JP2010107063A - Tool for separation - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily separate adhesion of a cooling mechanism with a cooled section in a stuck state by a thermally-conductive auxiliary material. <P>SOLUTION: A heater 121b is disposed to heat the thermally-conductive auxiliary material (for example, thermally-conductive grease) disposed between a heat transfer plate 50 connected with a power element 33 and a refrigerant jacket 20 cooling the heat transfer plate 50 by a refrigerant. Further, a jacket gripping section 120 is disposed to grip the refrigerant jacket 20. Prescribed separation force is applied to the jacket gripping section 120 to separate the adhesion of the heat transfer plate 50 with the refrigerant jacket 20. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a jig used for repair or inspection in a refrigeration apparatus.

In an air conditioner that performs a vapor compression refrigeration cycle by circulating a refrigerant, an electric circuit such as an inverter circuit is mounted to control the operating state of the motor of the compressor. Generally, a power element that generates high heat is used in this inverter circuit, and a conventional air conditioner is provided with a cooling mechanism that cools the power element so that the power element does not reach a temperature higher than the operable temperature. Yes. As an example of such a cooling mechanism, there is one in which a power element is cooled by a refrigerant used in a refrigeration cycle (see, for example, Patent Document 1). In the air conditioner of Patent Document 1, a refrigerant passage through which refrigerant used in a refrigeration cycle flows is provided in a heat sink (a heat sink provided with a refrigerant passage is hereinafter referred to as a refrigerant jacket), and a power element (giant in the same document is a giant).・ The transistor is fixed and the refrigerant jacket is housed in the electrical component box.
JP-A-62-69066

  By the way, in the refrigerant jacket (cooling mechanism), a heat conduction auxiliary material that assists heat conduction between these members is often interposed on the contact surface with the power element (cooled portion). An example of such a heat conduction auxiliary material is heat conductive grease. The thermally conductive grease is solidified at a temperature below (for example, room temperature). Therefore, the thermal conductive grease may be solidified at the time of repair or inspection, and when the thermal conductive grease is solidified in this way, the cooling mechanism and the part to be cooled may be stuck. There is sex. In addition, a large force is required for peeling between the cooling mechanism and the part to be cooled in the stuck state, and it becomes difficult to perform repair or inspection by removing the potential circuit from the refrigeration apparatus.

  In addition to the heat conductive grease, a heat conductive double-sided adhesive tape, a heat conductive sheet, or a heat conductive material may be used as the heat conduction auxiliary material between the cooling mechanism and the cooled portion. An adhesive or the like may be used. For example, since a heat conductive double-sided pressure-sensitive adhesive tape is coated with an adhesive material on both sides, a large force is still required for peeling between the cooling mechanism and the part to be cooled.

  It is considered that the heat conductive sheet can be easily separated from the cooling mechanism and the part to be cooled after a short period of use. However, as the refrigeration apparatus is used for a long period of time, there is a possibility that the cooling mechanism and the part to be cooled are stuck together, and in this case, a large force is required to separate them. Some of the thermally conductive sheets have adhesiveness on one side, and in this case, it is considered that a larger force is required.

  In addition, heat conductive adhesive is used for parts that do not need to be peeled off, but heat conductive adhesives with poor adhesive properties are parts that require peeling during repair, such as cooling mechanisms and parts to be cooled. May be adopted. In this case, although the adhesiveness is weak, a large force may still be required for peeling between the cooling mechanism and the portion to be cooled.

  The present invention has been made paying attention to the above-described problem, and an object of the present invention is to make it possible to easily peel the adhesion between the cooling mechanism in a glued state and the part to be cooled by the heat conduction auxiliary material.

In order to solve the above problems, the first invention is
A refrigerant circuit that performs a vapor compression refrigeration cycle by circulating a refrigerant, a cooled part (33, 50) that includes an electrical component (33) as a cooled object, and heat conduction that assists heat conduction between the two members In a refrigeration apparatus comprising: an auxiliary material; and a cooling mechanism (20) that is in close contact with the cooled portion (33, 50) via the heat conduction auxiliary material and cools the cooled object with the refrigerant. A peeling jig for peeling the close contact between the cooled portion (33, 50) and the cooling mechanism (20),
A heating unit (121b) for heating the heat conduction auxiliary material;
A grip portion (120) for gripping the cooling mechanism (20);
It is provided with.

  Thereby, a heating part (121b) heats a heat conduction auxiliary material, and this heat conduction auxiliary material is softened with the heat. When the heat conduction auxiliary material is softened, the force (adhesion force) for adhering the cooled parts (33, 50) and the cooling mechanism (20) to each other decreases. When the cooling mechanism (20) is gripped by the gripping part (120) and a predetermined force is applied in a state where the sticking force is reduced, the cooled part (33, 50) and the cooling mechanism (20) are in close contact with each other. Are separated from each other.

In addition, the second invention,
In the peeling jig of the first invention,
The cooled portion (33, 50) includes a heat transfer plate (50) that mediates heat exchange between the electrical component (33) and the cooling mechanism (20), and the heat transfer plate (50) It is closely attached to the mechanism (20) via the heat conduction auxiliary material.

