DE112013005735T5 - Mounting structure for a heat exchanger - Google Patents

Abstract

A fixing portion (30) for fixing an evaporator (10) to an air conditioning case is disposed on a surface surrounded by a first side (31) and a third side (33) of the evaporator (10). The fixing portion (30) is disposed at a position other than four corners of a heat exchanging surface (11a) of the evaporator (10) except for a position corresponding to a vibration antipodal portion of a natural vibration mode of the evaporator (10). Thus, since the fixing portion (30) is disposed avoiding the position which easily vibrates, the evaporator (10) is fixed to the air conditioning case by a portion which is hard to be vibrated. Vibration of the evaporator (10) is thus transmitted less to the air conditioning case from the attachment portion (30).

Description

Cross-reference to affected application

This application is based on the Japanese Patent Application No. 2012-262209 , filed on Nov. 30, 2012, the disclosure of which is incorporated herein by reference.

Technical area

The present invention relates to a mounting structure for a heat exchanger in which a refrigerant flows.

Background-stand-the-art

Patent Literature 1 describes a cooling evaporator in an air conditioning unit for a vehicle, and the cooling evaporator is mounted in a housing of an air conditioning unit by elastic members at four corners of the evaporator. The elastic member absorbs vibration from the evaporator. When the effect of absorbing vibration will be described in more detail, the evaporator is coupled to a compressor in an engine compartment of the vehicle through a piping system of a refrigerant, and the compressor is mounted on an engine of the vehicle and driven by the engine The compressor basically vibrates integrally with the engine. The compressor itself vibrates due to pulsation, which is generated when the compressor discharges a refrigerant. The vibration of the compressor propagates toward the evaporator, which is disposed inside the vehicle interior, through the refrigerant piping. Under these circumstances, the evaporator is carried by the elastic members, and the vibration which is propagated toward the evaporator is absorbed by the elastic members. The vibration of the evaporator is restricted to be transmitted to the casing of an air conditioning unit, to be amplified and to become an abnormal noise.

Patent Literature 2 describes a heat exchanger in an air conditioning apparatus for a vehicle in which other components of a non-passage than the refrigerant passage are supported by a housing. Since the components of a non-passage do not form a flow path for a heat exchange medium other than the components which form a passage, the components of a non-passage are not directly vibrated by the pulsation of the heat exchange medium and are not directly affected by a collision of the heat exchange medium vibrated. When the housing carries portions which are not directly vibrated, the vibration from the heat exchanger is hardly transmitted to the housing.

Prior Art Literature - Patent Literature

• Patent Literature 1: JP 2006-335189 A
• Patent Literature 2: JP 2012-1124 A

Summary of the invention

In the conventional art described in Patent Literature 1, the elastic members are engaged at the four corners. However, the elastic members mounted on the housing of the evaporator increase the number of components that make up the evaporator. This leads to an increase in the number of processes for producing the evaporator and leads to a decrease in productivity.

In the conventional art described in Patent Literature 2, the heat exchanger is constructed to be integral with the components of a non-passage and the components constituting a passage while the components of a non-passage are supported. When the passage-forming components vibrate, the vibration is also propagated to the component of non-passage. As a result, the effect of suppressing the transmission of the vibration is small as the vibration propagates to the case.

The present invention aims to provide a fixing structure for a heat exchanger capable of reducing transmission of vibration to an exterior with a simple configuration.

According to the present invention, at least one attachment portion provided for attachment to a housing is attached to at least one of a surface surrounded by a first side and a third side and a surface that is from a second side and the third side surrounded, arranged. In the heat exchanger mounting structure, the mounting portion is disposed at a position other than four corners of a heat exchanging surface except for a position corresponding to a vibration anti-vibration part of a natural vibration mode of the heat exchanger.

