KR20160110792A - Apparatus for separating cleaning ball installed a system for cleaning cooling water pipes using clean ball - Google Patents

Abstract

The present invention relates to an apparatus for sorting cleaning balls installed in multiple tube cleaning systems, which sorts cleaning balls on the basis of the diameters of multiple tubes. To achieve this, the apparatus for sorting cleaning balls installed in multiple tube cleaning systems comprises: a sorting housing which has an inlet and an outlet arranged to face each other at an interval in a flow direction, and a sorting hole formed in a direction horizontal to the flow direction; and a sorting unit which has multiple plate-shaped sorting parts arranged in a radial direction around a main flow path arranged in the flow direction and extended in the flow direction, and a sorting support part for supporting the sorting parts, wherein the main flow path has a flow cross section which gets narrower from the inlet to the outlet.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a cleaning ball sorting apparatus,

The present invention relates to a cleaning ball sorting apparatus installed in a multiple tube cleaning system.

Nuclear and thermal power plants require large amounts of cooling water, so they mainly use seawater as a cooling water source. When seawater is used as a cooling water source, marine organisms such as barnacles, seaweeds, and the like are adhered to the inner wall of the condenser tube, thereby deteriorating the flow and heat transfer of the cooling water. Therefore, the condensate tube cleaning system is combined with the cooling water to remove foreign substances adhered to the inner wall of the cooling water pipe Supply the cleaning ball. These wash balls are made of a flexible material and are made relatively larger than the inner diameter of the baffles. These wash balls pass through the condenser tube to remove foreign matter adhering to the inner wall and continue to circulate on the condensate tube cleaning system.

However, the wash balls continue to circulate on the condensate tube cleaning system and gradually decrease in size due to friction with the inner wall of the condenser tube. When the size of the cleaning ball is reduced to approximate the inner diameter of the condenser tube, the cleaning ball does not exhibit the cleaning effect even if it passes along the condenser tube. It is therefore necessary to classify the wash balls which have been worn down so that only valid wash balls are circulated on the multiple tube wash systems.

It is an object of the present invention to provide a cleaning ball sorting device capable of sorting the cleaning balls based on the diameter of the tube of the condenser.

The cleaning ball sorting apparatus according to the present invention comprises: a sorting housing having an inlet port and an outlet port arranged opposite to each other with a space therebetween in the flow direction; A plurality of plate-shaped separators extending radially from the main flow path along the flow direction and extending along the flow direction, and a separating and supporting part for supporting the separators, And a separation unit having a flow cross-sectional area reduced toward the cleaning ball outlet side.

Here, the clearance between the free ends of the separating units adjacent to each other in the separating units can be more accurately separated from the cleaning balls based on a predetermined size, which is constant along the flow direction.

On the other hand, the separating portion forms a relatively thick thick portion in the free end region, and the thick portion has a curved shape, thereby preventing breakage of the cleaning balls progressing at a high speed.

The cleaning ball sorting apparatus according to the present invention can classify the cleaning balls based on the diameter of the tube of the condenser. The clearance between the free ends of the separating units adjacent to each other of the separating units can more accurately separate the cleaning balls based on a predetermined size when they are constant along the flow direction. Also, the separator may form a relatively thick thick portion in the free end region, and the thick portion may prevent the cleaning balls, which progress at a high speed, from being broken if the curved shape is provided.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic representation of a multi-
2 is a cross-sectional view of the cleaning ball sorting apparatus according to the present invention,
3 is a cross-sectional view taken along line III (A) -III (A) and III (B) -III (B) shown in FIG.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic diagram of a condenser tube cleaning system. 1, the cooling water flows along the cooling water inflow path 20 on the right side and flows out along the cooling water outflow path 30 on the left side through the condenser 10.

The cleaning balls are introduced into the cooling water through the cleaning ball input portion 800 disposed on the cooling water inflow path 20. The cleaning balls inserted into the cooling water do not flow out along the cooling water outflow path 30 after being passed through the multiple pipes of the condenser 10 and are filtered by the cleaning ball screen 100. In the cleaning ball screen 100, the cooling water is allowed to flow along the cooling water outflow path 30, and the cleaning balls are screened and discharged separately through the ball outlets 150a and 150b. The cleaning balls discharged through the ball outlets 150a and 150b are directed to the cleaning ball sorting apparatus 400. [ Between the ball outlets 150a and 150b and the cleaning ball sorting apparatus 400, a pump 200 for controlling the pressure of the cleaning balls is installed.

The cleaning ball sorting apparatus 400 allows the cleaning balls that are larger than the diameter of the condenser 10 tube to pass through to the ball collector 500 to continue to circulate and the cleaning balls that are equal to or less than the tube diameter of the condenser 10, 408, and collected by the cleaning ball collecting unit 420.

2 is a cross-sectional view of the cleaning ball sorting apparatus 400 according to the present invention. As shown in Fig. 2, the cleaning ball sorting apparatus 400 has a sorting housing 401 which forms an internal space. The sorting housing 401 is formed with an inlet port 403 and an outlet port 405 which are mutually opposed to each other in the flow direction and a separator 407 penetrating in the transverse direction with respect to the flow direction. The separator 407 is connected to the bypass 408.