  Thereby, the heat conduction auxiliary material between the heat transfer plate (50) and the cooling mechanism (20) is heated by the heating unit (121b).

In addition, the third invention,
In the peeling jig of the first or second invention,
Further, when the close contact between the cooled part (33, 50) and the cooling mechanism (20) is peeled off, the cooled part (33, 50) is brought into contact with the cooled part (33, 50). A fixing portion (211) for fixing is provided.

  Thereby, since the to-be-cooled part (33, 50) is fixed by the fixing part (211) of the peeling jig, a larger force can be applied to the grip part (120).

In addition, the fourth invention is
In the peeling jig of the third invention,
Furthermore, a displacement regulating means (212) that regulates displacement of the gripping part (120) in a direction of separating the cooling mechanism (20) from the cooled part (33, 50) by contacting the gripping part (120). ).

  As a result, the displacement regulating means (212) regulates the displacement of the gripping part (120) during the peeling operation, so that the displacement of the cooling mechanism (20) during the peeling can be regulated within a predetermined range.

In addition, the fifth invention,
In any one of the peeling jigs of the first to fourth inventions,
The grip portion (120) is engaged with a recess (20b) formed in the cooling mechanism (20), or is engaged with a surface facing the cooled portion (33, 50) in the cooling mechanism (20). It is characterized by having a protruding portion (123a).

  Thereby, the protrusion (123a) formed in the holding part (120) engages with the cooling mechanism (20). Then, a force (peeling force) in a direction (peeling direction) in which the cooled parts (33, 50) and the cooling mechanism (20) are separated from each other is applied to the cooling mechanism (20) via the protrusion (123a).

In addition, the sixth invention,
In the peeling jig of the fifth invention,
The protrusion (123a) opens and closes to an engagement position with the cooling mechanism (20) and a position to release the engagement.

  Thereby, at the time of peeling operation, the protrusion (123a) is moved to the position where the engagement is released, and then the protrusion (123a) is brought in the vicinity of the engaging portion of the cooling mechanism (20). Next, when the protrusion (123a) is moved to the engagement position, the protrusion (123a) is engaged with the cooling mechanism (20).

In addition, the seventh invention,
In the peeling jig of the sixth invention,
The grip portion (120) includes an urging means (123c) for urging the protrusion (123a) toward the engagement position.

  Thereby, when the protrusion (123a) is in a position to release the engagement, the protrusion (123a) is moved toward the engagement position by the biasing means (123c).

Further, the eighth invention is
In the peeling jig of the sixth invention,
The grip part (120) disengages the protrusion (123a) by the displacement of the grip part (120) in a direction to separate the cooled parts (33, 50) and the cooling mechanism (20) from each other. A slider mechanism (320, 330) for moving to a matching position is provided.

  Thus, when the peeling force is applied, the gripping part (120) is displaced, and the protrusion (123a) is moved to the engagement position by the displacement, and the protrusion (123a) is engaged with the cooling mechanism (20). The When further peeling force is applied, the close contact between the cooled parts (33, 50) and the cooling mechanism (20) is peeled off from each other.

In addition, the ninth invention,
In any one of the first to eighth inventions, the peeling jig,
Furthermore, it is characterized by comprising temperature regulation means (121c) for regulating the heating temperature by the heating section (121b) to a certain temperature or less.

  As a result, the temperature regulating means (121c) regulates the heating temperature by the heating part (121b) to a certain temperature or less, so that the temperature rise of the electrical component (33) included in the part to be cooled (33, 50) is constant, for example. It is suppressed to the following.

The tenth aspect of the invention is
In any one of the first to ninth inventions, the peeling jig,
The heat conduction auxiliary material is any one of heat conductive grease, a heat conductive double-sided adhesive tape, a heat conductive sheet, and a heat conductive adhesive.

  Accordingly, in the refrigeration apparatus in which any one of the heat conductive grease, the heat conductive double-sided pressure-sensitive adhesive tape, the heat conductive sheet, and the heat conductive adhesive is employed as the heat conduction auxiliary material, heat such as the heat conductive grease is used. The conduction auxiliary material is heated by the heating unit (121b). And heat conduction auxiliary materials, such as heat conductive grease, are softened by the heat, and the force (adhesion force) which makes a to-be-cooled part (33,50) and a cooling mechanism (20) stick together mutually becomes small.

  In each of the first and second inventions, the sticking force due to the heat conduction auxiliary material is reduced, so that the close contact between the cooled parts (33, 50) and the cooling mechanism (20) can be peeled with a smaller force. Further, since the cooling mechanism (20) is held by the holding portion (120), a peeling force can be easily applied to the cooling mechanism (20). And by these, a to-be-cooled part (33,50) can be easily removed from a freezing apparatus, and repair, inspection, etc. can be performed.

  In addition, according to the third invention, since a larger force can be applied to the grip portion (120), the cooled portion (33, 50) and the cooling mechanism (20) can be more easily separated.

  According to the fourth invention, since the displacement of the cooling mechanism (20) at the time of peeling is regulated within a predetermined range, even if a larger peeling force is applied to the cooling mechanism (20) at the time of peeling, the cooling mechanism (20) and an excessive force is not applied to the member connected to this, and the member is not damaged.