According to the present invention, the heat exchanger is fixed to the housing, which is arranged to the outside. At least one attachment portion provided to be fixed to the housing is at least one of the surface surrounded by the first side and the third side and the surface surrounded by the second and third sides arranged. Further, the fixing portion is disposed at the position other than the four corners of the heat exchanging surface, and the position is also a position (hereinafter referred to as "position except for a vibration abutting part") except for a position which is a vibration abutting part of a natural vibration mode of the heat exchanger corresponds. It is difficult to vibrate at the position except for the four corners except for the vibration abdominal part. In other words, the largest vibration occurs at the antinode part, and it has been found by far-reaching investigation results of the Applicant that the four corners are also positions which tend to vibrate, as in the antinode part. Since the fixing portion is disposed avoiding the position which tends to vibrate, the heat exchanger is fixed to the housing at a portion which is less susceptible to vibrate. This makes it difficult to spread the vibration from the heat exchanger from the attachment portion to the housing. The vibration from the heat exchanger to the housing can be suppressed with a simple configuration for changing the position of the attachment portion. As a result, noise caused by the vibration transmitted from the heat exchanger to the housing can be suppressed.

Brief description of the drawings

1 FIG. 15 is a perspective view illustrating an evaporator according to a first embodiment. FIG.

2 FIG. 12 is a view illustrating a vibration state in respective natural vibration modes.

3 Fig. 15 is a diagram showing an amplitude in a longitudinal direction.

4 is a front view illustrating a simplified evaporator.

5 FIG. 13 is a diagram illustrating a relationship between a frequency and an inertance.

6 Fig. 10 is a diagram showing an entire inertance within a frequency band

7 FIG. 16 is a front view illustrating an air conditioning apparatus for a vehicle according to a second embodiment. FIG.

8th Fig. 15 is a diagram showing an amplitude in a width direction.

9 FIG. 10 is a front view illustrating an evaporator according to a third embodiment. FIG.

10 FIG. 10 is a front view illustrating an evaporator according to a fourth embodiment. FIG.

Description of embodiments

Hereinafter, several embodiments for carrying out the present invention will be described with reference to the drawings. In each embodiment, parts that correspond to circumstances described in a previous embodiment may be denoted by identical reference numerals, or a character may be added to a previous reference number for abbreviating the respective description. When a part of the configuration is described in the respective embodiments, other parts of the configuration are the same as those in the embodiment described above. Not only the combination of parts which is specifically described in the respective embodiments, but also the part Combination of the respective embodiments can be carried out, especially if there is no conflict in the combination.

First embodiment

A first embodiment of the present invention will be described with reference to FIGS 1 to 6 to be discribed. An evaporator 10 is a heat exchanger, which is arranged in a not-shown refrigeration cycle, in which a refrigerant is compressed by a compressor to have a high temperature and a high pressure, and is cooled by a radiator by heat radiation. A refrigerant is further reduced in pressure by a pressure reduction device to have a low temperature and a low pressure, and the refrigerant is passed through the evaporator 10 evaporated. As it is in the 1 is shown, the evaporator includes 10 according to this embodiment, a core portion 11 , an upper tank unit 12 and a lower tank unit 13 , The respective components are soldered together.

The core section 11 is by alternately stacking several flat tubes 14 and several corrugated ribs 15 formed on each other. A side plate 16 is outside of the outermost corrugated ribs 15 on both sides in a stacking direction thereof (X direction in the 1 ) arranged. A refrigerant, which is an internal fluid from the core portion 11 is flows along a longitudinal direction (Y direction in the 1 ) from the flat tubes 14 , When it is assumed that a flow direction of the refrigerant is a width direction Y of the evaporator 10 is a ventilation direction in the core section 11 a thickness direction Z of the evaporator 10 and a direction (stacking direction) orthogonal to the width direction Y and the thickness direction Z is a longitudinal direction X of the evaporator 10 , The evaporator 10 is arranged in a vehicle by setting the width direction Y as the vertical direction.

The flat tubes 14 are pipe members formed by bending a thin strip plate made of aluminum, and the cross section perpendicular to the flow direction of the refrigerant is formed in a flat shape. The flat tubes 14 may integrally define a plurality of refrigerant passages extending in the longitudinal direction by extrusion-molding an aluminum material. Alternatively, two thin plates made of aluminum may be bonded together to have a hollow shape. A thickness of the flat tube 14 is for example 0.2 mm.