Inside the sorting housing 401, a separation unit 410 for sorting the cleaning balls according to sizes is provided. The separation unit 410 has a separation portion 413 disposed at an interval along the circumferential direction about the axis of the flow direction F and forms a main flow path along the flow direction F. [ The separating portions 413 are plate-shaped and arranged radially with a main flow path, and extend along the flow direction F. [ The separation parts 413 are supported by the separation supporting part 417 and the separation supporting part 417 is fixed to the inner wall of the sorting housing 401 at the inlet 403 side. The separation support portion 417 extends from the inner wall on the inlet port side of the sorting housing 401 by a predetermined length along the flow direction. At this time, the separation supporting portion 417 is spaced at least such that at least the cleaning balls can pass through the inner wall on the side of the outlet 405 of the sorting housing 401.

3 is a cross-sectional view taken along line III (A) -III (A) and III (B) -III (B) shown in FIG. Referring to FIG. 3 together with FIG. 2, the main flow path is reduced in cross sectional area from the cleaning bowl inlet 403 to the cleaning bowl outlet 405 side. That is, the diameter d1 of the main flow path at the position of the line III (A) -III (A) in FIG. 2 is larger than the diameter d2 of the main flow path at the position of the line III (B) .

Accordingly, when the cleaning balls move along the flow direction F, the possibility of contact of the separation portion 413 with the free end 415 can be increased, so that the small cleaning balls can be separated with a higher probability.

In the free end region of the separation portions 413, a thick portion 415 relatively thicker than the body is formed, and the thick portion 415 has a curved shape. Accordingly, it is possible to prevent the soft flexible cleaning balls from being damaged even when receiving the shearing force from the free ends of the separation portions 413 while moving at a high speed.

At this time, the interval between free ends 415 of mutually adjacent separating units 413 among the separating units 413 is constant along the flow direction. That is, the distance L1 between the free ends 415 at the position of the line III (A) -III (A) in FIG. 2 is larger than the distance L1 between the free ends 415 at the III (B) L2) length. Here, it is preferable that the lengths of L1 and L2 are approximate to the length of the inner diameter of the tube (10) of the condenser (10).

Thus, the diameter of the main flow path is reduced along the flow direction (d1 to d2), and the flow direction F is changed to maintain the gap between the free ends 415 of the adjacent separation portions 413 (L1 = L2) The size of the thick portion 415 is reduced.

On the other hand, the interval between the free ends 415 of the separating portions 413 adjacent to each other along the flow direction F may not be maintained constant. That is, the size of the thick portion 415 may be maintained along the flow direction F so that the gap between the free ends 415 may be reduced. In this case, the maximum length of the interval between the free ends 415 of the adjacent separating portions 413, that is, the distance between the free end 415 on the outlet side is approximated to the inside diameter of the condenser 10.

With this structure, the cleaning balls having diameters larger than the distances L1 and L2 between the free ends 415 of the adjacent separating portions 413 pass along the main flow path and are directed to the ball collector 500, The cleaning balls having diameters equal to or less than the clearances L1 and L2 between the separation portions 413 and 415 are discharged to the bypass passage 408 through the separation portion 407 through the separation portion 413. The cleaning balls moved along the bypass path 408 are collected at the cleaning ball collecting unit 420. The cleaning ball collecting unit 420 collects the cooling water through the screen and scans only the cleaning balls. Accordingly, the cleaning ball sorting apparatus 400 eliminates the cleaning balls having a cleaning ability that is less than a predetermined size, and allows only the cleaning balls having the cleaning ability to continuously circulate.

The ball collector 500 has a collector screen disposed in the inner space, and can allow or block the movement of the cleaning balls through manipulation of the screen. A cleaning ball counter 600 is disposed downstream of the ball collector 500. The cleaning ball counter 600 measures the number of cleaning balls discharged from the ball collector 500. The cleaning ball counter 600 can measure the physical force generated when the cleaning balls flow, or measure the number of cleaning balls by using a light emitting element and a light receiving element or by photographing a camera.

The washing balls passing through the washing ball counter 600 are sprayed on the cooling water again through the washing ball inlet part 800 and moved along with the cooling water along the tube 10 to remove foreign substances from the inner wall of the condenser 10 do.

10: condenser 20: cooling water inflow path
30: Cooling water outflow line 100: Cleaning ball screen
150a, 150b: Cleaning ball outlet 200: Pump
300: upstream valve 400: cleaning ball sorting device
401: sorting housing 403: ball inlet
405: ball outlet 407: ball separator
408: Bypass 410: Separation unit
411: main flow path 413: separation part
415: thick portion 417:
420: Cleaning fire collector 500: Ball collector
600: Cleaning bowl counting part 700: Downstream valve
800: Cleaning ball input part

Claims (3)

CLAIMS 1. A cleaning ball sorting apparatus which is installed in a multi-tube cleaning system and classifies the cleaning balls according to size,
An inlet port and an outlet port arranged opposite to each other at intervals along the flow direction, and a separation port formed in the flow direction in the lateral direction;
A plurality of plate-shaped separators extending radially from the main flow path along the flow direction and extending along the flow direction, and a separating and supporting part for supporting the separators, And a separation unit having a flow cross-sectional area reduced toward the cleaning ball outlet side. The method according to claim 1,
Wherein a gap between free ends of mutually adjacent separating portions of the separating portions is constant along the flow direction. The method according to claim 1,
Wherein the separating portion forms a relatively thick thick portion in a free end region, and the thick portion has a curved shape.

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