JP6156091B2 - Heat exchanger manufacturing method and heat exchanger manufacturing apparatus - Google Patents

Description

The present invention relates to a process for producing a heat exchanger, and to a related apparatus for producing a heat exchanger.

  Conventionally, in an in-vehicle heat exchanger, surface treatment is performed by a method of coating a film on the surface of the heat exchanger in order to provide functions such as rust prevention, antibacterial, odor resistance, and hydrophilicity ( (See Patent Documents 1 and 2).

  In general, as the surface treatment, a treatment is performed by applying a chemical conversion reaction to form a film or applying and baking a resin-based paint on the surface. Such treatment is performed using a liquid treatment agent. In order to adapt to various product shapes, after being immersed in a treatment tank that stores the treatment agent, excess treatment agent is removed by air blow or the like. The method of controlling the adhesion amount of the processing agent in the heat exchanger is taken.

JP 2005-321166 A Japanese Patent No. 4990413

  The heat exchanger treated using the above method is immersed in the treatment tank in which the treatment agent is stored, so that the treatment agent is attached to all surfaces, but the above function is necessary for heat exchange. It is only a heat exchange core part comprised of the fin and tube which express a function. For this reason, the amount of the processing agent used is increased by attaching the processing agent to a portion such as a tank portion where the above function is unnecessary. For this reason, there exists a problem that manufacturing cost becomes high.

In view of the above points, the present invention provides a heat exchanger manufacturing method and a heat exchanger for suppressing the surface treatment liquid from adhering to a portion other than the heat exchange core portion of the heat exchanger. An object is to provide a manufacturing apparatus.

In order to achieve the above object, according to the first aspect of the present invention, in the heat exchanger manufacturing method, the heat exchange core (8) in which a plurality of tubes are arranged in parallel is connected to the first and second tanks (3). First, the surface treatment liquid is discharged from the outlet of the nozzle (50) from one side in a predetermined direction to the heat exchanger (10) disposed between 4, 5, 6). Comprising a step (110),
The predetermined direction is a direction orthogonal to the direction in which the plurality of tubes are arranged and orthogonal to the longitudinal direction of the plurality of tubes, and the predetermined direction is between two adjacent tubes of the plurality of tubes. At least one or more air passages (9) are provided therethrough,
A second step (110) of sucking excess of the processing liquid through the air passage from the other side in the predetermined direction with respect to the heat exchange core;
By simultaneously performing the first and second steps, the treatment liquid is attached to the surface of the heat exchange core,
In the second step, excess processing liquid is recovered in the liquid recovery tank by sucking the processing liquid into the liquid recovery tank (30) from the other side of the predetermined direction with respect to the heat exchange core,
In the first step, the processing liquid in the liquid recovery tank is circulated toward the inlet of the nozzle, and the processing liquid is discharged from the outlet of the nozzle.
A third step (120) for sucking the treatment liquid adhering to the heat exchange core of the heat exchanger that has been subjected to the first and second steps;
In the third step, the processing liquid in the heat exchange core is sucked into the liquid recovery tank, and the sucked processing liquid is recovered in the liquid recovery tank.
In the second and third steps, the treatment liquid is sucked into the liquid recovery tank from the heat exchange core by the suction force of the suction pump (42), and the first control device (60) sucks the suction force of the suction pump. By controlling the amount of the treatment liquid adhering to the heat exchange core .

  As described above, the treatment liquid is adhered to the surface of the heat exchange core by simultaneously performing the first and second steps. Therefore, the manufacturing method of the heat exchanger which suppresses that a process liquid adheres to tank parts other than a heat exchange core among heat exchangers can be provided.

In the invention according to claim 7, the heat exchange core (8) in which a plurality of tubes are arranged in parallel is arranged between the first and second tanks (3, 4, 5, 6). The exchanger (10) includes a nozzle (50) for discharging a treatment liquid for surface treatment from one side of the predetermined direction,
The predetermined direction is a direction orthogonal to the direction in which the plurality of tubes are arranged and orthogonal to the longitudinal direction of the plurality of tubes, and the predetermined direction is between two adjacent tubes of the plurality of tubes. At least one or more air passages (9) are provided therethrough,
A pump (40) for circulating the processing liquid toward the inlet of the nozzle and discharging the processing liquid from the outlet of the nozzle;
A suction pump (42) for generating a suction force for sucking excess processing liquid through the air passage from the other side of the predetermined direction with respect to the heat exchange core,
By allowing the processing liquid to be discharged from the outlet of the nozzle by the pressure pump and simultaneously generating the suction force by the suction pump, the processing liquid is attached to the surface of the heat exchange core ,
A liquid recovery tank (30) for recovering the processing liquid sucked by the suction pump from the heat exchange core,
The pressure feed pump causes the processing liquid in the liquid recovery tank to flow toward the inlet of the nozzle and discharge the processing liquid from the outlet of the nozzle.
The heat exchanger is adapted to be conveyed so as to pass the other side of the predetermined direction with respect to the nozzle,
Detection means (61) for detecting that the heat exchange core is located on the other side in a predetermined direction with respect to the nozzle;
When the detection means detects that the heat exchange core is located on the other side of the nozzle in the predetermined direction, the processing liquid from the nozzle is heated by controlling the pressure feed pump so that the processing liquid is discharged from the outlet of the nozzle. A second control device (60) attached to only the heat exchange core of the exchanger;
It is characterized by providing.