  According to the fifth aspect of the invention, since the protrusion (123a) of the grip portion (120) is engaged with the cooling mechanism (20), the peeling force is more reliably applied to the cooling mechanism (20). Can do.

  According to the sixth aspect of the invention, the protrusion (123a) opens and closes to the engagement position with the cooling mechanism (20) and the position to release the engagement. Can be installed. That is, workability is improved.

  According to the seventh invention, the protrusion (123a) at the position for releasing the engagement is moved toward the engagement position by the urging means (123c). A cooling mechanism (20) can be engaged. That is, workability is improved.

  According to the eighth invention, when the peeling force is applied, the protrusion (123a) and the cooling mechanism (20) are simultaneously engaged. That is, since it is not necessary to separately perform the work of engaging the protrusion (123a) with the cooling mechanism (20), the peeling work can be performed efficiently.

  Further, according to the ninth invention, the temperature rise of the electrical component (33) included in the cooled part (33, 50) is suppressed to a certain level, so that the electrical component (33) is damaged by the heat. There is nothing to do.

  According to the tenth invention, in the refrigeration apparatus in which any one of the heat conductive grease, the heat conductive double-sided pressure-sensitive adhesive tape, the heat conductive sheet, and the heat conductive adhesive is employed as the heat conduction auxiliary material, The adhesion between the cooling part (33, 50) and the cooling mechanism (20) is easily peeled off.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use. In the following description of each embodiment, constituent elements having the same functions as those described once will be assigned the same reference numerals and description thereof will be omitted.

Embodiment 1 of the Invention
The peeling jig according to the present embodiment is used when repairing or inspecting a refrigeration apparatus (for example, an air conditioner) including a refrigerant circuit that performs a vapor compression refrigeration cycle by circulating the refrigerant. More specifically, in the refrigeration apparatus in which the peeling jig according to the present embodiment is used, a cooling mechanism is attached to cool the electrical components of the electric circuit (printed circuit board) with the refrigerant, and the peeling jig is used. The tool is used when removing the cooling mechanism from the part to be cooled at the time of repair or inspection. Here, first, a description will be given focusing on the refrigeration apparatus in which the peeling jig according to the present embodiment is used, particularly the electrical component and a cooling mechanism for cooling the electrical component.

  FIG. 1 is a diagram illustrating an electric circuit (30) and its surroundings in a refrigeration apparatus in which the peeling jig according to the present embodiment is used. The electric circuit (30) controls the rotational speed of the motor of the compressor of the refrigeration apparatus. As shown in FIG. 1, the electric circuit (30) is formed on a printed circuit board (31). In this example, as shown in FIG. 1, a power element (33) is disposed as an electrical component on one mounting surface of the printed circuit board (31), and another electrical component (34) is disposed on the mounting surface on the back side. Has been placed. This power element (33) is a switching element of an inverter circuit that supplies electric power to the motor of the compressor, for example, and generates heat when the compressor is in operation.

  The printed circuit board (31) on which the electric circuit (30) is formed is fixed in the electrical component box (40) via the spacer (32). The electrical component box (40) is formed in a flat box shape with one surface opened, and a through hole (40a) is provided on the surface (bottom surface) opposed to the opening. And in the through-hole (40a), the heat-transfer plate (50) formed in plate shape is being fixed with the attachment screw (illustration omitted) so that this through-hole (40a) may be covered. The heat transfer plate (50) is made of a material having a relatively small thermal resistance, such as aluminum. And with respect to this heat exchanger plate (50), the power element (33) is being fixed with the attachment screw (illustration omitted) from the inner side of the electrical component box (40).

  The electrical component box (40) containing the printed circuit board (31) (electric circuit (30)) in this manner is incorporated in the refrigeration apparatus (for example, an outdoor unit of an air conditioner), and a predetermined fixing member (for example, The inside of the casing of the outdoor unit is fixed to a machine room in which a compressor or the like is accommodated and a partition plate or the like partitioning into a heat exchange chamber in which an outdoor heat exchanger or the like is accommodated by screwing or the like.

  Since the power element (33) generates heat as described above, there is a possibility that if the power element (33) is not cooled, it may exceed a temperature at which the power element (33) can operate (for example, 90 ° C.). Therefore, in this refrigeration apparatus, the power element (33) is cooled by the refrigerant circulating in the refrigerant circuit. Specifically, in this refrigeration apparatus, as shown in FIG. 1, a refrigerant jacket (20) that cools the object to be cooled (power element (33)) with a refrigerant is fixed to a heat transfer plate (50). The power element (33) in the box (40) is cooled. That is, the heat transfer plate (50) and the power element (33) constitute a cooled part of the present invention, and the power element (33) is a cooled object cooled by the cooling mechanism. The refrigerant jacket (20) corresponds to the cooling mechanism in the present invention.

