KR20230128785A - Cleaning ball detection device - Google Patents

Abstract

The invention of a cleaning ball detection device is disclosed. The disclosed cleaning ball detection device is installed in a heat exchanger, has a main pipe through which a plurality of cleaning balls and fluid move, branches at a point in the main pipe and is connected to another point in the main pipe, and transfers some of the cleaning balls and fluid in a branching manner. It is characterized in that it includes a branch pipe and a wear degree measurement unit for measuring and determining the degree of wear of the cleaning balls provided in the branch pipe and transported in a branch.

Description

Cleaning ball detection device {CLEANING BALL DETECTION DEVICE}

The present invention relates to a cleaning ball detection device, and more particularly, is provided in a branch pipe branched from the main pipe to measure the wear of the cleaning ball branched from the main pipe, and enters the cleaning ball moving in the main pipe by using a vortex It relates to a cleaning ball detection device capable of accurately measuring the number of cleaning balls by inducing them in a row.

In general, as a conduit through which a fluid such as water flows is used, components contained in the water accumulate in the conduit and foreign substances or rust are generated through corrosion of the conduit, resulting in a significant deterioration in the performance of the device.

As an example, a heat exchanger used in a power plant among equipment exhibits its performance by the flow of fluid including cooling water passing through a pipe line, but the flow of the fluid is smooth due to the accumulation of foreign substances and rust on the pipe line, heat transfer pipe or heat plate due to long-term use. There is a problem that does not perform properly because it is not done.

In order to improve this, cleaning balls are introduced into the conduit and circulated to remove foreign substances and rust generated inside the heat exchanger. That is, as the cleaning ball passes through the inside of the pipe of the device including the heat exchanger, it hits the part where foreign matter is accumulated and the part where rust occurs, removing foreign matter and rust to keep the inside of the pipe clean, so the performance of the heat exchanger can be maintained as it is. .

However, when the cleaning ball is used for a certain period of time, it hits the inner wall of the pipe and wears out, gradually decreasing in size, and the foreign matter and rust accumulated inside the pipe cannot be properly removed, so the performance of the heat exchanger deteriorates. However, there is no method for predicting the replacement time of the cleaning balls by accurately measuring the degree of wear of the cleaning balls. In addition, a device for counting the number of cleaning balls by inducing them has been proposed, but there is a problem in that the number of cleaning balls is not accurately measured due to the problem that the cleaning balls are caught on the entry side of the guide part for guiding the cleaning balls. .

Therefore, there is a need to improve this.

As a related background art, there is Korean Patent Registration No. 1384109 (2014.04.04, title of the invention: ball counting device).

The present invention was created by the above necessity, and is provided in a branch pipe that is branched from the main pipe coupled to the pipe to measure the abrasion of the cleaning ball branched from the main pipe, and uses a vortex to enter the cleaning ball passing through the main pipe Its purpose is to provide a cleaning ball detection device capable of accurately measuring the number of cleaning balls by inducing them in a row.

In order to achieve the above object, the cleaning ball detection device according to the present invention is installed in a heat exchanger, and includes a main pipe through which a plurality of cleaning balls and a fluid move; a branch pipe branched from a certain point of the main pipe and connected to another point of the main pipe, and branching and transporting any part of the cleaning ball and the fluid; and a wear degree measuring unit provided in the branch pipe to measure and determine the degree of wear of the cleaning balls that are branched and transported.

and a counting unit for counting the number of cleaning balls transported only to the main pipe or the number of cleaning balls transported to the main pipe and the branch pipe, wherein the counting unit is provided inside the main pipe, and the cleaning ball a shrinking unit for reducing and guiding the flow of the cleaning balls to pass through the cleaning balls one by one in a row; and a counting sensor that moves the shrinking unit or counts the number of cleaning balls that have passed through the shrinking unit.

The main pipe includes a vortex generator for forming a vortex in the cleaning ball to guide smooth entry of the cleaning ball into the reduced portion and guiding it to the center of the reduced portion, and the vortex generating portion is wound inside the main pipe in a spiral form. It is characterized in that it is formed as a groove or protrusion while holding.