  As described above, the processing liquid is adhered to the surface of the heat exchange core by simultaneously discharging the processing liquid from the nozzle by the pressure feed pump and generating the suction force by the suction pump. Therefore, the manufacturing apparatus of the heat exchanger which suppresses that a process liquid adheres to tank parts other than a heat exchange core among heat exchangers can be provided.

  In addition, the code | symbol in the bracket | parenthesis of each means described in this column and the claim shows the correspondence with the specific means as described in embodiment mentioned later.

It is a figure which shows the manufacturing process of the heat exchanger in one Embodiment of this invention. It is a perspective view which shows the heat exchanger in the said embodiment. It is an enlarged view of A part in FIG. It is a figure which shows the manufacturing apparatus used at the manufacturing process of FIG. It is a figure which shows the dimension of the pallet etc. which are used in the manufacturing process of FIG. It is a flowchart which shows the control processing of the manufacturing apparatus used with the manufacturing process of FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, parts that are the same or equivalent to each other are given the same reference numerals in the drawings in order to simplify the description.

(First embodiment)
FIG. 1 shows an embodiment of a method for manufacturing an evaporator 10 according to the present embodiment according to the present invention. FIG. 1 is a flowchart showing steps of a method for manufacturing the evaporator 10.

  Here, prior to the description of the method for manufacturing the evaporator 10, the schematic structure of the evaporator 10 will be described.

  The evaporator 10 is a cooling heat exchanger for an in-vehicle air conditioner, and constitutes a well-known refrigeration cycle apparatus together with an expansion valve, a compressor, and the like.

  As shown in FIG. 2, the evaporator 10 is provided with a connection block 1, and the connection block 1 is directed toward a refrigerant inlet 1 a into which refrigerant flowing out from an expansion valve (not shown) enters and a compressor (not shown). A refrigerant outlet 1b that flows out is provided.

  Each of the evaporators 10 includes a plurality of tubes 2 arranged in parallel, and the plurality of tubes 2 are arranged in two rows in one direction orthogonal to the air flow direction X.

  Specifically, the tubes 2 are arranged in parallel in one direction on the upstream side of the air, and the tubes 2 are arranged in parallel in one direction on the downstream side of the air. The direction in which the tubes 2 on the air upstream side are arranged and the direction in which the tubes 2 on the air downstream side are arranged are the same direction. The air flow direction X corresponds to a predetermined direction of the present invention, and is a direction in which air passing through the plurality of air passages 9 (see FIG. 3) of the completed evaporator 10 flows. Each tube 2 on the upstream side of the air is hidden by each tube 2 on the downstream side of the air.

  The evaporator 10 includes tank portions 3, 4, 5, and 6. The tank portion 3 is joined to one end side in the longitudinal direction of each tube 2 on the downstream side of the air, and the tank portion 3 is connected to the refrigerant inlet 8a. The refrigerant flowing in from each is distributed to each tube 2. The tank unit 4 is joined to the other end side in the longitudinal direction of each tube 2 on the downstream side of the air, and the tank unit 4 collects refrigerant from each tube 2.

  The tank unit 5 is joined to the other end side in the longitudinal direction of each tube 2 on the air upstream side, and the tank unit 5 distributes the refrigerant collected in the tank unit 4 to each tube 2 on the air upstream side. The tank unit 6 is joined to the other end side in the longitudinal direction of each tube 2 on the upstream side of the air, and the tank unit 6 collects refrigerant from each tube 2 on the upstream side of the air. The refrigerant collected in the tank unit 6 is discharged from the refrigerant outlet 1b.

  FIG. 3 shows an enlarged view of a portion A in FIG. An air passage 9 is formed between two adjacent tubes 2 among the tubes 2 on the air upstream side. An air passage 9 penetrating in the air flow direction X is formed between two adjacent tubes 2 among the tubes 2 on the downstream side of the air.

  The air passage 9 on the upstream side of the air and the air passage 9 on the downstream side of the air are configured to penetrate in the air flow direction X. The air flow direction X is a direction orthogonal to the direction in which the tubes 2 on the upstream side of the air (or the tubes 2 on the downstream side of the air) are arranged, and orthogonal to the longitudinal direction of the tubes 2.