  Specifically, the refrigerant jacket (20) is made of, for example, a metal such as aluminum in a flat rectangular parallelepiped shape. For example, the refrigerant jacket (20) covers a part of the refrigerant pipe (21) formed of a copper pipe or the like, It is thermally connected to the refrigerant pipe (21). Specifically, as shown in FIG. 2, the refrigerant jacket (20) is provided with two through holes (20a) (or grooves) for fitting the refrigerant pipe (21). After passing through one through hole (20a), it is folded in a U shape and passes through the other through hole (20a). And this refrigerant | coolant piping (21) is connected to the said refrigerant circuit, and the refrigerant | coolant used for the said refrigerating cycle circulates in the inside. Thus, the refrigerant jacket (20) can exchange heat with the refrigerant flowing through the refrigerant pipe (21) via the refrigerant pipe (21).

  The refrigerant jacket (20) is fixed to the heat transfer plate (50) from the outside of the electrical component box (40) with a mounting screw (not shown). The bottom surface of the refrigerant jacket (20) (the surface on the side in contact with the heat transfer plate (50)) is provided with two recesses (20b) on each side surface facing each other as shown in FIG. . These recesses (20b) are wedge-shaped in cross section, as shown in FIG.

  During operation of the refrigeration system, the heat of the power element (33) is transferred to the refrigerant jacket (20) through the heat transfer plate (50), and the refrigerant jacket (20) heats the refrigerant in the refrigerant pipe (21). Dissipate heat. As a result, the power element (33) is maintained at an operable temperature. As described above, in this refrigeration apparatus, heat conduction is performed between the heat transfer plate (50) and the refrigerant jacket (20), so that the contact surface between the heat transfer plate (50) and the refrigerant jacket (20) Thermally conductive grease is applied as a thermal conduction auxiliary material that assists thermal conduction between the two members. That is, this heat conductive grease corresponds to the heat conduction auxiliary material of the present invention. In addition, since heat conduction is similarly performed between the power element (33) and the heat transfer plate (50), heat conductive grease is also present on the contact surface between the power element (33) and the heat transfer plate (50). It has been applied.

  By the way, in this refrigeration apparatus, when the electric circuit (30) is repaired or inspected, the electric component box (40) is frozen while the printed circuit board (31) is mounted in the electric component box (40). It is designed to be removed from the device (for example, an outdoor unit). Specifically, in a state where the electrical component box (40) is fixed to a fixing member (for example, the partition plate) in the outdoor unit, the refrigerant jacket (20) and the heat transfer plate (50) are separated from each other, The electrical component box (40) is removed from the refrigeration unit by removing the electrical component box (40) (ie, when the electrical component box (40) is removed from the refrigeration unit, the heat transfer plate (50) is connected to the electrical component box (40). ).

  However, since the thermally conductive grease is solidified at a certain temperature (for example, room temperature) or less, the thermally conductive grease is solidified at the time of repair or inspection, and the refrigerant jacket (20) and the heat transfer plate (50 ) May be stuck. A large force is required to peel both the stuck states. For example, if a person grabs the refrigerant jacket (20) by hand and applies the force, it is difficult to separate the two. That is, in such a stuck state, it is difficult to take out the electrical component box (40) from the outdoor unit for repair or inspection. The peeling jig of the present embodiment provides close contact (that is, close contact between the portion to be cooled and the cooling mechanism) between the heat transfer plate (50) and the refrigerant jacket (20) by a heat conduction auxiliary material (thermal conductive grease). They peel from each other.

<Configuration of peeling jig (100)>
FIG. 3 is a front view of the peeling jig (100) according to the first embodiment of the present invention. FIG. 4 is a plan view of the peeling jig (100). As shown in FIG. 3, the peeling jig (100) includes a handle (110) to which a person manually applies a peeling force (described later) and a jacket gripping part (120) for gripping the refrigerant jacket (20). It is configured.

  The handle (110) is a member formed in a straight line as shown in FIG.

  Moreover, the jacket holding part (120) is comprised by the plate-shaped member (121), the columnar member (122), and the nail | claw holding | maintenance part (123). The jacket grip (120) corresponds to the grip of the present invention.

  The plate-like member (121) is a member having a flat surface along the upper surface of the refrigerant jacket (20) (the surface opposite to the contact surface with the heat transfer plate (50)). Claw holding portions (123) are respectively provided on two opposite side surfaces of the plate-like member (121). The columnar member (122) is a member that extends in the vertical direction from the center of the plate-like member (121). The columnar member (122) is connected to the handle (110).

  Each claw holding part (123) has two claws (123a) as shown in FIG. As shown in FIG. 3, these claws (123a) are formed in a wedge shape so as to follow the cross-sectional shape of the recess (20b). And as shown in FIG. 5, each nail | claw holding | maintenance part (123) engages with the recessed part (20b) of any one side surface of a refrigerant | coolant jacket (20). That is, these claws (123a) correspond to the protrusions of the present invention.

