-mentioned experimental example.

Experimental Example 4

The diameter of the second pipe was 90 mm. The second pipe was connected to a cleaning ball collector and a three-way valve. The remaining experimental procedure was the same as the above-mentioned experimental example.

Experimental Example 5

The diameter of the second pipe was 100 mm. The second pipe was connected to a cleaning ball collector and a three-way valve. The remaining experimental procedure was the same as the above-mentioned experimental example.

Experimental Example 6

The diameter of the second pipe was 125 mm. The second pipe was connected to a cleaning ball collector and a three-way valve. The remaining experimental procedure was the same as the above-mentioned experimental example.

Experimental Example 7

The diameter of the second pipe was 150 mm. The second pipe was connected to a cleaning ball collector and a three-way valve. The remaining experimental procedure was the same as the above-mentioned experimental example.

Experimental Example 8

The diameter of the second pipe was 200 mm. The second pipe was connected to a cleaning ball collector and a three-way valve. The remaining experimental procedure was the same as the above-mentioned experimental example.

Experimental Example 9

The diameter of the second pipe was 250 mm. The second pipe was connected to a cleaning ball collector and a three-way valve. The remaining experimental procedure was the same as the above-mentioned experimental example.

Experiment result

First, the three-way valve was used to shut off the communication with the second pipe, the cleaning balls were put into the cleaning ball collecting case, and the cleaning balls were circulated by communicating the recovery line, the cleaning ball collecting case, the first pipe and the discharge line . Then, the three-way valve was used to block the communication with the first pipe, and the second pipe and the discharge line were connected to collect the cleaning balls in the cleaning ball collecting box. In this case, the collecting state of the cleaning balls in the cleaning ball collecting tanks of Experimental Examples 1 to 9 was observed.

Experimental results of Experimental Example 1

The cleaning balls recovered from the recovery line failed to escape from the cleaning ball collecting well and were collected well in the cleaning ball collecting bin. However, since the cooling water can not flow smoothly to the second pipe, a rising vortex due to the cooling water is generated to the upper part of the cleaning ball collecting barrel, and thus the cleaning ball collecting time is somewhat long. On the other hand, since the second pipe having a small diameter was used, the production cost of the second pipe was relatively inexpensive.

Experimental result of Experimental Example 2

The cleaning balls recovered from the recovery line failed to escape from the cleaning ball collecting chamber and were relatively well collected in the cleaning ball collecting chamber. However, since the cooling water does not flow well to the second pipe, the rising vortex due to the cooling water is generated to the vicinity of the upper part of the cleaning ball collecting barrel, and thus the cleaning ball collecting time is somewhat long. On the other hand, since the second pipe having a somewhat smaller diameter was used, the production cost of the second pipe was relatively inexpensive.

Experimental results of Experimental Example 3

The cleaning balls recovered from the recovery line failed to escape from the cleaning ball collecting well and were collected well in the cleaning ball collecting bin. However, since the cooling water had flowed comparatively well to the second pipe similarly as before, there was no eddy in the cooling water in the cleaning ball collecting case. Therefore, the collection time of cleaning balls was rather short. On the other hand, since the second pipe having an appropriate diameter was used, the manufacturing cost of the second pipe was normal.

Experimental results of Experimental Example 4

The cleaning balls recovered from the recovery line failed to escape from the cleaning ball collecting well and were collected well in the cleaning ball collecting bin. Since the cooling water flowed relatively well to the second pipe, no vortex was generated in the cooling water in the cleaning ball collector. Therefore, the collection time of cleaning balls was rather short. Further, although the second pipe having a rather large diameter was used, the volume of the second pipe was not so large, and the manufacturing cost of the second pipe was normal.

Experimental results of Experimental Example 5

The cleaning balls recovered from the recovery line failed to escape from the cleaning ball collecting well and were collected well in the cleaning ball collecting bin. Since the cooling water was well discharged to the second pipe, no vortex was generated in the cooling water in the cleaning ball collector, and the collection time of the cleaning balls was rather short. Further, although the second pipe having a rather large diameter was used, the volume of the second pipe was not so large, and the manufacturing cost of the second pipe was normal.

Experimental results of Experimental Example 6

The cleaning balls recovered from the recovery line failed to escape from the cleaning ball collecting well and were collected well in the cleaning ball collecting bin. Since the cooling water was well discharged to the second pipe, no vortex was generated in the cooling water in the cleaning ball collecting case. Therefore, the cleaning ball collection time is shortened. However, the production ratio was slightly increased by using a second pipe having a rather large diameter.

Experimental results of Experimental Example 7

The cleaning balls recovered from the recovery line failed to escape from the cleaning ball collecting well and were collected well in the cleaning ball collecting bin. Since the cooling water was well discharged to the second pipe, no vortex was generated in the cooling water in the cleaning ball collecting case. Therefore, the cleaning ball collection time is shortened. However, the production ratio was slightly increased by using a second pipe having a rather large diameter.

Experimental results of Experimental Example 8

The cleaning balls recovered from the recovery line failed to escape from the cleaning ball collecting well and were collected well in the cleaning ball collecting bin. Since the cooling water was well discharged to the second pipe, no vortex was generated in the cooling water in the cleaning ball collecting case. Therefore, the cleaning ball collection time is shortened. However, the manufacturing cost was greatly increased by using the second pipe having a large diameter.