  Fins 7 are provided in the air passage 9 on the upstream side and the air passage 9 on the downstream side, respectively. The fin 7 is joined to the surface of the tube 2 to promote heat exchange between the refrigerant in the tube 2 and the air. In the present embodiment, corrugated fins that are formed in a wave shape are used as the fins 7.

  The fins 7 and the plurality of tubes 2 constitute the heat exchange core 8 and are disposed between the tank portions 3 and 6 and the tank portions 4 and 5. The heat exchange core 8 is formed in a flat shape by the fins 7 and the plurality of tubes 2. The heat exchange core 8 exchanges heat between the air passing through the plurality of air passages 9 and the refrigerant in the plurality of tubes 2.

  A resin film having a uniform thickness is formed on the surface of the heat exchange core 8 configured as described above, and the resin film serves to perform functions such as rust prevention, antibacterial properties, odor resistance, and hydrophilicity. It is a processing liquid. The connection block 1, the plurality of tubes 2, the tank portions 3, 4, 5, 6 and the fins 7 are made of an aluminum alloy.

  Next, the process of the manufacturing method of the evaporator 10 of this embodiment is demonstrated with reference to FIG.

  First, the connection block 1, the plurality of tubes 2, the tank portions 3, 4, 5, 6, and the fins 7 are temporarily assembled and then brazed and integrated (step 100). Hereinafter, this integrated intermediate product (that is, the evaporator 10 before completion) is referred to as a workpiece 10A.

  In the next step 110, a resin liquid (that is, a surface treatment liquid) is adhered to the heat exchange core 8 of the workpiece 10A. In the next step 120, excess resin liquid adhering to the heat exchange core 8 is sucked. The details of the adhering step (step 110) for adhering the resin liquid to the heat exchange core 8 and the suction step (step 120) for sucking excess resin liquid will be described later.

  In the next step 130, the resin liquid adhering to the workpiece 10A is dried. Thereafter, in the next step 140, the workpiece 10A is heated. For this reason, a resin liquid bridge | crosslinks in the surface of the heat exchange core 8 among the workpiece | work 10A, and a resin film is produced | generated. As a result, the surface treatment of the heat exchange core 8 is completed.

  Next, the manufacturing apparatus 20 used in the above steps 110 and 120 will be described with reference to FIG.

  As shown in FIG. 4, the manufacturing apparatus 20 is a surface treatment apparatus including a liquid recovery tank 30, a circulation pump 40, a suction pump 42, a nozzle 50, and a control device 60.

  The liquid recovery tank 30 is a container having suction ports 31 and 32. The suction ports 31 and 32 are respectively provided in the ceiling portion 34 of the liquid recovery tank 30 and open upward. The floor surface 36 of the liquid recovery tank 30 is inclined so as to gradually become lower toward the suction port 41 side of the circulation pump 40.

  The circulation pump 40 is an electric pump that sucks the resin liquid accumulated in the lower side of the liquid recovery tank 30 from the suction port 41 and sends it to the inlet side of the nozzle 50. The nozzle 50 is disposed above the suction port 31. The nozzle 50 discharges the resin liquid sent from the circulation pump 40 from the outlet. The nozzle 50 and the circulation pump 40 are connected by a pipe 45. The pipe 45 causes the resin liquid to flow from the circulation pump 40 toward the nozzle 50.

  The suction pump 42 sucks the air in the liquid recovery tank 30 and discharges the air to the outside of the liquid recovery tank 30, thereby removing excess resin liquid from the heat exchange core 8 in the workpiece 10 </ b> A as will be described later. Suction input to be sucked into the liquid recovery tank 30 through the suction ports 31 and 32 is generated.

  The control device 60 includes a microcomputer, a memory, and the like, and executes a control process for controlling the circulation pump 40 and the suction pump 42 based on detection by the detection sensor 61. The detection sensor 61 is used to detect the pallet 70 that conveys the workpiece 10A, as will be described later. The detection sensor 61 includes a transmission unit that transmits transmission waves such as light and ultrasonic waves, and a reception unit that receives reflected waves. In the present embodiment, the detection sensor 61 is disposed in the vicinity of the nozzle 50.

  In the present embodiment, the amount of resin liquid adhering to the surface of the heat exchange core 8 of the workpiece 10A described later is determined by the suction input of the suction pump 42. Therefore, the control device 60 controls the suction input of the suction pump 42 so that the amount of the resin liquid attached to the surface of the heat exchange core 8 becomes an appropriate amount.

  The workpiece 10a is sequentially transported at a constant speed by the transport device while the workpiece 10a is mounted on the pallet 70 above the liquid recovery tank 30 of the manufacturing apparatus 20 configured as described above. The transport route is set so as to pass between the nozzle 50 and the suction port 31 and the upper side of the suction port 32. The workpiece 10a is mounted at a predetermined position on the pallet 70.