  The claw holding part (123) on the left side in FIG. 3 is formed integrally with the plate member (121). Hereinafter, the left claw holding portion (123) will be referred to as a fixed claw holding portion (123). Further, the right claw holding portion (123) in FIG. 3 can slide in the left-right direction in FIG. Thereby, the claw holding part (123) on the right side can be opened and closed at the engagement position with the cooling mechanism (20) and the position where the engagement is released. More specifically, the right claw holding part (123) is inserted into a sliding hole (121a) provided on the right end surface of the plate-like member (121) and slides into a rod-like sliding rod part (123b). have. The sliding rod portion (123b) has a direction in which the distance from the fixed claw holding portion (123) is narrowed by the spring (123c) provided in the sliding hole (121a) (left direction in FIG. 3). Is being energized. By this urging, the interval between the two claw holding portions (123) is normally in the engagement position. Hereinafter, the right claw holding portion (123) will be referred to as the opening / closing side claw holding portion (123).

  In addition, a heater (121b) made of, for example, a heating wire is embedded in the plate-like member (121). The heater (121b) heats the contact surface with the plate-like member (121), in particular, the refrigerant jacket (20). This heater (121b) corresponds to the heating section of the present invention. In addition, the plate member (121) is provided with a thermostat (121c) as temperature regulating means for regulating the heating temperature by the heater (121b) to a certain temperature or less, for example, depending on the temperature of the plate member (121). The heater (121b) is turned on and off. Although not shown in FIG. 3, the peeling jig (100) is also provided with a switch for manually controlling on / off of the heater (121b).

<Peeling action of refrigerant jacket (20) and heat transfer plate (50)>
In order to peel the heat transfer plate (50) and the refrigerant jacket (20) from each other by the peeling jig (100), first, the peeling jig (100) is fixed to the refrigerant jacket (20). For this purpose, as shown in FIG. 6, the claw (123a) of the opening / closing claw holding part (123) is hooked on the recess (20b) on one side surface (right side surface in the example of FIG. 6) of the refrigerant jacket (20). Thus, the spring (123c) is resisted in the direction parallel to the upper surface of the refrigerant jacket (20) (in this example, the left direction in FIG. 6) so that the gap between the two claw holding portions (123) is widened. The applied force is applied to the handle (110). Thereby, the space | interval of two nail | claw holding | maintenance parts (123) opens more than the space | interval of the recessed part (20b) of both sides | surfaces. That is, the claw (123a) moves to the position where the engagement is released. In this position, the claw (123a) of the fixed claw holding portion (123) can be moved to the side of the recess (20b) on the other side surface (the left side surface in the example of FIG. 6) of the refrigerant jacket (20). . When the horizontal force is relaxed in this state, the distance between the two claw holding portions (123) is narrowed by the force of the spring (123c). That is, the claw (123a) moves to the engagement position. At this position, the recess (20b) of the refrigerant jacket (20) is sandwiched between the claws (123a) of the claw holding portions (123) on both sides.

  Next, when the heater (121b) is energized, the plate-like member (121) portion of the jacket gripping part (120) (particularly the contact surface between the plate-like member (121) and the refrigerant jacket (20)) is heated. The heating temperature of the heater (121b) at this time is regulated to a certain temperature or less by switching on and off of the heater (121b) by the thermostat (121c). That is, unnecessary heat can be prevented from being applied to the power element (33) and the power element (33) is not damaged by the heat.

  The heat of the plate-like member (121) heated by the heater (121b) is conducted to the refrigerant jacket (20) and is applied to the contact surface between the refrigerant jacket (20) and the heat transfer plate (50). Softens sex grease. When the heat conductive grease is softened, the force (adhesion force) for adhering the heat transfer plate (50) and the refrigerant jacket (20) to each other decreases. Then, in such a state that the sticking force is reduced, the force in the direction of separating the heat transfer plate (50) and the refrigerant jacket (20) from each other (referred to as the peeling direction) with respect to the handle (110) When applied (referred to as peeling force), the heat transfer plate (50) and the refrigerant jacket (20) can be peeled from each other.

  As described above, in the present embodiment, since the solidified thermal conductive grease is heated and softened, the sticking force due to the thermal conductive grease is reduced. Further, since the refrigerant jacket (20) is hooked by the claws (123a) to separate the refrigerant jacket (20) and the heat transfer plate (50) from each other, the peeling force can be easily applied. That is, according to the present embodiment, the refrigerant jacket (20) (cooling mechanism) and the heat transfer plate (50) (cooled portion) can be easily separated. And thereby, an electrical component box (40) can be easily removed from a freezing apparatus (for example, outdoor unit), and repair, inspection, etc. can be performed.

<< Embodiment 2 of the Invention >>
FIG. 7 is a front view of a peeling jig (200) according to Embodiment 2 of the present invention. As shown in FIG. 7, the peeling jig (200) is obtained by adding a frame (210) to the peeling jig (100).

  As shown in FIG. 7, the frame (210) is formed by a leg portion (211), a beam portion (212), and a holding portion (213).

  The leg part (211) is two columnar members, and the two columnar parts are connected to each other by a beam part (212) at the upper part thereof. As shown in FIG. 8, the leg portion (211) abuts on a portion to be cooled (more specifically, the heat transfer plate (50)) and fixes the portion to be cooled.