Experimental results of Experimental Example 9

The cleaning balls recovered from the recovery line failed to escape from the cleaning ball collecting well and were collected well in the cleaning ball collecting bin. Since the cooling water was well discharged to the second pipe, no vortex was generated in the cooling water in the cleaning ball collecting case. Therefore, the cleaning ball collection time is shortened. However, the manufacturing cost was greatly increased by using the second pipe having a large diameter.

The above-described experimental results are summarized in Table 1 below. In Table 1, the piping expense ratio means the ratio of the second pipe diameter to the first pipe diameter.

As shown in Table 1, in Experimental Examples 3 to 7, the production ratio of the second pipe was moderate or slightly increased, but the cleaning ball collection time could be shortened or maintained as usual. More preferably, in Experimental Examples 3 to 5, the collection time of the cleaning balls could be shortened in spite of the installation of the cleaning ball collecting net while maintaining the production cost of the second pipe at a normal level. Therefore, the efficiency of using the cleaning balls can be increased.

It will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the following claims.

10. Three way valve 13, 93. Gate valve
20, 22. Cleaning bowl collecting basin 30, 33. First piping
40. Pump 50, 53. Second piping
55. Check valve 60. Cleaning ball collecting net
90. Recovery line 92. Discharge line
93. Gate valve 95. Heat exchanger
97. Coolant inlet line 98. Coolant outlet line
99. Cleaning ball collecting net 100, 200. Cleaning ball operating device
201. Cleaning ball collecting unit 203. Cover
205. fixing part 221. cleaning ball collecting body
209, 223. Hinge portion 2511. Body portion
2053. First end 2055. Second end
B. Washing balls

Claims (13)

A three-way valve connected to the discharge line for discharging the cleaning balls to the discharge line,
A cleaning ball collecting container connected to the collection line for collecting the cleaning balls introduced through the collection line,
A first pipe connecting the three-way valve and the cleaning ball collecting cylinder,
Way valve and a second pipe for connecting the three-way valve and the cleaning ball collecting cylinder separately from the first pipe,
/ RTI >
A cleaning ball collecting net blocking the connection of the second pipe and the cleaning ball collecting barrel,
The cleaning ball collecting container includes:
A cleaning ball collecting unit,
A cover provided on the cleaning ball collecting part and adapted to open and close the cleaning ball collecting part,
And a plurality of fixing parts applied to closely fix the cover on the cleaning ball collecting part
/ RTI >
The plurality of fixing portions may include:
A long body extending in one direction,
A first end connected to the body and hinged to the side of the cleaning ball collector,
And a second end that is provided with a bolt and fixes the cover on the cleaning ball collecting portion
And a control unit for controlling the cleaning unit. The method according to claim 1,
Wherein the length of the second pipe is greater than the length of the first pipe, and the second pipe includes a bending portion. 3. The method of claim 2,
And the diameter of the second pipe is equal to or larger than the diameter of the first pipe. The method of claim 3,
Wherein the ratio of the diameter of the second pipe to the diameter of the first pipe is 1.000 to 1.875. The method according to claim 1,
Further comprising a pump installed in the recovery line and adapted to introduce the cleaning balls into the cleaning ball collection cylinder. The method according to claim 1,
Wherein the three way valve closes communication with the second pipe when the cleaning balls are discharged from the cleaning ball collecting cylinder to the discharge line side through the first pipe. The method according to claim 1,
Way valve closes communication with the first pipe when the cleaning balls are collected from the collection line into the cleaning ball collection case. The method according to claim 1,
Way valve closes communication with the discharge line when the cleaning balls are removed from the cleaning ball collection cylinder. The method according to claim 1,
Wherein the cleaning ball collecting cylinder includes a cleaning ball collecting body installed in the inside thereof and rotatably driven, and when the cleaning balls collect from the collecting line into the cleaning ball collecting cylinder, the cleaning ball collecting body collects the cleaning balls A cleaning ball drive device driven so as to be positioned to intercept the barrel. delete A recovery line provided with the first gate valve,
A cleaning ball collecting box connected to the collecting line for collecting the washing balls flowing through the collecting line,
A first conduit connected to the cleaning ball collection passage, to which a second gate valve is installed, the first conduit connected to the discharge line,
And a second pipe connected to the cleaning ball collecting cylinder separately from the first pipe and provided with a check valve,
/ RTI >
A cleaning ball collecting net blocking the connection of the second pipe and the cleaning ball collecting barrel,
The cleaning ball collecting container includes:
A cleaning ball collecting unit,
A cover provided on the cleaning ball collecting part and adapted to open and close the cleaning ball collecting part,
And a plurality of fixing parts applied to closely fix the cover on the cleaning ball collecting part
/ RTI >
The plurality of fixing portions may include:
A long body extending in one direction,
A first end connected to the body and hinged to the side of the cleaning ball collector,
And a second end that is provided with a bolt and fixes the cover on the cleaning ball collecting portion
And a control unit for controlling the cleaning unit. 12. The method of claim 11,
Wherein the second gate valve is closed when the cleaning balls are collected from the collection line into the cleaning ball collection case. 12. The method of claim 11,
Wherein the first gate valve is closed when the cleaning balls are removed from the cleaning ball collection cylinder.

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