  In the present embodiment, in a state where the workpiece 10a is mounted on the pallet 70, the tank portions 3 and 6 are positioned on the front side in the transport direction, and the tank portions 4 and 5 are positioned on the rear side in the transport direction. At this time, the air flow direction X (see FIG. 2) of the heat exchange core 8 coincides with the top-to-bottom direction.

  Next, the operation of the manufacturing apparatus 20 of this embodiment will be described.

  The manufacturing apparatus 20 controls the circulation pump 40 according to the flowchart of FIG. FIG. 6 is a flowchart showing the control process of the circulation pump 40. The manufacturing apparatus 20 performs the control process when the pallet 70 on which the workpiece 10a is mounted is being conveyed by the conveying device.

  First, in step 200, it is determined whether or not the pallet 70 is detected according to the detection result of the detection sensor 61.

  Specifically, a transmission wave is transmitted from the transmission unit of the detection sensor 61, and it is determined whether or not a reflected wave of the transmission wave is received by the reception unit. When the reflected wave is not received by the receiving unit, it is determined as NO because the pallet 70 is not detected. Accordingly, the process returns to step 200. For this reason, unless the reflected wave is received by the receiving unit, the NO determination in step 200 is repeated.

  Thereafter, when the leading end 71 in the transport direction of the pallet 70 reaches the lower side of the detection sensor 61, the transmission wave is reflected by the leading end 71 of the pallet 70 and the reflected wave is received by the receiving unit. Then, assuming that the tip 71 of the pallet 70 is detected by the detection sensor 61, YES is determined in step 200.

  Next, in step 210, it is determined whether or not the tank units 3 and 6 have passed between the nozzle 50 and the suction port 31.

  Specifically, by determining whether or not the time (hereinafter referred to as count time A) that has elapsed since the first determination of YES in step 200 has reached a certain time Ta, the nozzle 50 and the suction port 31 are determined. It is determined whether the tank parts 3 and 6 have passed between them. The predetermined time Ta is determined by the distance L1 between the front end portion 71 of the pallet 70 and the heat exchange core 8 in the transport direction and the transport speed of the pallet 70.

  Thereafter, when the count time A is less than the predetermined time Ta, it is determined that the tank portions 3 and 6 are located between the nozzle 50 and the suction port 31 and NO is determined in step 210. Accordingly, the process returns to step 210. For this reason, the NO determination is repeated in step 210 until the count time A reaches a certain time Ta.

  Thereafter, when the count time A reaches a certain time Ta, the tank portions 3 and 6 pass between the nozzle 50 and the suction port 31, and the heat exchange core 8 reaches between the nozzle 50 and the suction port 31. In step 210, the determination is YES. That is, it is determined that the heat exchange core 8 has reached the nozzle 50 in the vertical direction (that is, in the other direction of the air flow direction X). Accordingly, in step 220, the operations of the circulation pump 40 and the suction pump 42 are started. At this time, the circulation pump 40 sucks the resin liquid accumulated in the lower side of the liquid recovery tank 30 from the suction port 41 and sends it to the inlet side of the nozzle 50. Accordingly, the nozzle 50 discharges the resin liquid from one side in the air flow direction X to the heat exchange core 8 from the outlet. In addition to this, the suction pump 42 sucks the air in the liquid recovery tank 30 and discharges it to the outside of the liquid recovery tank 30. Thereby, the atmospheric pressure in the liquid recovery tank 30 becomes a negative pressure that is lower than the atmospheric pressure outside the liquid recovery tank 30. That is, the suction input by which the suction pump 42 sucks the resin liquid into the liquid recovery tank 30 through the suction port 31 can be generated. Therefore, the resin liquid discharged from the outlet of the nozzle 50 to the heat exchange core 8 is sucked into the liquid recovery tank 30 through the plurality of air passages 9 and the suction ports 31. As a result, a part of the resin liquid discharged from the outlet of the nozzle 50 adheres to the surface of the heat exchange core 8, and the excess resin liquid is recovered in the liquid recovery tank 30.

  In addition, the pallet 70 of this embodiment is comprised from the frame member which mounts the workpiece | work 10A. An opening that penetrates in the vertical direction is provided at the center of the frame member. For this reason, the surplus resin liquid is sucked to the suction port 31 side through the opening.

  Next, in step 230, it is determined whether or not the heat exchange core 8 has passed between the nozzle 50 and the suction port 31.

  Specifically, by determining whether or not the time (hereinafter referred to as count time B) that has elapsed since the first determination of YES in step 210 has reached a certain time Tb, the nozzle 50 and the suction port 31 can be determined. It is determined whether or not the heat exchange core 8 has passed between them. The fixed time Tb is determined by the distance L2 between the front side in the transport direction and the rear side in the transport direction of the heat exchange core 8 and the transport speed of the pallet 70.