  In addition, a holding portion (213) is formed in the central portion of the leg portion (211). The holding portion (213) is a member that holds the columnar member (122) of the jacket gripping portion (120) so as to be slidable in a direction parallel to the peeling direction (upward in FIG. 7). When the jacket gripping part (120) moves by a predetermined distance in the direction of the beam part (212), the handle (110) of the jacket gripping part (120) is brought into contact with the beam part (212). It has become. That is, the beam portion (212) functions as a displacement regulating means that regulates the displacement of the jacket gripping portion (120) in the peeling direction by abutting against the handle (110). The holding part (213) of the frame (210) can also be used as a displacement restricting means. In this case, the plate-like member (121) of the jacket gripping part (120) is brought into contact with the holding part (213).

<Peeling action of refrigerant jacket (20) and heat transfer plate (50)>
In order to peel the heat transfer plate (50) and the refrigerant jacket (20) from each other by the peeling jig (200), the peeling jig (200) is first fixed to the refrigerant jacket (20).

  For this purpose, as shown in FIG. 8, the claw (123a) of the opening / closing claw holding part (123) is connected to one side surface of the refrigerant jacket (20) in the same manner as the peeling jig (100) of the first embodiment. The gap between the two claw holders (123) is widened by hooking it into the recess (20b). Then, the claw (123a) of the fixed-side claw holding part (123) is moved to the side of the recess (20b) on the other side of the refrigerant jacket (20), and then, as shown in FIG. The interval between the portions (123) is narrowed, and the concave portions (20b) on both side surfaces of the refrigerant jacket (20) are sandwiched between these claw holding portions (123).

  Next, the heater (121b) is energized to heat the contact surface between the plate-like member (121) and the refrigerant jacket (20), and the heat conductive grease applied to the contact surface is softened. Also in the present embodiment, the heating temperature by the heater (121b) is regulated to a certain temperature or less by switching on and off of the heater (121b) by the thermostat (121c).

  Next, in such a state that the heat conductive grease is softened and the sticking force is reduced, a force is applied to the frame (210), and the heat transfer plate is formed by the legs (211) of the frame (210). Hold (50) on the electrical component box (40) side and fix the heat transfer plate (50). When a peeling force is applied to the handle (110) in this state, the heat transfer plate (50) and the refrigerant jacket (20) can be peeled from each other as shown in FIG. At this time, the handle (110) is displaced in the peeling direction with respect to the frame (210). However, if the handle (110) is displaced to some extent, the handle (110) contacts the beam portion (212), and the displacement is restricted at that position. That is, the displacement of the jacket holding part (120) in the peeling direction is restricted.

  As described above, in the present embodiment, the frame (210) is provided and the portion to be cooled (specifically, the heat transfer plate (50)) is fixed, so that it is larger than the peeling jig (100) of the first embodiment. It becomes possible to apply a peeling force.

  Further, since the displacement of the jacket gripping part (120) in the peeling direction is restricted, deformation of the refrigerant pipe (21) when the refrigerant jacket (20) and the heat transfer plate (50) are peeled from each other (for example, the refrigerant pipe (21 ) Can be regulated within a predetermined range. That is, even if a larger peeling force is applied to the refrigerant jacket (20), an excessive force is not applied to the refrigerant pipe (21), and the refrigerant pipe (21) is not damaged.

<< Embodiment 3 of the Invention >>
FIG. 11 is a front view of the peeling jig (300) according to the third embodiment, and shows a state where the peeling jig (300) is placed on the heat transfer plate (50). The peeling jig (300) is different from the peeling jig (200) of the second embodiment in the mechanism for opening and closing the opening / closing claw holding portion (123). Specifically, the peeling jig (300) includes a slider mechanism that moves the open / close claw holding portion (123) to the engagement position by the displacement of the grip portion (120) in the peeling direction.

  More specifically, as shown in FIG. 12, in the opening / closing claw holding portion (123) of the present embodiment, the sliding rod portion (123b) has a slider at the end portion on which the claw (123a) is not formed. The plate for use (310) is integrally formed. The slider plate (310) has a groove (320) extending obliquely from the vicinity of the joint with the sliding rod portion (123b). A cavity is formed in the columnar member (122) of the jacket grip (120), and the slider plate (310) is accommodated in the cavity as shown in FIG. A pin (330) is fixed to the holding part (213) of the frame (210). The pin (330) is fitted in the groove (320) and slides relative to the groove (320). With this configuration, when the jacket grip (120) moves in the peeling direction with the frame (210) fixed (that is, with the pin (330) fixed), the pin (330) and the groove (320) are separated. They slide against each other, and the open / close side claw holder (123) moves toward the engagement position. In this peeling jig (300), as shown in FIG. 11, the opening / closing claw holding portion is moved with the jacket gripping portion (120) moved to the refrigerant jacket (20) side (downward in FIG. 11). The angle of the groove (320) and the position of the pin (330) are set so that (123) comes to the position where the engagement is released. In the present embodiment, the spring (123c) is not provided.

<Peeling action of refrigerant jacket (20) and heat transfer plate (50)>
In order to peel the heat transfer plate (50) and the refrigerant jacket (20) from each other by the peeling jig (300), the peeling jig (300) is first fixed to the refrigerant jacket (20).