The wavy rib 15 is formed by exposing a thin strip plate made of aluminum, in which both surfaces are pre-coated with a solder filler metal or solder, a rolling process in a serpentine shape (waveform). The wavy rib 15 has multiple louvers (not shown) formed by cutting and bending for increasing the efficiency of heat exchange. A thickness of the corrugated rib 15 is for example 0.05 mm.

The side plate 16 is as a reinforcing member at the core portion 11 educated. The side plate 16 is formed by pressing a plate material made of aluminum, which is a bare material on which a Lötfüllmetall is not sheathed. Both ends of the side plate 16 in a longitudinal direction (width direction Y) are formed in a planar shape. A middle section of each side plate 16 is formed to have a U-shaped cross section, which is outwardly in the stacking direction of the flat tubes 14 and the ribbed ribs 15 is open. The side plate 16 is at the corrugated rib 15 soldered. A thickness of the side plates 16 is for example 1 mm.

The upper tank unit 12 is in two parts in a longitudinal direction from the flat tube 14 divided to include a header plate adjacent to the flat tube and a header tank away from the flat tube. Each of the header tank and the header plate has a semicircular or rectangular cross-sectional shape and is formed by pressing a flat aluminum material.

A solder fillet metal is pre-coated on both surfaces of the header tank and an inner surface of the header plate. The header tank and the header plate are fitted with each other and brazed together to form a cylindrical body in which two internal spaces in the flow direction of the blowing air (thickness direction Z of the evaporator 10 ) are aligned. A cover formed by exposing a flat aluminum material to press working is soldered to an opening portion provided at one end of the upper tank unit 12 in a longitudinal direction thereof (both ends in the longitudinal direction X), thereby closing the opening portion. The thickness of the upper tank unit 12 and the lower tank unit 13 is for example 1 mm.

Further, two separators (not shown) are located at substantially the center of the upper tank unit 12 in the longitudinal direction X, and separate the respective inner spaces in the longitudinal direction from the upper tank unit 12 (Longitudinal direction X from the evaporator 10 ). The two inner spaces of the upper tank unit 12 , which are arranged in the flow direction of the blast air, communicate with each other through a plurality of communication passages, not shown, in an area of the upper tank unit 12 on a right side of the separator in communication.

The lower tank unit 13 has a similar structure to that of the upper tank unit 12 and forms a cylindrical body, which includes a header tank and a collector plate. A cover is provided at an opening portion at both ends thereof in the longitudinal direction. Unlike the upper tank unit 12 For example, configurations corresponding to the separator and the communication passage are not in the lower tank unit 13 intended.

An insertion hole of a flat tube, which is not shown, and an insertion hole of a side plate, which is not shown, are in a wall surface (wall surface of the header plate) of the upper and lower tank units adjacent to the core portion 11 at the same divisions as the divisions of the flat tubes 14 and the side plates 16 provided in the longitudinal direction X. The end of the flat tube 14 in the longitudinal direction and the end of the side plate 16 in the longitudinal direction are inserted and soldered in the respective insertion holes. With the above configuration stands the flat tube 14 with the inner space of the upper and lower tank unit 12 . 13 in communication, and the ends of the side plate 16 in the longitudinal direction are carried and fastened by / to the upper and lower tank units, respectively 12 and 13 ,

A connection block 17 (Outlet / inlet part for refrigerant) is at one end of a left side of the upper tank unit 12 in the 1 soldered and has an inlet opening 18 in which a refrigerant flows, and an outlet port 19 from which a refrigerant flows out. From the inner spaces of the upper tank unit 12 stands the inlet opening 18 with the interior of the tank unit 12a on a downstream side in the air flow in the 1 in communication and stands the outlet opening 19 with the interior of the tank unit 12b on the upstream side in the air flow in the 1 in communication.