The wear measurement unit is provided in the branch pipe, a flow meter for measuring the flow rate (velocity of the fluid) passing through the branch pipe; a sensing unit provided in the branch pipe and detecting a difference in moving time of the cleaning balls passing through the branch pipe; and a control unit configured to determine the wear degree of the cleaning balls by measuring the speed of the cleaning balls using the moving time difference value of the cleaning balls detected by the sensing unit with respect to the flow rate measured by the flow meter. to be characterized

The sensing unit may include: a first light emitting sensor provided at one point of the branch pipe to irradiate light into the branch pipe; a first light-receiving sensor detecting a moving time of the cleaning ball by recognizing a time point when the light emitted from the first light-emitting sensor is blocked by the cleaning ball; a second light emitting sensor provided at another point of the branch pipe, spaced apart from the first light emitting sensor by a set distance, and irradiating light into the branch pipe; and a second light-receiving sensor for detecting a moving time of the cleaning ball by detecting a time point when the light emitted from the second light-emitting sensor is blocked by the cleaning ball.

In the cleaning ball detection device according to the present invention, a wear degree measuring unit is provided in a branch pipe connected to a main pipe connected to a pipe, so that the wear degree of the cleaning ball branched in the main pipe can be measured and the replacement time can be determined.

In addition, according to the present invention, the wear degree of the cleaning balls measured by the wear measurement unit can be determined and the replacement timing of the cleaning balls can be notified to the user through the replacement timing notification unit.

In addition, according to the present invention, the number of cleaning balls can be accurately measured by preventing the cleaning balls from being caught by inducing a vortex through the spiral portion when the cleaning balls enter through the main pipe.

In addition, according to the present invention, the main pipe is provided with a vortex generator in the shape of a groove or a protrusion to induce a vortex when the cleaning balls enter and give a rotational force to the cleaning balls, thereby guiding them in a row toward the center of the reduced portion to prevent the cleaning balls from getting stuck. .

1 is an overall configuration diagram of a washing ball detection device according to an embodiment of the present invention.
2 is a view showing a state in which the degree of wear of the cleaning balls is measured using a wear degree measuring unit in the cleaning ball detection device according to an embodiment of the present invention.
3 is a view showing a straight tube shape of a reduced part in the counting part of the washing ball detection device according to an embodiment of the present invention.
4 is a view showing an inclined shape of a reduced part in a counting part of a cleaning ball detection device according to an embodiment of the present invention.
5 is a view showing a curved streamlined shape of the reduced part in the counting part of the washing ball detection device according to an embodiment of the present invention.

Hereinafter, an apparatus for detecting cleaning balls according to an embodiment of the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of a user or operator. Therefore, definitions of these terms will have to be made based on the content throughout this specification.

1 is an overall configuration diagram of a cleaning ball detecting device according to an embodiment of the present invention, and FIG. 2 is a cleaning ball detecting device according to an embodiment of the present invention, which measures the degree of wear of the cleaning balls using a wear measurement unit. FIG. 3 is a view showing the straight tube shape of the reduced part in the counting unit of the cleaning ball detection device according to an embodiment of the present invention, and FIG. 4 is the cleaning ball detection device according to an embodiment of the present invention. 5 is a view showing a curved streamlined shape of the reduced portion in the counting unit of the cleaning ball detection device according to an embodiment of the present invention.

1 to 5 , the cleaning ball detection device according to an embodiment of the present invention includes a main pipe 100, a branch pipe 200, and a wear degree measurement unit 400.

The main pipe 100 is installed in the heat exchanger and has a configuration in which a plurality of cleaning balls 10 and a fluid move. Here, the fluid includes cooling water.

The main pipe 100 is formed larger than the diameter of the cleaning balls so that the cleaning balls can move smoothly. The main pipe 100 may be opaque or made of a transparent material in some necessary sections.

A conduit 20 connecting a discharge line of the heat exchanger and an inlet line of the heat exchanger through a flange may be provided on the inlet side and the outlet side of the main pipe 100, respectively. That is, the inlet side of the main pipe 100 is connected to the discharge line of the heat exchanger, and the outlet side of the main pipe 100 is connected to the inlet line of the heat exchanger.

The branch pipe 200 is branched at a point in the main pipe 100 and connected to another point in the main pipe 100, and branches and transfers a portion of the cleaning balls 10 and the fluid.

The branch pipe 200 may have the same or similar diameter as the cleaning ball 10 . The main pipe 100 or the branch pipe 200 may be made of a transparent material in some sections.