  Thereafter, when the count time B is less than the predetermined time Tb, it is determined that the heat exchange core 8 is located between the nozzle 50 and the suction port 31 and NO is determined in Step 220. That is, it is determined that the heat exchange core 8 is located below the nozzle 50 (that is, the other side of the air flow direction X of the nozzle 50). Accordingly, the process returns to step 230. Therefore, the NO determination is repeated at step 230 until the count time B reaches a certain time Tb.

  Therefore, during the period in which the heat exchange core 8 is located between the nozzle 50 and the suction port 31, the resin liquid is discharged from the nozzle 50 to the heat exchange core 8, and the surplus resin liquid is removed from the heat exchange core 8. The suction into the liquid recovery tank 30 through the plurality of air passages 9 and the suction port 31 is simultaneously performed. Then, the excess resin liquid recovered in the liquid recovery tank 30 through the suction port 31 flows along the floor surface 36 toward the circulation pump 40 on the lower side of the liquid recovery tank 30.

  That is, the processing liquid is discharged from the nozzle 50 in a direction perpendicular to the core surface of the work 10A, and at the same time, the processing liquid is sucked from the opposite side of the nozzle 50 to the work 10A by the suction pump 42, and between the fins 9 and the tube 2 The processing liquid is brought into contact only with the fins 9 and the surfaces of the tubes 2 while always flowing the processing liquid without completely filling the gap with the processing liquid. The core surface is one of an air inflow surface and an air outflow surface of the heat exchange core 8. The air inflow surface is a surface through which air flows in the heat exchange core 8. The air outflow surface is a surface through which air flows out of the heat exchange core 8. Then, while the processing liquid is discharged from the nozzle 50, the processing liquid that has not adhered to the surface of the heat exchange core 8 passes through the plurality of air passages 9 of the heat exchange core 8 of the workpiece 10A as it is, and is immediately sucked and processed. The liquid is recovered in the liquid recovery tank 30, and the process of circulating the recovered processing liquid is repeated.

  Thereafter, when the count time B reaches a certain time Tb, it is determined that the heat exchange core 8 has passed between the nozzle 50 and the suction port 31 and YES is determined in step 230. That is, it is determined that the tank portions 4 and 5 have reached between the nozzle 50 and the suction port 31. Along with this, the operation of the circulation pump 40 is stopped (step 240). For this reason, the resin liquid is not discharged from the outlet of the nozzle 50.

  Thus, every time the pallet 70 is transported by the transport device and the heat exchange core 8 of the workpiece 10A reaches between the nozzle 50 and the suction port 31, the operation of the circulation pump 40 is started. Thereafter, when the heat exchange core 8 passes between the nozzle 50 and the suction port 31, the circulation pump 40 is stopped. For this reason, during the period in which the heat exchange core 8 is positioned between the nozzle 50 and the suction port 31 for each workpiece 10A, the resin liquid is discharged from the outlet of the nozzle 50 to the heat exchange core 8, and surplus The resin liquid is simultaneously sucked into the liquid recovery tank 30 through the plurality of air passages 9 of the heat exchange core 8 and the suction port 31. Thereby, the resin liquid adhesion step (step 110) in FIG. 1 is completed.

  Thereafter, the heat exchange core 8 of the workpiece 10A that has completed the resin liquid adhesion step (step 110) is transported to the upper side of the suction port 32 by the transport device. During the period in which the heat exchange core 8 of the workpiece 10A is positioned above the suction port 32, the heat exchange core of the workpiece 10A is caused by the negative pressure in the liquid recovery tank 30 (that is, the suction force of the suction pump 42). Excess resin liquid adhering to 8 is sucked into the liquid recovery tank 30 through the plurality of air passages 9 of the heat exchange core 8 and the suction port 32 and recovered. Thereafter, when the heat exchange core 8 of the workpiece 10A is separated from the suction port 32 by the conveyance by the conveyance device, the suction of the excess resin liquid from the heat exchange core 8 of the workpiece 10A into the liquid recovery tank 30 is completed. As a result, the resin liquid suction step (step 120) is completed. The resin liquid recovered in the liquid recovery tank 30 by the suction force in this way flows along the floor surface 36 toward the circulation pump 40.

  According to the present embodiment described above, the method for manufacturing the heat exchanger 10 allows the resin liquid to be discharged from the nozzle 50 toward the work 10A from one side of the heat exchange core 8 in the air flow direction X (Ten district improvement side). And a suction step of sucking excess resin liquid from the other side (downward in the vertical direction) of the heat exchange core 8 through the plurality of air passages 9 from the suction port 32. The air flow direction X is a direction in which air that exchanges heat with the refrigerant in the tube 2 of the heat exchange core 8 in the heat exchanger 10 flows through the plurality of air passages 9. And a resin liquid can be made to adhere to the surface of the heat exchange core 8 by performing a discharge process and a suction process simultaneously by the adhesion process of step 110. FIG.

