JP2016176641A - Thin tube cleaning device and method for heat exchanger - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress outflow of a cleaning ball to outside, in a thin tube cleaning device and method for a heat exchanger.SOLUTION: A thin tube cleaning device for a heat exchanger includes: a cleaning ball input device 41 having an input unit 51 for inputting a cleaning ball to an intake pipe 44; a cleaning ball recovery device 42 having a recovery unit 52 for recovering the cleaning ball from a drain pipe 45; a control device 43 configured to operate the cleaning ball input device 41 and the cleaning ball recovery device 42. The control device 43 opens the recovery unit 52 only for a predetermined period after executing a cleaning ball recovery work with the cleaning ball recovery device 42, and starts a cleaning ball input work with the cleaning ball input device 41 after stopping the recovery unit 52.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a thin tube cleaning apparatus and method for a heat exchanger, and for example, in various power plants such as nuclear power and thermal power, the steam used in a steam turbine is cooled and condensed by heat exchange with cooling water and returned to water. It is suitable for application to a condenser.

  For example, there is a pressurized water reactor (PWR) as a nuclear power plant. This pressurized water reactor uses light water as a reactor coolant and neutron moderator, and makes it high-temperature and high-pressure water that does not boil throughout the primary system, and sends this high-temperature and high-pressure water to a steam generator to generate steam by heat exchange. The steam is sent to a turbine generator to generate electricity. At this time, the steam used for power generation by the turbine generator is cooled by the condenser to become condensed water, and is returned to the steam generator again.

  This condenser has a steam inlet at the top of the hollow housing, a water (condensate) outlet at the bottom, and an inlet water chamber at one side of the housing, An outlet water chamber is provided on the other side, and a large number of thin tubes through which cooling water flows are arranged so as to connect the inlet water chamber and the outlet water chamber. Therefore, the cooling water is constantly flowing in a large number of narrow tubes, and the steam that flows into the housing from the inflow port is subjected to heat exchange (cooling) with the cooling water to become condensed water, and the discharge port. Discharged from.

  In such a condenser, seawater is generally used as cooling water, and this seawater flows into the numerous thin tubes from the inlet water chamber and is discharged to the outlet water chamber. This seawater is inhabited by microorganisms such as shellfish and algae, and when seawater containing microorganisms flows into many tubules, these microorganisms adhere to the inner wall of the tubules and grow on shellfish and algae to block the tubules. There is a risk of letting you.

  As what solves such a problem, there exists a thing described in the following patent document 1, for example. In the condenser thin tube cleaning operation device described in Patent Document 1, during normal operation of the power plant, a cleaning ball is introduced into the condenser thin tube, and the condenser ball is attached to the condenser thin tube by the cleaning ball. Removes scales and seawater products.

JP 2009-052821 A

  In a conventional condenser thin tube cleaning device, a thin tube cleaning operation using a cleaning ball is periodically performed (for example, once a day). That is, a cleaning ball is placed on the upstream side of the condenser, and the cleaning ball is collected on the downstream side of the condenser. In this case, the cleaning balls are collected by a strainer provided on the downstream side of the condenser. Since this strainer is attached with dust contained in the seawater, conventionally, the strainer is opened before removing the thin tube to remove the attached dust. However, if all of the cleaning balls were not collected during the previous thin tube cleaning operation and some cleaning balls remained in the strainer, the cleaning balls would flow into the sea when the strainer was opened. End up.

  The present invention solves the above-described problems, and an object thereof is to provide a thin tube cleaning apparatus and method for a heat exchanger that suppresses the outflow of cleaning balls to the outside.

  In order to achieve the above object, a thin tube cleaning apparatus for a heat exchanger according to the present invention includes a housing provided with a steam inlet and a condensate outlet, and an inlet water chamber and outlet provided at each end of the housing. A water chamber, a plurality of thin tubes through which cooling water flows through the inlet water chamber and the outlet water chamber inside the housing, a water intake pipe connected to the inlet water chamber and the outlet water chamber, respectively In the heat exchanger having a drain pipe, a cleaning ball throwing device having a feeding section for feeding a cleaning ball into the intake pipe, and a cleaning ball collection having a collecting section for collecting the cleaning ball from the drain pipe And a control device for controlling the operation of the cleaning ball throwing device and the cleaning ball recovery device, and the control device performs the cleaning ball recovery operation by the cleaning ball recovery device. , In which a predetermined time period to open the recovery unit, starts a cleaning ball shooting operation by the cleaning ball throwing device after closing the collecting unit, characterized in that.

  Therefore, after the cleaning ball is collected, the recovery part is opened to remove the adhered foreign matter, so that even if the cleaning ball remains in the recovery part, the remaining cleaning ball is reliably recovered. After that, the collection unit is opened, and the outflow of the cleaning balls to the outside can be suppressed.