The branch pipe 200 may be configured to have the same inner diameter as the condenser. The reason for this is to measure the degree of abrasion of the cleaning balls 10 accordingly, since the cleaning balls 10 collide with and remove foreign substances or rust formed inside the condenser.

The cleaning ball detection device according to an embodiment of the present invention counts the number of cleaning balls transferred only to the main pipe 100 or the number of cleaning balls 10 transferred to the main pipe 100 and the branch pipe 200. It may include a counting unit 300 that does.

As shown in FIG. 1, the counting unit 300 is shown as measuring the number of cleaning balls transferred only to the main pipe 100 as an example, but is installed in the main pipe 100 on the discharge side of the branch pipe 200. The number of cleaning balls 10 transferred to the main pipe 100 and the branch pipe 200 may be counted.

The counting unit 300 is provided inside the main pipe 100 and reduces and guides the flow of the cleaning balls 10 to guide them to pass through the cleaning balls 10 one by one in a row. 330) and a counting sensor 340 that counts the number of cleaning balls 10 that have moved the shrinking parts 310, 320, and 330 or passed through the shrinking parts 310, 320, and 330. do.

The reduced parts 310, 320, and 330 are made of at least one of a perforated plate, a wedge wire, or a bar to reduce the differential pressure in the fluid flowing inside the main pipe 100 to smooth the flow of the fluid. It can be configured to guide you.

Referring to FIGS. 1 and 3 , the reduced portion 310 may be supported on the inner circumferential surface of the main pipe 100 and extended toward the center of the main pipe 100 and then extended in a straight line.

The reduced part 310 includes an inner diameter expansion part 312 extending from the inner circumferential surface of the main pipe 100 toward the center, and a straight moving part 314 extending in a straight direction from the inner end of the inner diameter expansion part 312. do. The inner diameter expansion part 312 is formed as a circular plate. The straight moving unit 314 is formed as a circular tube. At the exit side of the inner diameter expansion part 312, the cleaning balls 10 may be discharged one by one in a row.

The inner diameter expansion part 312 and the linearly moving part 314 are formed with holes or spaces to help the flow of fluid.

Referring to FIG. 4 , the reduced portion 320 may be supported on the inner circumferential surface of the main pipe 100 and extended in a funnel shape to have an inclined surface to move the cleaning balls 10 one by one.

The reduced portion 320 may include an inner support portion 322 supported on an inner circumferential surface of the main pipe 100 and an inclined moving portion 324 extending obliquely in a funnel shape from an inner end of the inner support portion 322. The inner support part 322 has a length long enough to prevent the cleaning ball 10 from being caught, and makes it easy to fix to the inner surface of the main pipe 10.

The inner support part 322 is formed as a circular plate. The inclined moving part 324 is formed of a cone-shaped inclined pipe. The inclined moving part 324 is formed to be inclined so that the cleaning balls 10 passing through the inside are discharged one by one in a row from the outlet side.

The inner support part 322 and the inclined moving part 324 are formed with holes or spaces to help the flow of fluid.

Referring to FIG. 5 , the reduced portion 330 may be supported on the inner circumferential surface of the main pipe 100 and extended curvedly in a streamlined shape to have a set curvature.

The reduced portion 330 may include an inner support portion 332 supported on an inner circumferential surface of the main pipe 100 and a bending moving portion 334 curvedly extending in a streamlined shape from an inner end of the inner support portion 322. .

The inner support part 322 is formed as a circular plate. The bending moving part 334 is formed as a streamlined inclined pipe. The bending moving part 334 is formed to be curved so that the cleaning balls 10 passing through the inside are discharged one by one from the outlet side.

The inner support part 322 and the bending moving part 334 are formed with holes or spaces to help the flow of fluid.

The counting sensor 340 includes a light emitting unit 342 that emits light and a light receiving unit 344 that receives the light emitted from the light emitting unit 342 .

The counting sensor 340 senses that the light irradiated from the light emitting unit 342 is blocked by the cleaning ball 10 when the cleaning ball 10 passes through the branch pipe 200, and the light receiving unit 344 detects that the cleaning ball 10 10) detects the number of passes.

The counting sensor 340 has a feature of not detecting foreign substances of 6 mm or less. This is to reduce detection errors.