The flat tubes 14 are arranged in two rows so that the upstream row of a flat tube and the downstream row of a flat tube are aligned in a flow of blown air, which is an outer fluid, in accordance with the arrangement of the upper and lower tank units 12 . 13 , At the evaporator 10 which is formed as described above, after a refrigerant in the tank unit 12a from the inlet opening 18 on the downstream side of the upper tank unit 12 In the air flow, the refrigerant vertically inverts U and flows into the downstream row of a flat tube and returns to a right area from the upper tank unit 12 in the 1 back. The refrigerant flows from the upper tank unit 12a (right tank unit) on the downstream side in the air flow into the upper tank unit 12b (right tank unit) on the upstream side in the air flow. The refrigerant passes through the upstream row of a flat tube, performs a vertical U-turn in the same manner, and returns to the upper tank unit 12b on the upstream side in the air flow back. Then, finally, the refrigerant flows from the outlet port 19 out. During this operation, the evaporator evaporates 10 the refrigerant, thereby cooling the blown air by a latent heat of evaporation.

A mounting structure of the evaporator 10 will be described. The evaporator 10 is mounted in an air conditioning case, which forms an air conditioning device for a vehicle. The air conditioning case (not shown) includes a ventilation passage therein, and an outside air inlet port and an inside air inlet port, which are air suction ports, are provided on a side of the ventilation passage. A bubble opening is defined on the other side of the ventilation passage, and the conditioned air is blown into the interior of the vehicle from the bubble opening. The air conditioning case is formed of a plurality of case members, and a material of the case member is, for example, a resin molded product such as polypropylene.

The evaporator 10 is arranged to intersect with the ventilation passage in the air conditioning case as a whole, and all of the blown air passes through the evaporator 10 therethrough. The evaporator 10 , which is described above, functions as a heat exchanger which cools the blown air before flowing into a cold air passage by absorbing heat by the refrigerant flowing in the evaporator 10 during cooling operation.

As it is in the 1 is shown, the evaporator 10 a rectangular shape of a parallelepiped. If the evaporator 10 As the rectangular shape of a parallelepiped is considered, it is assumed that one side of the evaporator 10 which extends in the longitudinal direction X, a first side 31 is one side of the evaporator 10 which extends in the width direction Y, a second side 32 is and one side of the evaporator 10 which extends in the thickness direction Z, a third side 33 is. In this embodiment, a length is from the first side 31 longest, and a length from the third page 33 is the shortest surface from the first page 31 and the second page 32 is surrounded, forms a surface of the core portion 11 and corresponds to a heat exchange surface 11a in which heat is exchanged between the refrigerant and the air.

In this embodiment, a fixing structure of the evaporator 10 formed under a concentrated attention of a noise, which by a vibration propagation from the evaporator 10 causing the air conditioning case, which is one of the causes of one Noise is. More particularly, attention will be paid to the natural vibration mode of the evaporator 10 concentrated to form the attachment structure to the propagation of a vibration from the evaporator 10 to suppress the air conditioner housing.

The noise caused by the spread of the evaporator 10 is caused to the air conditioner housing is limited to 1000 Hz or lower. As it is in the 2 and 3 is shown, the evaporator 10 the natural vibration mode in this frequency band, and the kind of vibration is different depending on the vibration mode. In the 3 Similarly, a second order mode corresponds to 241 Hz, a third order mode corresponds to 367 Hz, a fourth order mode corresponds to 677 Hz, and a fifth order mode corresponds to 865 Hz Axis of the ordinate in the 3 returns a dimensionless value with the maximum value of amplitude greater than 1, which is referred to as the "vibration level". The deformation, which in the 2 is represented by the shape of the evaporator 10 regardless of physical properties.

The vibration-inducing force of the vibration mode (sum of the vibration modes) is in the 3 shown in sections where the amplitude is greater, and in sections where the amplitude is smaller, which are present on upper and lower sides, on front and rear sides and on right and left sides. In other words, when a portion where the sum of the vibration modes is the lowest is held, the transmission of vibration from the evaporator can be maintained 10 be minimized to the air conditioning housing. Hereinafter, the large amplitude may be referred to as the "antinode", and the small amplitude may be referred to as "the vibronic node".