  In the thin tube cleaning device for a heat exchanger according to the present invention, the cleaning ball charging device and the cleaning ball recovery device include a ball circulation line for circulating the cleaning balls recovered by the recovery unit to the charging unit, and the ball And a ball circulation pump provided in the circulation line, wherein the control device stops the ball circulation pump when the recovery unit is opened.

  Accordingly, since the ball circulation pump is stopped when the recovery unit is opened, the cleaning ball is not circulated when the recovery unit is opened, and the outflow of the cleaning ball to the outside can be suppressed. .

  In the thin tube cleaning device for a heat exchanger according to the present invention, the control device operates the cleaning ball throwing device when a recovery unit closing confirmation signal is input after the recovery unit is closed.

  Therefore, after the collection unit is closed, the cleaning ball throwing device does not operate until the collection unit close confirmation signal is input, and the outflow of the cleaning ball to the outside can be reliably suppressed.

  In the thin tube cleaning apparatus for a heat exchanger according to the present invention, the recovery unit closing confirmation signal is a signal output by operating a recovery unit closing confirmation switch.

  Therefore, after the operator confirms the closed state of the recovery part, the recovery part close confirmation signal is output by operating the recovery part close confirmation switch, so that the outflow of the cleaning ball to the outside can be surely suppressed. .

  In the thin tube cleaning device for a heat exchanger according to the present invention, a differential pressure gauge for detecting a differential pressure between the upstream side and the downstream side in the recovery unit is provided, and the control device operates when the cleaning ball recovery device is in operation. An alarm is issued when the pressure exceeds a preset differential pressure.

  Therefore, when foreign matter adheres to the recovery unit, an alarm is issued when the differential pressure between the upstream side and the downstream side of the recovery unit exceeds a specified differential pressure, so that damage due to the attachment of foreign matter to the recovery unit can be suppressed. .

  In the thin tube cleaning apparatus for a heat exchanger according to the present invention, an open / close switch for opening and closing the recovery unit is provided, and after the differential pressure exceeds the specified differential pressure, the control unit receives a recovery unit open signal from the open / close switch. Is input, the collection unit is opened.

  Therefore, when an alarm is issued when the differential pressure between the upstream and downstream sides of the recovery unit exceeds the specified differential pressure, the operator operates the open / close switch to output a recovery unit open signal and open the recovery unit. It is possible to suppress breakage due to adhesion of foreign matter to the collection unit.

  In the heat exchanger thin tube cleaning device according to the present invention, the control device includes an automatic cleaning mode for operating the cleaning ball throwing device and the cleaning ball recovery device at a predetermined time set in advance, and a cleaning start signal. Is input, a manual cleaning mode for operating the cleaning ball throwing device and the cleaning ball collecting device is provided.

  Therefore, since the control device has an automatic cleaning mode and a manual cleaning mode, the operator can freely select this mode, and versatility can be improved.

  The method of cleaning a thin tube of a heat exchanger according to the present invention includes a housing provided with a steam inlet and a condensate outlet, an inlet water chamber and an outlet water chamber provided at each end of the housing, and the interior of the housing. And a plurality of thin tubes through which the cooling water flows through the inlet water chamber and the outlet water chamber, and a water intake pipe and a drain pipe respectively connected to the inlet water chamber and the outlet water chamber. A step of closing the recovery unit and recovering the cleaning ball from the drain pipe, a step of opening the recovery unit for a predetermined period when the cleaning ball recovery operation is completed, and the recovery unit after a predetermined time has elapsed. And a step of throwing a cleaning ball into the intake pipe from the throwing portion.

  Therefore, after the cleaning ball is collected, the recovery part is opened to remove the adhered foreign matter, so that even if the cleaning ball remains in the recovery part, the remaining cleaning ball is reliably recovered. After that, the collection unit is opened, and the outflow of the cleaning balls to the outside can be suppressed.

  According to the thin tube cleaning apparatus and method of the heat exchanger of the present invention, the recovery unit is opened after the cleaning ball recovery operation is performed. Therefore, the remaining cleaning balls are recovered and the cleaning balls are discharged to the outside. Outflow can be suppressed.

FIG. 1 is a schematic configuration diagram illustrating a condenser cleaning device for a condenser according to the present embodiment. FIG. 2 is a time chart showing a method for cleaning a condenser tube. FIG. 3 is a partially cutaway perspective view showing the overall configuration of the condenser.

  Exemplary embodiments of a heat exchanger thin tube cleaning apparatus and method according to the present invention will be explained below in detail with reference to the accompanying drawings. In addition, this invention is not limited by this embodiment, and when there are two or more embodiments, what comprises combining each embodiment is also included.