  For this purpose, as shown in FIG. 11, with the jacket gripping part (120) moved to the refrigerant jacket (20) side, the opening / closing claw holding part (123) is moved to the position where the engagement is released. Let me. In this state, the columnar member (122) is brought into contact with the upper surface of the refrigerant jacket (20).

  Next, the heater (121b) is energized to heat the contact surface between the plate member (121) and the refrigerant jacket (20), thereby softening the thermally conductive grease applied to the contact surface. Also in the present embodiment, the heating temperature by the heater (121b) is regulated to a certain temperature or less by switching on and off of the heater (121b) by the thermostat (121c).

  Next, in such a state that the heat conductive grease is softened and the sticking force is reduced, a force is applied to the frame (210) and the legs (211) of the frame (210) are used to heat the heat transfer plate. Hold (50) on the electrical component box (40) side and fix the heat transfer plate (50). When a peeling force is applied to the handle (110) in this state, the handle (110) moves in the peeling direction. When the handle (110) moves in the peeling direction, the slider mechanism (320, 330) moves the open / close claw holder (123) to move in the direction in which the refrigerant jacket (20) is sandwiched, that is, in the engagement position. Thereby, the refrigerant jacket (20) is held by the claw (123a).

  Further, when a peeling force is applied, the heat transfer plate (50) and the refrigerant jacket (20) are peeled from each other as shown in FIG. At this time, the handle (110) is displaced in the peeling direction with respect to the frame (210), but also in this embodiment, the handle (110) abuts on the beam portion (212) and the jacket gripping portion ( 120) displacement is regulated.

  As described above, in this embodiment, the slider mechanism (320, 330) that moves the opening / closing claw holding portion (123) to the engagement position by the displacement of the grip portion (120) in the peeling direction is provided. The engagement between the claw (123a) and the refrigerant jacket (20) is also performed at the same time. That is, it is not necessary to separately engage the claw (123a) with the refrigerant jacket (20), so the refrigerant jacket (20) can be easily grasped and the separation operation can be performed efficiently. . That is, repair and inspection performed by removing the electrical component box (40) become easier.

<< Other Embodiments >>
<1> In the above example, the recess (20b) is provided in the refrigerant jacket (20) and the claw (123a) is engaged, but the claw (123a) is engaged with the bottom surface of the refrigerant jacket (20). You may do it. For example, as shown in FIG. 14, the recess (52) having a size for allowing the tip of the claw (123a) to enter the bottom surface of the refrigerant jacket (20) is provided on the upper surface of the heat transfer plate (50) (refrigerant jacket (20)). And the bottom surface of the refrigerant jacket (20) is hooked with the claws (123a).

  <2> In addition, the refrigerant jacket (20) can be provided with a concave portion (20b) on the side surface as shown in FIG. 15, for example, instead of providing the concave portion (20b) on the bottom surface.

  <3> The shape of the leg (211) of the frame (210) is not limited to the above example. For example, as shown in FIG. 16, it is also possible to form in a pin shape penetrating through holes respectively formed in the plate-like member (121) and the refrigerant jacket (20).

  <4> The heat transfer plate (50) is not necessarily essential. That is, the jig of the present invention can also be applied when the power element (33) is attached to the refrigerant jacket (20) via a heat conduction auxiliary material (thermal conductive grease). FIG. 17 is a diagram showing a configuration example of the peeling jig in this case. In this example, the leg portion (211) of the frame (210) is formed in a pin shape that penetrates the through hole formed in the refrigerant jacket (20), and the leg portion (211) is connected to the power element (33) during the peeling operation. ). Also in this case, if the recess (20b) is formed in the refrigerant jacket (20), the claw (123a) can be hooked on the recess (20b) to apply a peeling force.

  <5> The position where the heater (121b) is provided is not limited to the plate-like member (121). For example, as shown in FIG. 18, it can also be provided on the leg (211) of the frame (210). In this case, the heat transfer plate (50) is heated by the heater (121b), and the heat conduction auxiliary material (heat conductive grease) is softened.

  <6> The spring (123c) provided as the biasing means in the first embodiment or the like may be omitted. When the spring (123c) is omitted, the opening / closing claw holding portion (123) is manually opened and closed.

  <7> Moreover, the heating wire employ | adopted as a heater (121b) (heating part) is an illustration, and can employ | adopt various heaters. Similarly, a thermostat employed as the temperature regulating means is also an example, and the present invention is not limited to this.

  <8> Each embodiment is also applied to a refrigeration apparatus in which a material that softens when heat is applied, such as a heat conductive double-sided adhesive tape, a heat conductive sheet, or a heat conductive adhesive, as the heat conduction auxiliary material. The jig can be used. In short, the jig of the present invention can be used for peeling between the cooling mechanism and the part to be cooled which are stuck together by the heat conduction auxiliary material softened by heat.

  The present invention is useful as a jig used for repair or inspection in a refrigeration apparatus.