The reduced parts 310, 320, and 330 may be formed of a transparent material. Thus, when the counting sensor 340 is installed outside the main pipe 100 made of a transparent material, when light is projected to the outside of the reduced parts 310, 320, and 330, the reduced parts 310, 320, and 330 ), the movement of the cleaning ball 10 can be sensed.

The main pipe 100 forms a vortex in the cleaning ball 10 to guide the cleaning ball 10 to smoothly enter the reduced portion 310, 320, and 330, thereby reducing the pressure of the reduced portion 310, 320, 330. It includes a vortex generator 350 guiding it over the center.

The vortex generating unit 350 is formed as a groove or a protrusion while being wound in a spiral shape inside the main pipe 100.

The vortex generating unit 350 forms a vortex in the cleaning ball 10 moving with the fluid, guides it toward the center of the main pipe 100, and guides it to the center of the reduced portion 310, 320, and 330, so that the cleaning ball (10) is prevented from being clogged with the surface of the entry side of the constriction parts 310, 320, and 330. Accordingly, it is possible to prevent the cleaning balls 10 from being clogged by sticking to the surfaces of the shrinking units 310, 320, and 330, as in the prior art.

The vortex generating unit 350 includes a groove recessed to a set depth on the inner circumferential surface of the main pipe 100 and a protrusion protruding from the inner circumferential surface of the main pipe 100 toward the center. At this time, the grooves and protrusions may be formed in various shapes.

A spiral part 360 is provided at the beginning of the main pipe 100 to guide the branching of the cleaning balls 10 moving to the branch pipe 200 . The spiral part 360 includes a spiral plate.

The end side of the spiral part 360 may be connected to the entry side of the branch pipe 200 to guide some of the plurality of cleaning balls 10 to the branch pipe 200 .

The wear measurement unit 300 is provided in the branch pipe 200 to measure and determine the wear degree of the cleaning balls 10 that are branched and transported. In the branch pipe 200, the cleaning balls 10 move only one by one in order to accurately measure the degree of abrasion of the cleaning balls 10.

The wear measurement unit 300 is provided in the branch pipe 200, and is provided in the flow meter 410 and the branch pipe 410 for measuring the flow rate (velocity of the fluid) passing through the branch pipe 200, The sensing unit 420 detects the difference in moving time of the cleaning balls 10 passing through the pipe 420, and the cleaning balls 10 detected by the sensing unit 420 with respect to the flow rate measured by the flow meter 410 and a control unit 430 that determines the degree of abrasion of the cleaning balls 10 by measuring the speed of the cleaning balls 10 using the moving time difference value.

The sensing unit 420 includes a first light emitting sensor 422 provided at one point of the branch pipe 200 and irradiating light into the branch pipe 200, and the light emitted from the first light emitting sensor 422. The first light-receiving sensor 424 detects the moving time of the cleaning ball 10 by detecting the time when the cleaning ball 100 is blocked, and the first light-emitting sensor provided at another point of the branch pipe 200 ( 422) and a second light emitting sensor 426 that is installed at a set distance and radiates light into the branch pipe 200, and the light emitted from the second light emitting sensor 426 is blocked by the cleaning ball 10 and a second light-receiving sensor 428 for detecting the movement time of the cleaning ball 10 by detecting the time when the washing ball 10 is moved.

The control unit 430 determines the difference between the time detected by the first light emitting sensor 422 and the first light receiving sensor 424 and the time detected by the second light emitting sensor 426 and the second light receiving sensor 428, The moving speed of the cleaning ball 10 may be measured by comparing the speed of the fluid detected by the flow meter 410 .

In this way, the degree of wear of the cleaning balls 10 is determined by determining the state in which the cleaning balls 10 pass through the branch pipe 200 using the moving speed of the cleaning balls 10 . Using this information, if the moving speed of the cleaning ball 10 is almost equal to or similar to the speed of the fluid, it is determined that the degree of abrasion of the cleaning ball 10 is high, and the moving speed of the cleaning ball 10 is the speed of the fluid. If the level is low, it can be determined that the degree of abrasion of the cleaning balls 10 is low, and the replacement timing of the cleaning balls 10 can be determined based on this.

The wear measurement unit 400 checks the wear degree (cleaning rate) of the plurality of cleaning balls 10 measured by the control unit 430 and averages them to display or notify the replacement time of the cleaning balls 10. A notification unit 440 may be included.