  The heat exchanger of the present embodiment is, for example, a condenser, which is applied to a nuclear power plant, and the nuclear power plant includes a pressurized water reactor and steam generation stored in a reactor containment vessel. It consists of a steam generator, a steam turbine, a generator, a condenser, and the like. The pressurized water reactor uses light water as the reactor coolant and neutron moderator, and generates high-temperature and high-pressure water that does not boil over the entire core, and sends this high-temperature and high-pressure water to a steam generator to generate steam by heat exchange. Is.

  The steam generator is connected to a steam turbine via a cooling water pipe, and the condenser is connected to the steam turbine. The condenser is provided with a water intake pipe and a drain pipe for circulating cooling water (for example, seawater) and is connected to the steam generator via the cooling water pipe. Therefore, the steam generated by the steam generator is sent to the steam turbine through the cooling water pipe, and the steam turbine is driven by the steam to generate power by the generator. The steam that has driven the steam turbine is cooled using seawater in the condenser to become condensed water, and is returned to the steam generator through the cooling water pipe.

  Here, the condenser of this embodiment will be described. FIG. 3 is a partially cutaway perspective view showing the overall configuration of the condenser.

  As shown in FIG. 3, the condenser 10 includes a housing 11, inlet water chambers 12 and 13, outlet water chambers 14 and 15, and heat transfer tube groups 16 and 17.

  The housing 11 is box-shaped and has a hollow shape with a truncated pyramid at the top. A steam inlet 21 through which used steam flows is formed at the top, and the steam is condensed at the bottom. A condensate drain 22 for discharging water (condensate) is formed.

  As for the housing 11, the tube plates 23 and 24 are being fixed to each edge part in the longitudinal direction (horizontal direction). The inlet water chamber 12 and the outlet water chamber 15 are fixed adjacent to one tube plate 24 in the horizontal direction, and the outlet water chamber 14 and the inlet water chamber 13 are fixed adjacent to the other tube plate 23. . Here, the inlet water chamber 12 and the outlet water chamber 14 are disposed at positions that are horizontally opposed via the housing 11, and the inlet water chamber 13 and the outlet water chamber 15 are horizontally opposed via the housing 11. Placed in position. The inlet water chambers 12 and 13 are provided with inlet nozzles 25 and 26 at the lower part, and the outlet water chambers 14 and 15 are provided with outlet nozzles 27 and 28 (see FIG. 3) at the lower part.

  The inlet water chamber 12 and the outlet water chamber 14 are connected by a heat transfer tube group 16 in the housing 11, and the inlet water chamber 13 and the outlet water chamber 15 are connected by a heat transfer tube group 17 in the housing 11. The heat transfer tube group 16 is composed of a plurality of heat transfer tubes (thin tubes) 31, arranged inside the housing 11, supported so that one end portion penetrates the tube plate 23, and the other end portion penetrates the tube plate 24. So that it is supported. Therefore, the inlet water chamber 12 and the outlet water chamber 14 are communicated with each other by a plurality of heat transfer tubes 31. The heat transfer tube group 17 includes a plurality of heat transfer tubes 32, is disposed inside the housing 11, is supported so that one end portion penetrates the tube plate 23, and the other end portion penetrates the tube plate 24. It is supported by. Therefore, the inlet water chamber 13 and the outlet water chamber 15 communicate with each other through a plurality of heat transfer tubes 32.

  Moreover, the housing 11 has a plurality of tube support plates 33 and 34 arranged therein at predetermined intervals in the longitudinal direction of the heat transfer tubes 31 and 32. The lower portion of the tube support plate 33 is supported on the bottom portion of the housing 11 by the support member 35, and the lower portion of the tube support plate 34 is supported on the bottom portion and the side portion of the housing 11 by a support member (not shown). The intermediate portion of the heat transfer tube 31 is supported through the tube support plates 33, and the intermediate portion of the heat transfer tube 32 is supported through the tube support plates 34.

  Therefore, the steam S enters the housing 11 from the steam inlet 21, flows downward in the housing 11 in the vertical direction, and is discharged as condensate W from the condensate drain port 22. On the other hand, seawater C as cooling water is introduced into the inlet water chambers 12 and 13 from the inlet nozzles 25 and 26, flows along the heat transfer tubes 31 and 32 in the horizontal direction, and flows into the outlet water chambers 14 and 15. The gas is discharged from the outlet nozzles 27 and 28. Here, since the steam S flows vertically in the housing 11 and the seawater C flows horizontally in the heat transfer tubes 31 and 32, the flow of the steam S and the flow of the seawater C intersect without mixing. Then, heat exchange is performed. That is, the steam S is cooled by the seawater C flowing through the heat transfer tubes 31 and 32 and falls into the housing 11 as condensate W.