  In the present embodiment, the resin liquid is discharged from the outlet of the nozzle 50 to the heat exchange core 8 only during the period in which the heat exchange core 8 of the workpiece 10 </ b> A is positioned between the nozzle 50 and the suction port 31. For this reason, a resin liquid can be made to adhere only to the surface of the fin 7 of the heat exchange core 8 and the tube 2 which require functions, such as rust prevention and antibacterial mentioned above.

  By the above, the manufacturing method of the heat exchanger 10 which suppresses that a resin liquid adheres to tank parts 3, 4, 5, 6, etc. other than the heat exchange core 8 among workpiece | work 10A, the manufacturing apparatus 20 of the heat exchanger 10, And the heat exchanger 10 manufactured by the said manufacturing method can be provided.

  Conventionally, when the entire workpiece 10A is immersed in the treatment tank in order to attach the resin solution to the workpiece 10A, the resin solution enters the inside of the refrigerant flow path such as the tube 2 or the tank portions 3, 4, 5, 6 and the like. It was necessary to plug tightly so that there was no. For this reason, since it is necessary to add a process without added value to a manufacturing process, there exists a problem that manufacturing cost becomes still higher.

  On the other hand, in this embodiment, the resin liquid is discharged from the nozzle 50 from one side of the air flow direction of the heat exchange core 8 to the workpiece 10A, and the resin liquid is attached to the surface of the heat exchange core 8. ing. For this reason, it is not necessary to seal the resin liquid so that it does not enter the refrigerant flow path. Thereby, manufacturing cost can be reduced.

  Further, if the resin liquid is simply discharged to the heat exchange core 8, the fins 7 of the heat exchange core 8 of the workpiece 10 </ b> A are arranged at a high density, and a phenomenon occurs in which the resin liquid closes the gap with the surface tension. After curing, the air passage 9 (see FIG. 3) of the heat exchange core 8 is blocked, and the heat exchange performance of the heat exchanger 10 is deteriorated.

  On the other hand, in the present embodiment, the discharge process and the suction process are performed simultaneously in the attaching process of Step 110. Further, after the attaching process in step 110, a suction process in step 110 is performed. Therefore, excess resin liquid can be removed from the fins 7. As a result, the air passage 9 is not blocked by the resin liquid. For this reason, the heat exchanger 10 which has high heat exchange performance can be manufactured.

  In the present embodiment, of the resin liquid discharged from the outlet of the nozzle 50, excess resin liquid that has not adhered to the heat exchange core 8 of the workpiece 10A is recovered through the plurality of air passages 9 and the suction ports 31 (32). It is collected in the tank 30. The recovered resin liquid is pumped by the circulation pump 40 and discharged from the nozzle 50. In this way, circulation is performed in the order of the nozzle 50 → the heat exchange core 8 of the workpiece 10A → the suction port 31 (32) → the liquid recovery tank 30 → the nozzle 50. Accordingly, the recovery rate for recovering the excess resin liquid in the liquid recovery tank 30 can be increased, and the use efficiency of the resin liquid can be 90%.

  In the present embodiment, after the attaching process of step 110, a resin liquid suction process (step for sucking excess resin liquid adhering to the heat exchange core 8 of the workpiece 10A on the front side in the transport direction to the liquid recovery tank 30 side through the suction port 32. 120) is implemented. The recovery rate of the resin liquid can be increased.

  In the present embodiment, the resin adhering to the heat exchange core 8 is controlled by controlling the suction force for sucking the resin liquid into the liquid recovery tank 30 through the suction ports 31 and 32 by the suction pump 42 in the steps 110 and 120. The amount of liquid attached can be controlled. Thereby, the adhesion amount of the resin liquid adhering to the heat exchange core 8 can be controlled to an appropriate amount.

  In the above-described embodiment, the example in which the air flow direction X and the direction in which the tubes 2 are arranged is orthogonal to each other and the air flow direction X and the longitudinal direction of the tubes 2 are orthogonal to each other has been described. The angle formed by the air flow direction X and the direction in which the tubes 2 are arranged (or the longitudinal direction of the tubes 2) is not limited to a right angle, and may be as follows. That is, the term “orthogonal” in the present invention means that the angle formed by the air flow direction X and the direction in which the tubes 2 are arranged (or the longitudinal direction of the tubes 2) is an angle within a predetermined range including a right angle. The predetermined range is a range of angles determined in order to obtain the effect of the present invention such that the resin liquid is prevented from adhering to the tank portions 3, 4, 5, 6 and the like other than the heat exchange core 8 in the workpiece 10A. That is. That is, according to the present invention, if the effect of the present invention can be obtained, the angle formed by the air flow direction X and the direction in which the tubes 2 are arranged is an angle other than a right angle, and the air flow direction X and the tubes 2 This includes the case where the angle formed by the longitudinal direction is an angle other than a right angle.