It is a figure showing the periphery of the electric circuit (30) in the freezing apparatus in which the jig | tool for peeling which concerns on this embodiment is used. It is a figure which shows the structural example of a refrigerant | coolant jacket (20). It is a front view of the peeling jig | tool (100) which concerns on Embodiment 1 of this invention. It is a top view of the jig | tool for peeling (100) which concerns on Embodiment 1 of this invention. It is the figure which planarly viewed the state which mounted the jig | tool for peeling (100) on the heat exchanger plate (50). It is a figure explaining the engagement procedure by a nail | claw (123a). It is a front view of the jig | tool for peeling (200) which concerns on Embodiment 2 of this invention. It is a figure which shows the state which mounted the jig | tool for peeling (200) on the heat exchanger plate (50). It is a figure which shows the state which pinched | interposed the refrigerant | coolant jacket (20) with the two nail | claw holding | maintenance parts (123) of the jig | tool for peeling (200). It is a figure which shows the state which peeled the refrigerant | coolant jacket (20) from the heat exchanger plate (50) with the peeling jig | tool (200). It is a front view of the peeling jig | tool (300) which concerns on Embodiment 3, and has shown the state which mounted the peeling jig | tool (300) on the heat exchanger plate (50). It is a figure explaining a slider mechanism, and has shown the structure of the slider mechanism by the side of an opening-and-closing side nail holding part (123). It is a figure which shows the state which peeled the refrigerant | coolant jacket (20) from the heat exchanger plate (50) with the peeling jig | tool (300). It is a figure explaining the structural example, such as a heat exchanger plate (50) in the case of engaging a nail | claw (123a) with a refrigerant | coolant jacket (20) bottom face. It is a figure which shows the other structural example of the recessed part (20b) formed in a refrigerant | coolant jacket (20). It is a figure which shows the other structural example of the leg part (211) of a frame (210). It is a figure which shows the structural example of the jig | tool for peeling when the refrigerant | coolant jacket (20) and the power element (33) are contact | abutting. It is a figure which shows the other example of arrangement | positioning of a heater (121b).

Explanation of symbols

100 Jig for peeling 20 Refrigerant jacket (cooling mechanism)
20b recess 33 power element (electrical component)
50 Heat transfer plate 120 Jacket gripping part (grip part)
121b Heater (heating part)
121c thermostat (temperature regulation means)
123a Claw (projection)
123c Spring (biasing means)
200 Peeling jig 211 Leg (fixed part)
212 Beam (displacement restricting means)
300 Peeling jig 320 Groove 330 Pin

Claims (10)

A refrigerant circuit that performs a vapor compression refrigeration cycle by circulating a refrigerant, a cooled part (33, 50) that includes an electrical component (33) as a cooled object, and heat conduction that assists heat conduction between the two members In a refrigeration apparatus comprising: an auxiliary material; and a cooling mechanism (20) that is in close contact with the cooled portion (33, 50) via the heat conduction auxiliary material and cools the cooled object with the refrigerant. A peeling jig for peeling the close contact between the cooled portion (33, 50) and the cooling mechanism (20),
A heating unit (121b) for heating the heat conduction auxiliary material;
A grip portion (120) for gripping the cooling mechanism (20);
A peeling jig characterized by comprising: The peeling jig according to claim 1,
The cooled portion (33, 50) includes a heat transfer plate (50) that mediates heat exchange between the electrical component (33) and the cooling mechanism (20), and the heat transfer plate (50) A peeling jig characterized in that it is in close contact with the mechanism (20) via the heat conduction auxiliary material. In the peeling jig according to claim 1 or 2,
Further, when the close contact between the cooled part (33, 50) and the cooling mechanism (20) is peeled off, the cooled part (33, 50) is brought into contact with the cooled part (33, 50). A stripping jig comprising a fixing portion (211) for fixing. In the peeling jig according to claim 3,
Furthermore, a displacement regulating means (212) that regulates displacement of the gripping part (120) in a direction of separating the cooling mechanism (20) from the cooled part (33, 50) by contacting the gripping part (120). ). In any one peeling jig in any one of Claims 1-4,
The grip portion (120) is engaged with a recess (20b) formed in the cooling mechanism (20), or is engaged with a surface facing the cooled portion (33, 50) in the cooling mechanism (20). A stripping jig comprising a protruding portion (123a). The peeling jig according to claim 5,
The peeling jig, wherein the protrusion (123a) opens and closes to an engagement position with the cooling mechanism (20) and a position to release the engagement. The peeling jig according to claim 6,
The gripping part (120) includes a biasing means (123c) that biases the protrusion (123a) toward the engagement position. The peeling jig according to claim 6,
The grip part (120) disengages the protrusion (123a) by the displacement of the grip part (120) in a direction to separate the cooled parts (33, 50) and the cooling mechanism (20) from each other. A stripping jig comprising a slider mechanism (320, 330) for moving to a matching position. In any one peeling jig in any one of Claims 1-8,
Furthermore, the peeling jig | tool provided with the temperature control means (121c) which controls the heating temperature by the said heating part (121b) below to a fixed temperature. In any one peeling jig in any one of Claims 1-9,
The peeling jig, wherein the heat conduction auxiliary material is any one of heat conductive grease, a heat conductive double-sided adhesive tape, a heat conductive sheet, and a heat conductive adhesive.

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