  Here, the condenser cleaning apparatus and method of the condenser of this embodiment will be described in detail. FIG. 1 is a schematic configuration diagram illustrating a condenser thin tube cleaning apparatus according to the present embodiment, and FIG. 2 is a time chart illustrating a condenser thin tube cleaning method.

  In the present embodiment, as shown in FIG. 1, the condenser thin tube cleaning device 40 includes a cleaning ball throwing device 41, a cleaning ball collection device 42, and a control device 43. As described above, the condenser 10 is provided with the inlet water chamber 12 (13) and the outlet water chamber 14 (15) on both sides of the housing 11, and the inlet water chamber 12 and the outlet water chamber 14 are connected to the housing 11. It is connected by a heat transfer tube group 16 (heat transfer tube 31). A water intake pipe 44 is connected to the inlet nozzle 25, and a drain pipe 45 is connected to the outlet nozzle 27. The intake water chamber 13 and the outlet water chamber 15 are also connected with a water intake pipe and a drain pipe, and a thin tube cleaning device 40 is connected.

  The cleaning ball throwing device 41 has a throwing portion 51 for throwing a cleaning ball into the intake pipe 44 of the condenser 10. The cleaning ball collection device 42 includes a collection unit 52 that collects the cleaning balls from the drain pipe 45 of the condenser 10. The control device 43 can control the operation of the cleaning ball throwing device 41 and the cleaning ball collecting device 42.

  The charging portion 51 of the cleaning ball charging device 41 has a charging pipe 53 attached through the water intake pipe 44 on the left and right sides of the water intake pipe 44 in the horizontal direction. The ball throwing line 54 has a base end connected to a ball throwing / collecting device 55 and a tip connected to each throwing pipe 53 via a branch line 56, and a ball throwing source valve 57 is provided on the branch line 56. ing.

  On the other hand, the recovery part 52 of the cleaning ball recovery device 42 has a strainer 58 provided opposite to the left and right sides of the drain pipe 45 in the horizontal direction. The strainer 58 is closed by the drive device 59 (FIG. 1). (Solid line position) and an open position (two-dot chain line position in FIG. 1). The collection unit 52 includes a collection pipe 60 that is attached to the drain pipe 45 through the drain pipe 45 on the left and right sides in the horizontal direction and on the downstream side of the strainer 58. The ball recovery line 61 has a base end portion connected to each recovery pipe 60 via a branch line 62, a ball recovery source valve 63 provided on the branch line 62, and a tip end portion connected to a ball throwing / collecting device 55. ing.

  In this embodiment, the cleaning ball throwing device 41 and the cleaning ball collecting device 42 have a ball circulation line for circulating the cleaning balls collected by the collecting unit 52 to the throwing unit 51. The circulation line includes a ball throw-in line 54 (branch line 56) and a ball collection line 61 (branch line 62).

  The ball throwing and collecting device 55 is provided with a ball discharge portion 72 and a ball inflow portion 73 with respect to the collection container 71. The ball discharge unit 72 is provided with a ball throw-in / collector switching valve 74, the base end of the ball throw-in line 54 is connected, and the ball throw-in / collector outlet valve 75 is provided in the ball throw-in line 54.

  The ball collection line 61 is provided with a ball circulation pump 76 in the middle. The ball recovery line 61 is connected to a ball separator 77 at the tip end downstream of the ball circulation pump 76, and a ball circulation pump outlet valve 78 is provided upstream of the ball separator 77. A first recovery line 79 extending from the ball separator 77 is connected to the ball inflow portion 73, and a second recovery line 80 is connected to the ball discharge portion 72 (ball input recovery device switching valve 74) in the ball input line 54. It is connected between the collector outlet valve 75.

  The ball circulation pump 76 circulates the cleaning balls on the ball recovery line 61 and feeds the cleaning balls recovered by the recovery unit 52 to the ball throwing and collecting device 55 side. The ball circulation pump 76 is provided with a seal water supply line 81 for supplying seal water, and a ball circulation pump seal water source valve 82 is provided in the seal water supply line 81.

  The control device 43 can open and close the strainer 58 of the collection unit 52 by controlling the drive device 59. Further, the ball throwing / collecting device switching valve 74, the ball throwing / collecting device outlet valve 75, the ball circulation pump 76, the ball circulation pump outlet valve 78, and the ball circulation pump seal water source valve 82 are electromagnetic valves, and the control device 43 includes: Each valve 74, 75, 76, 78, 82 can be controlled to open and close. Further, the control device 43 can switch the communication destination of the ball collection line 61 between the first collection line 79 and the second collection line 80 by switching the ball separator 77.