(Other embodiments)
In the said embodiment, a partition wall may be provided in the liquid collection tank 30, and two rooms may be provided. In this case, the partition wall may be provided with a through hole that communicates the two rooms.

  In the said embodiment, although demonstrated to the example using the heat exchanger 10 which has the heat exchange core 8 provided with the fin 7 and the tube 2 as the evaporator 10, it replaces with this and only the tube 2 among the fin 7 and the tube 2 is used. May be used in the heat exchanger core 8. That is, a finless heat exchanger that does not include the fins 7 in the heat exchange core 8 may be used as the heat exchanger 10 of the present invention.

  In the said embodiment, although the example using the heat exchanger by which the several tube 2 was arranged in 2 rows was demonstrated as the evaporator 10, it is not restricted to this, The heat by which the several tube 2 is arranged in 1 row An exchanger may be used, and a heat exchanger in which a plurality of tubes 2 are arranged in three or more rows may be used.

  In the said embodiment, although the example using the evaporator 10 as the heat exchanger 10 was demonstrated, heat exchangers, such as radiators other than the evaporator 10, are good also as the heat exchanger 10 of this invention.

  In addition, this invention is not limited to above-described embodiment, In the range described in the claim, it can change suitably. Further, the above embodiments are not irrelevant to each other, and can be combined as appropriate unless the combination is clearly impossible.

2 Tube 3, 4, 5, 6 Tank part (first and second tank parts)
8 Heat exchange core 10 Evaporator (heat exchanger)
20 Manufacturing Equipment 30 Liquid Recovery Tank 31, 32 Suction Port 34 Ceiling 40 Circulation Pump (Pressure Pump)
42 Suction pump 50 Nozzle 60 Control device (first and second control devices)

Claims (8)