The replacement time notification unit 440 determines the degree of abrasion of the cleaning balls 10 measured by the control unit 430, sets an alarm rate within the effective measurement range, and operates the cleaning balls 10 at a desired set time point. The replacement time of the cleaning ball 10 may be notified.

The replacement timing notification unit 440 may include an alarm or monitor.

Therefore, in the cleaning ball detection device according to an embodiment of the present invention, a wear degree measuring unit is provided in a branch pipe connected to a main pipe connected to a pipe, so that the wear of the cleaning ball branched and moved in the main pipe can be measured and the replacement time can be determined. . In addition, according to the present invention, the wear degree of the cleaning balls measured by the wear measurement unit can be determined and the replacement timing of the cleaning balls can be notified to the user through the replacement timing notification unit.

In addition, according to the present invention, the number of cleaning balls can be accurately measured by preventing the cleaning balls from being caught by inducing a vortex through the spiral portion when the cleaning balls enter through the main pipe. In addition, according to the present invention, the main pipe is provided with a vortex generator in the shape of a groove or a protrusion to induce a vortex when the cleaning balls enter and give a rotational force to the cleaning balls, thereby guiding them in a row toward the center of the reduced portion to prevent the cleaning balls from getting stuck. .

The present invention has been described with reference to the embodiments shown in the drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalent other embodiments. will understand

Therefore, the true technical protection scope of the present invention should be determined by the claims below.

10: cleaning ball 100: main pipe
200: branch pipe 300: counting unit
310: reduction part 312: inner diameter expansion part
314: linear movement unit 320: reduction unit
322: inner support part 324: inclined moving part
330: reduced portion: 332: inner support portion
334: bending moving unit 340: counting sensor
342; Light sensor 344: light receiving sensor
350: vortex generating unit 360: spiral unit
400: wear measurement unit 410: flow meter
420: sensing unit 422: first light emitting sensor
324: first light receiving sensor 426: first light emitting sensor
328: second light receiving sensor 430: control unit

Claims (5)

A main pipe installed in the heat exchanger and through which a plurality of cleaning balls and fluid move;
a branch pipe branched from a certain point of the main pipe and connected to another point of the main pipe, and branching and transporting any part of the cleaning ball and the fluid; and
A wear degree measurement unit provided in the branch pipe to measure and determine the degree of wear of the cleaning balls that are branched and transported;
Cleaning ball detection device, characterized in that it comprises.
According to claim 1,
A counting unit for counting the number of cleaning balls transported only to the main pipe or the number of cleaning balls transported to the main pipe and the branch pipe;
The counting unit,
a shrinking unit provided inside the main pipe and reducing and guiding the flow of the cleaning balls to pass through the cleaning balls one by one in a row; and
a counting sensor for counting the number of cleaning balls that move the shrinking unit or pass through the shrinking unit;
Cleaning ball detection device, characterized in that it comprises.
According to claim 2,
The main pipe includes a vortex generator for forming a vortex in the cleaning ball to guide the cleaning ball to smoothly enter the constriction portion and guiding it to the center of the constriction portion;
The cleaning ball detecting device, characterized in that the vortex generator is formed as a groove or a protrusion while being wound in a spiral shape inside the main pipe.
According to claim 1,
The abrasion measurement unit,
a flow meter provided in the branch pipe and measuring a flow rate (velocity of the fluid) passing through the branch pipe;
a sensing unit provided in the branch pipe and detecting a difference in moving time of the cleaning balls passing through the branch pipe; and
a control unit configured to determine the degree of abrasion of the cleaning balls by measuring the speed of the cleaning balls using the moving time difference value of the cleaning balls detected by the sensing unit with respect to the flow rate measured by the flow meter;
Cleaning ball detection device, characterized in that it comprises.
According to claim 3,
the sensor,
a first light emitting sensor provided at one point of the branch pipe to irradiate light into the branch pipe;
a first light-receiving sensor detecting a moving time of the cleaning ball by recognizing a time point when the light emitted from the first light-emitting sensor is blocked by the cleaning ball;
a second light emitting sensor provided at another point of the branch pipe, spaced apart from the first light emitting sensor by a set distance, and irradiating light into the branch pipe; and
a second light-receiving sensor for detecting a moving time of the cleaning ball by detecting a time point when the light emitted from the second light-emitting sensor is blocked by the cleaning ball;
Cleaning ball detection device, characterized in that it comprises.

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