  The condenser thin tube cleaning apparatus configured as described above periodically cleans the heat transfer tube 31 (32) with a cleaning ball (for example, once a day). At this time, the strainer 58 of the recovery unit 52 recovers the cleaning ball that has been input from the input unit 51 and cleaned the heat transfer tube 31. Since the strainer 58 has a mesh shape, foreign matter such as dust contained in seawater adheres thereto. Therefore, the adhered foreign matter is removed by opening the strainer 58 between cleaning operations of the heat transfer tube 31 (32) with the cleaning balls. However, if the cleaning balls cannot be recovered and a part of them remains in the strainer 58 during the previous cleaning operation of the heat transfer tube 31, when the strainer 58 is opened, the cleaning balls flow out into the sea. .

  For this reason, in this embodiment, the control device 43 opens the strainer 58 of the recovery unit 52 for a predetermined period after the cleaning ball recovery operation by the cleaning ball recovery device 42 and closes the strainer 58. The cleaning ball charging operation by the cleaning ball charging device 41 is started. The control device 43 stops the ball circulation pump 76 when the strainer 58 of the collection unit 52 is opened.

  Further, the control device 43 opens the strainer 58 of the collecting unit 52 for a predetermined time and then closes the strainer 58. At this time, when the collecting unit closing confirmation signal is input, the cleaning ball throwing device 41 is turned on. Operate. A recovery unit closing confirmation switch 91 operable by an operator is provided, and the recovery unit closing confirmation signal is a signal output to the control device 43 when the operator operates (turns on) the recovery unit closing confirmation switch 91. It is.

  The recovery unit 52 is provided with pressure gauges 92 and 93 on the upstream side and downstream side of the strainer 58, and a differential pressure gauge 94 that detects the differential pressure between the upstream side and the downstream side from the measured values of the pressures 92 and 93. The detection result (differential pressure) is output to the control device 43. The control device 43 is connected to an alarm device 95. If the differential pressure between the upstream side and the downstream side of the strainer 58 exceeds a predetermined differential pressure during the operation of the cleaning ball collection device 42, the alarm device A warning is issued by 95.

  A manual opening / closing switch 96 for opening / closing the strainer 58 of the collecting unit 52 is provided. After the controller 43 issues an alarm by the alarm device 95, when the operator operates (turns on) the opening / closing switch 96, the opening / closing switch 96 The collection unit opening signal is input to the control device 43, and the control device 43 opens the strainer 58 based on the collection unit opening signal.

  The controller 43 is connected to a cleaning mode changeover switch 97. When a predetermined time (time) set in advance is reached, an automatic cleaning mode in which the cleaning ball throwing device 41 and the cleaning ball collection device 42 are operated, and when a cleaning start signal is input, the cleaning ball throwing device 41 and the cleaning ball A manual cleaning mode for operating the ball collection device 42. The operator can switch between the automatic cleaning mode and the manual cleaning mode by operating the cleaning mode changeover switch 97.

  Here, the thin tube cleaning operation by the thin tube cleaning device of the condenser of this embodiment will be described in detail.

  In the condenser thin tube cleaning method of the present embodiment, the recovery unit 52 is closed and the cleaning ball is recovered from the drain pipe 45, and when the cleaning ball recovery operation is completed, the recovery unit 52 is opened for a predetermined period. And a step of closing the collection unit 52 after a predetermined time has elapsed and introducing a cleaning ball into the water intake pipe 44 from the input unit 51.

  In the condenser 10, when the inner surfaces of the inlet water chamber 12, the heat transfer pipe 16, the outlet water chamber 14, and the like are contaminated with shellfish or the like, or dirt, the adhered matter is removed using a cleaning ball. Perform cleaning operations. That is, as shown in FIGS. 1 and 2, at time t1, the control device 43 receives the cleaning start signal S1 in the automatic cleaning mode or the cleaning start signal S2 by the operator's operation in the manual cleaning mode. Then, the cleaning operation of the condenser 10 is started.

  The controller 43 operates the ball separator 77 at time t2, switches the ball collection line 61 to the first collection line 79, and opens the ball circulation pump seal water source valve 82 at time t3. Subsequently, the control device 43 operates (ON) the ball circulation pump 76 at time t4, and opens the ball circulation pump outlet valve 78 at time t5. Then, the operation of the ball circulation pump 76 generates a flow from the collecting unit 52 side to the ball throwing and collecting unit 55 side with respect to the ball collecting line 61. Therefore, if a cleaning ball remains on the strainer 58 in the recovery unit 52, the cleaning ball passes through the branch line 62, the ball recovery line 61, and the first recovery line 79 together with the seawater and is recovered by the ball throwing and collecting unit 55. It is collected in the container 71. At this time, since the ball insertion / collection device switching valve 74 of the ball insertion / recovery device 55 is closed, the cleaning balls are not sent out from the collection container 71 to the ball insertion line 54.