For a heat exchanger (10) in which a heat exchange core (8) in which a plurality of tubes are arranged in parallel is arranged between the first and second tanks (3, 4, 5, 6), A first step (110) for discharging the treatment liquid for surface treatment from the outlet of the nozzle (50) from one side in the predetermined direction;
The predetermined direction is a direction orthogonal to the direction in which the plurality of tubes are arranged and orthogonal to the longitudinal direction of the plurality of tubes, and the predetermined direction is between two adjacent tubes of the plurality of tubes. At least one or more air passages (9) are provided therethrough,
A second step (110) of sucking excess of the processing liquid through the air passage from the other side in the predetermined direction with respect to the heat exchange core;
By simultaneously performing the first and second steps, the treatment liquid is attached to the surface of the heat exchange core ,
In the second step, the excess processing liquid is recovered in the liquid recovery tank by sucking the processing liquid into the liquid recovery tank (30) from the other side in the predetermined direction with respect to the heat exchange core. And
In the first step, the processing liquid in the liquid recovery tank is circulated toward the inlet of the nozzle to discharge the processing liquid from the outlet of the nozzle,
A third step (120) for sucking the treatment liquid adhering to the heat exchange core of the heat exchanger having undergone the first and second steps;
In the third step, the processing liquid in the heat exchange core is sucked into the liquid recovery tank, and the sucked processing liquid is recovered in the liquid recovery tank,
In the second and third steps, the treatment liquid is sucked into the liquid recovery tank from the heat exchange core by the suction force of the suction pump (42), and the first control device (60) A method for manufacturing a heat exchanger, wherein the amount of the treatment liquid adhering to the heat exchange core is controlled by controlling a suction force of a suction pump . For a heat exchanger (10) in which a heat exchange core (8) in which a plurality of tubes are arranged in parallel is arranged between the first and second tanks (3, 4, 5, 6), A first step (110) for discharging the treatment liquid for surface treatment from the outlet of the nozzle (50) from one side in the predetermined direction;
The predetermined direction is a direction orthogonal to the direction in which the plurality of tubes are arranged and orthogonal to the longitudinal direction of the plurality of tubes, and the predetermined direction is between two adjacent tubes of the plurality of tubes. At least one or more air passages (9) are provided therethrough,
A second step (110) of sucking excess of the processing liquid through the air passage from the other side in the predetermined direction with respect to the heat exchange core;
By simultaneously performing the first and second steps, the treatment liquid is attached to the surface of the heat exchange core ,
The heat exchanger is adapted to be conveyed so as to pass the other side of the predetermined direction with respect to the nozzle,
A pressure pump (40) circulates the processing liquid toward the inlet of the nozzle and discharges the processing liquid from the outlet of the nozzle;
In the first step, when the detection means (61) detects that the heat exchange core is located on the other side in the predetermined direction with respect to the nozzle, the processing liquid is discharged from the outlet of the nozzle. The second control device (60) controls the pressure pump so that the treatment liquid from the nozzle is attached only to the heat exchange core of the heat exchanger. Production method. In the second step, the excess processing liquid is recovered in the liquid recovery tank by sucking the processing liquid into the liquid recovery tank (30) from the other side in the predetermined direction with respect to the heat exchange core. And
3. The heat according to claim 2 , wherein in the first step, the processing liquid in the liquid recovery tank is circulated toward an inlet of the nozzle and the processing liquid is discharged from the outlet of the nozzle. Exchanger manufacturing method. Heat according to claim 3, characterized in that it comprises a third step (120) for sucking the first, the processing liquid adhering to the second of the heat exchange core Performed heat exchangers step Exchanger manufacturing method. Wherein in the third step, a treatment fluid of the heat exchanger in the core and sucked into the liquid collection tank, said treating solution suction to claim 4, characterized in that recovering the liquid collection tank The manufacturing method of the heat exchanger of description. In the second and third steps, the treatment liquid is sucked into the liquid recovery tank from the heat exchange core by the suction force of the suction pump (42), and the first control device (60) 6. The method of manufacturing a heat exchanger according to claim 5 , wherein the amount of the treatment liquid adhering to the heat exchange core is controlled by controlling the suction force of a suction pump. For a heat exchanger (10) in which a heat exchange core (8) in which a plurality of tubes are arranged in parallel is arranged between the first and second tanks (3, 4, 5, 6), A nozzle (50) for discharging a treatment liquid for surface treatment from one side in the predetermined direction;
The predetermined direction is a direction orthogonal to the direction in which the plurality of tubes are arranged and orthogonal to the longitudinal direction of the plurality of tubes, and the predetermined direction is between two adjacent tubes of the plurality of tubes. At least one or more air passages (9) are provided therethrough,
A pump (40) for circulating the processing liquid toward the inlet of the nozzle and discharging the processing liquid from the outlet of the nozzle;
A suction pump (42) for generating a suction force for sucking excess processing liquid through the air passage from the other side of the predetermined direction with respect to the heat exchange core,
By allowing the processing liquid to be discharged from the outlet of the nozzle by the pressure pump and simultaneously generating the suction force by the suction pump, the processing liquid is attached to the surface of the heat exchange core ,
A liquid recovery tank (30) for recovering the processing liquid sucked by the suction pump from the heat exchange core;
The pressure feed pump causes the processing liquid in the liquid recovery tank to flow toward the inlet of the nozzle and discharge the processing liquid from the outlet of the nozzle,
The heat exchanger is adapted to be conveyed so as to pass the other side of the predetermined direction with respect to the nozzle,
Detection means (61) for detecting that the heat exchange core is located on the other side of the predetermined direction with respect to the nozzle;
By controlling the pumping pump so that the processing liquid is discharged from the outlet of the nozzle when the detection means detects that the heat exchange core is located on the other side of the predetermined direction with respect to the nozzle, A second control device (60) for adhering the treatment liquid from the nozzle only to the heat exchange core of the heat exchanger;
An apparatus for manufacturing a heat exchanger, comprising: For a heat exchanger (10) in which a heat exchange core (8) in which a plurality of tubes are arranged in parallel is arranged between the first and second tanks (3, 4, 5, 6), A nozzle (50) for discharging a treatment liquid for surface treatment from one side in the predetermined direction;
The predetermined direction is a direction orthogonal to the direction in which the plurality of tubes are arranged and orthogonal to the longitudinal direction of the plurality of tubes, and the predetermined direction is between two adjacent tubes of the plurality of tubes. At least one or more air passages (9) are provided therethrough,
A pump (40) for circulating the processing liquid toward the inlet of the nozzle and discharging the processing liquid from the outlet of the nozzle;
A suction pump (42) for generating a suction force for sucking excess processing liquid through the air passage from the other side of the predetermined direction with respect to the heat exchange core,
By allowing the processing liquid to be discharged from the outlet of the nozzle by the pressure pump and simultaneously generating the suction force by the suction pump, the processing liquid is attached to the surface of the heat exchange core ,
A liquid recovery tank (30) for recovering the processing liquid sucked by the suction pump from the heat exchange core;
The pressure feed pump causes the processing liquid in the liquid recovery tank to flow toward the inlet of the nozzle and discharge the processing liquid from the outlet of the nozzle,
The suction pump sucks the treatment liquid adhering to the heat exchange core of the heat exchanger to which the treatment liquid is already attached;
The suction pump sucks the processing liquid adhering to the heat exchange core of the heat exchanger to which the processing liquid is already attached into the liquid recovery tank, and recovers the sucked processing liquid into the liquid recovery tank. And
An apparatus for manufacturing a heat exchanger , comprising: a first control device (60) for controlling a suction force of the suction pump in order to control an amount of the treatment liquid attached to the heat exchange core .

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