  Then, when the predetermined time has elapsed, the control device 43 closes the ball circulation pump outlet valve 78 at time t6, closes the ball circulation pump seal water source valve 82 at time t7, and ball circulation pump 76. Is stopped (OFF). Thereafter, the control device 43 operates the ball separator 77 at time t8 to switch the ball collection line 61 to the second collection line 80. In this case, the predetermined time is a time until the cleaning balls remaining in the strainer 58 are collected in the recovery unit 52 and recovered to the recovery container 71, and are the opening time of the ball circulation pump outlet valve 78. . This predetermined time is set in advance by experiments or the like.

  When the ball collection line 61 is completely switched to the second collection line 80 at time t9, the control device 43 opens the strainer 58 of the collection unit 52 at time t10, and at time t12 when a predetermined time has elapsed. Then, the strainer 58 is closed. Then, the strainer 58 is completely opened from time t11 to time t12, and the adhering foreign matter is removed by the flow of seawater.

  When the strainer 58 is closed at time t13, the operator visually confirms that the strainer 58 is closed. When the operator confirms that the strainer 58 is closed, the operator operates (turns on) the recovery unit close confirmation switch 91 and outputs a recovery unit close confirmation signal S3 to the control device 43. When this recovery unit closing confirmation signal S3 is input at time t14, the control device 43 opens the ball circulation pump seal water source valve 82 and operates (ON) the ball circulation pump 76 at time t15. At the same time, the ball circulation pump outlet valve 78 is opened. Further, the control device 43 operates the ball separator 77 at time t16 to switch the ball collection line 61 to the first collection line 79, and opens the ball throw-in / collector switching valve 74 at time t17.

  Then, by the operation of the ball circulation pump 76, a flow from the recovery unit 52 side to the input unit 51 side is generated from the ball recovery line 61 through the ball input recovery device 55 to the ball input line 54. Therefore, the cleaning balls of the collection container 71 are fed to the charging unit 51 through the ball charging line 54 and are charged from the charging pipes 53 to the water intake pipe 44 of the condenser 10. The cleaning balls introduced into the intake pipes 44 are introduced from the intake pipes 44 to the heat transfer pipes 31 through the inlet water chambers 12, and the cleaning balls pass through the heat transfer pipes 31 to adhere to the inner surface. Foreign matter is removed.

  The cleaning balls that have passed through the heat transfer tubes 31 are discharged from the outlet water chamber 14 to the drain tube 45. The recovery unit 52 recovers the cleaning balls flowing through the water intake pipe 45 by the strainer 58, and the cleaning balls flow into the ball recovery line 61 from the branch line 62 from each recovery pipe 60. Then, the cleaning balls in the ball collection line 61 are collected in the collection container 71 of the ball throwing and collecting unit 55 through the first collection line 79.

  The controller 43 operates the ball separator 77 to switch the ball collection line 61 to the second collection line 80 at time t19. Then, at time t21, when either the cleaning time timer signal S4, the operator's forced stop switch ON signal S5, or the cleaning ball count signal S6 is input, the control device 43 receives the ball throwing and collecting device. The switching valve 74 is closed, and the ball separator 77 is operated at time t22 to switch the ball collection line 61 to the first collection line 79.

  Thereafter, at time t24, when either the timer signal S7 indicating the end of the cleaning time or the final count signal S8 of the cleaning balls is input, the control device 43 sets the ball throwing / collecting device outlet valve 75 to the water-containing state, At t27, the ball separator 77 is operated to switch the ball collection line 61 to the second collection line 80. Thereafter, the control device 43 closes the ball circulation pump outlet valve 78 at time t23, closes the ball circulation pump seal water source valve 82 at time t29, and stops the operation of the ball circulation pump 76 (OFF). Then, at time t30, the cleaning operation of the condenser 10 is completed.

  As described above, in the condenser thin tube cleaning device of this embodiment, the cleaning ball charging device 41 having the charging portion 51 for charging the cleaning ball into the water intake tube 44 and the cleaning ball from the drain tube 45 are supplied. A cleaning ball recovery device 42 having a recovery unit 52 for recovery, and a control device 43 for controlling the operation of the cleaning ball throwing device 41 and the cleaning ball recovery device 42 are provided. The control device 43 is provided with a cleaning ball recovery device 42. After carrying out the cleaning ball collecting operation by, the collecting unit 52 is opened only for a predetermined period, and after the collecting unit 52 is closed, the washing ball throwing operation by the washing ball throwing device 41 is started.

  Therefore, after the cleaning ball collecting operation is performed, the collecting unit 52 can be opened to remove the adhered foreign matter. Therefore, even if the cleaning ball remains in the recovery unit 52, the recovery ball 52 is opened after the remaining cleaning ball is reliably recovered, and the outflow of the cleaning ball to the outside is suppressed. can do.

  In the condenser thin tube cleaning device of this embodiment, the cleaning ball throwing device 41 and the cleaning ball collecting device 42 are balls as a ball circulation line for circulating the cleaning balls collected by the collecting unit 52 to the throwing unit 51. The control unit 43 has a throw-in line 54 and a ball collection line 61 (branch line 62) and a ball circulation pump 76 provided in the ball collection line 61, and the controller 43 stops the ball circulation pump 76 when the collection unit 52 is opened. . Accordingly, since the ball circulation pump 76 is stopped when the recovery unit 52 is opened, the cleaning ball is not circulated when the recovery unit 52 is opened, and the outflow of the cleaning ball to the outside is suppressed. be able to.

  In the condenser thin tube cleaning device of the present embodiment, the control device 43 operates the cleaning ball throwing device 41 when the recovery portion closing confirmation signal is input after the recovery portion 52 is closed. Therefore, after the collection unit 52 is closed, the cleaning ball throwing device 41 does not operate until the collection unit close confirmation signal is input, and the outflow of the cleaning ball to the outside can be reliably suppressed.

  In the condenser thin tube cleaning device of this embodiment, the recovery unit closing confirmation signal is a signal output by operating the recovery unit closing confirmation switch 91. Therefore, after the operator confirms the closed state of the recovery part 52, the recovery part close confirmation signal is output by operating the recovery part close confirmation switch 91, thereby reliably suppressing the outflow of the cleaning balls to the outside. Can do.

  In the condenser thin tube cleaning device of the present embodiment, a differential pressure gauge 94 for detecting the differential pressure between the upstream side and the downstream side in the recovery unit 52 is provided, and the control device 43 is operated when the cleaning ball recovery device 42 is in operation. An alarm is issued when the differential pressure exceeds the specified differential pressure. Therefore, if foreign matter adheres to the recovery unit 52, an alarm is issued when the differential pressure between the upstream side and the downstream side of the recovery unit 52 exceeds a specified differential pressure, thereby preventing damage due to the foreign matter adhering to the recovery unit 52. be able to.

  In the condenser thin tube cleaning device of the present embodiment, an open / close switch 96 for opening and closing the recovery unit 52 is provided, and the control device 43 receives a recovery unit opening signal from the open / close switch 96 after the differential pressure exceeds a specified differential pressure. Is input, the collection unit 52 is opened. Accordingly, when an alarm is issued when the differential pressure between the upstream side and the downstream side in the recovery unit 52 exceeds the specified differential pressure, the operator operates the open / close switch 96 to output a recovery unit open signal and collect the recovery unit. 52 can be opened, and damage due to foreign matter adhering to the collection unit 52 can be suppressed.

  In the condenser thin tube cleaning device of the present embodiment, the control device 43 has an automatic cleaning mode and a manual cleaning mode, and can be switched by a cleaning mode changeover switch 97. Therefore, the operator can freely select this mode, and versatility can be improved.

  In the condenser thin tube cleaning method of the present embodiment, the recovery unit 52 is closed and the cleaning balls are recovered from the drain pipe 45, and the recovery is completed for a predetermined period after the cleaning ball recovery operation is completed. A step of opening the portion 52, and a step of closing the collection portion 52 after a predetermined time has elapsed and putting the cleaning ball into the water intake pipe 44 from the input portion 51.

  Therefore, after the cleaning ball is collected, the recovery unit 52 is opened to remove the adhered foreign matter, so that even if the cleaning ball remains in the recovery unit 52, the remaining cleaning ball can be surely retained. Then, the recovery unit 52 is opened, and the outflow of the cleaning balls to the outside can be suppressed.

  In the above-described embodiment, the heat exchanger of the present invention has been described as being applied as a condenser of a nuclear power plant having a pressurized water reactor, but is applied to a condenser in another type of nuclear reactor. You can also. Moreover, you may apply as condensers, such as not only a nuclear power plant but a thermal power plant and a geothermal power plant. Furthermore, you may apply the heat exchanger of this invention not only to a condenser but to a heat exchanger which has a some thin tube in a fuselage | body by a fuel cell, a cogeneration plant, etc.

10 Condenser (heat exchanger)
11 Housing 12, 13 Inlet water chamber 14, 15 Outlet water chamber 16, 17 Heat transfer tube group 21 Steam inlet 22 Condensate outlet 23, 24 Tube plate 25, 26 Inlet nozzle 27, 28 Outlet nozzle 31, 32 Heat transfer tube 33 , 34 Tube support plate 35 Support member 40 Thin tube cleaning device 41 Cleaning ball throwing device 42 Cleaning ball collecting device 43 Control device 44 Water intake pipe 45 Drain pipe 51 Input portion 52 Recovery portion 53 Input tube 54 Ball input line 55 Ball input recovery Device 56 Branch line 57 Ball throwing source valve 58 Strainer 59 Drive device 60 Recovery pipe 61 Ball recovery line 62 Branch line 63 Ball recovery source valve 71 Recovery container 72 Ball discharge part 73 Ball inflow part 74 Ball input recovery switch valve 75 Ball input Collector outlet valve 76 Ball circulation pump 77 Ball separator 78 Ball circulation pump outlet valve 79 First recovery line 80 Second recovery line 81 Seal water supply line 82 Ball circulation pump seal water source valve 91 Recovery section closing confirmation switch 92, 93 Pressure gauge 94 Differential pressure gauge 95 Alarm 96 Open / close switch 97 Cleaning mode selector switch S Steam C Seawater W Condensate

Claims (8)

A housing provided with a steam inlet and a condensate outlet;
An inlet water chamber and an outlet water chamber provided at each end of the housing;
A large number of thin tubes in which the inlet water chamber and the outlet water chamber communicate with each other and the cooling water flows inside the housing;
An intake pipe and a drain pipe respectively connected to the inlet water chamber and the outlet water chamber;
In a heat exchanger having
A cleaning ball throwing device having a throwing portion for throwing the cleaning ball into the intake pipe;
A cleaning ball recovery device having a recovery unit for recovering the cleaning balls from the drain pipe;
A control device for controlling the operation of the cleaning ball throwing device and the cleaning ball collecting device;
Have
The control device opens the recovery unit for a predetermined period after the cleaning ball recovery operation by the cleaning ball recovery device, closes the recovery unit, and then inputs the cleaning ball by the cleaning ball input device. Start work,
A thin tube cleaning device for a heat exchanger.   The cleaning ball throwing device and the cleaning ball collecting device have a ball circulation line for circulating the cleaning balls collected by the collecting unit to the throwing unit, and a ball circulation pump provided in the ball circulation line. 2. The heat exchanger thin tube cleaning apparatus according to claim 1, wherein the controller stops the ball circulation pump when the recovery unit is opened. 3.   3. The heat exchanger according to claim 1, wherein the controller activates the cleaning ball charging device when a recovery unit closing confirmation signal is input after the recovery unit is closed. 4. Tube cleaning equipment.   The thin tube cleaning apparatus for a heat exchanger according to claim 3, wherein the recovery unit closing confirmation signal is a signal output by operating a recovery unit closing confirmation switch.   A differential pressure gauge that detects a differential pressure between the upstream side and the downstream side in the recovery unit is provided, and the control device, when the cleaning ball recovery device is operated, when the differential pressure exceeds a preset specified differential pressure The thin tube cleaning device for a heat exchanger according to any one of claims 1 to 4, wherein an alarm is issued.   An open / close switch for opening and closing the recovery unit is provided, and the control device opens the recovery unit when a recovery unit release signal is input from the open / close switch after the differential pressure exceeds the specified differential pressure. The thin tube cleaning apparatus for a heat exchanger according to claim 5.   The control device includes an automatic cleaning mode for operating the cleaning ball throwing device and the cleaning ball collecting device when a predetermined time is set in advance, and the cleaning ball throwing device and the cleaning start signal when a cleaning start signal is input. The thin tube cleaning device for a heat exchanger according to any one of claims 1 to 6, further comprising a manual cleaning mode for operating the cleaning ball collection device. A housing provided with a steam inlet and a condensate outlet;
An inlet water chamber and an outlet water chamber provided at each end of the housing;
A large number of thin tubes in which the inlet water chamber and the outlet water chamber communicate with each other and the cooling water flows inside the housing;
An intake pipe and a drain pipe respectively connected to the inlet water chamber and the outlet water chamber;
In a heat exchanger having
Closing the collection part and collecting the cleaning balls from the drain pipe;
A step of opening the recovery unit only for a predetermined period when the cleaning ball recovery operation is completed;
Closing the recovery unit after a predetermined time has elapsed, and introducing a cleaning ball into the intake pipe from the input unit;
A method for cleaning a thin tube of a heat exchanger, comprising:

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