In a conventional state of the art, as by the imaginary lines 21 in the 4 is specified, the evaporator 10 held at four corners (corners of a square). In this holding method, since the antinode of the evaporator 10 held, the transmission of a vibration from the evaporator 10 to the air conditioning case, and a reduction in NV (noise vibration) is insufficient. In this embodiment, therefore, in order to reduce the noise vibration NV, a structure is required for holding positions indicated by the dashed lines 22 are specified in the 4 are shown.

More precisely, a mounting portion 30 for attachment to at least one housing on at least one of a surface thereof from the first side 31 and the third page 33 is surrounded (hereinafter also referred to as "upper and lower surfaces"), and a surface arranged, which from the second side 32 and the third page 33 is surrounded (hereinafter also referred to as "right and left surfaces"). In this embodiment, two attachment portions are of the upper and lower surfaces 30 arranged on the lower surface. As it is in the 1 and 4 is shown, the attachment portion 30 at a position except for the four corners in the heat exchange surface 11a from the evaporator 10 and with the exception of a position corresponding to the anti-vibration part (refer to FIGS 3 ) in the natural vibration mode of the evaporator 10 available. The attachment section 30 is therefore arranged avoiding a center and both ends (four corners) from the first side 31 , In other words, the attachment portion 30 at a position except for the above-mentioned four corners such that the amplitude of the self-oscillation mode of the evaporator 10 is less at the position than at the four corners.

If further, a length from the first page 31 is defined as L, is preferably a position of the attachment portion 30 prefers a position which is separated by 0.25 L ± 0.05 L and a position which is 0.75 L ± 0.05 L away from an end from the first side 31 , In the present specification, 0.25 L has the meaning of 0.25 × L and a case in which numbers and L are continuously written to have the same kind of meaning. In other words, the attachment portion 30 at least one of a range of 0.2 L to 0.3 L and a range of 0.7 L to 0.8 L from the end of the first side 31 arranged. The positions of the attachment section 30 correspond to areas defined by imaginary lines in the 3 are surrounded. In other words, the attachment portion 30 at the position (so-called vibration node) where the composite vibration mode of not higher than 1000 Hz is minimum.

The attachment section 30 is defined by a projecting portion which is downwardly from the lower tank unit 13 protrudes. The evaporator 10 is attached to the air conditioning case in a state in which the attachment portion 30 is pressed against an inner wall of the air conditioning case. An elastic member such as a rubber is between the attachment portion 30 and the Air conditioning housing used. With the insertion of an elastic member, the vibration generated by the attachment portion 30 is transferred to the air conditioner housing, more attenuated. The evaporator 10 enters with the air conditioner housing in a section other than the attachment portion 30 in contact, however, is on the air conditioning case at the attachment portion 30 attached to transmit the vibration. Therefore, the other contact portions with the air conditioning case reach a degree of merely carrying the evaporator 10 in contact.

The attachment section 30 is disposed at a position where a frequency of the vibration mode of the evaporator 10 is different from a natural frequency of a wall surface of the air conditioning case. The natural frequency of the air conditioner housing differs depending on a location. When the attachment section 30 is disposed at the position where the natural frequency of the air conditioner housing is the same as the frequency of the vibration mode of the evaporator 10 , even if the vibration, which comes from the evaporator 10 is transmitted, is attenuated, the air conditioner housing strongly in vibration. This is because the effect of reducing the noise vibration NV becomes low.

Subsequently, examination results will be described by comparing the mounting structure of the evaporator 10 According to this embodiment, a fixing structure of a comparative example is obtained. In the fixing structure of the embodiment, the evaporator is 10 at the positions of 0.25 L and 0.75 L at each of the upper tank unit 12 and the lower tank unit 13 attached. In the fixing structure of the comparative example, the evaporator is fixed at the four corners.

In the examination, in addition to the evaporator, an expansion valve is mounted on an air conditioning apparatus for a vehicle, and a vibration is excited in the thickness direction Z relative to the expansion valve at nine kinds of respective frequencies, which are in the 5 ie 160 Hz, 200 Hz, 250 Hz, 315 Hz, 400 Hz, 500 Hz, 630 Hz, 800 Hz and 1000 Hz. In vibration, a shaker or shaker (product name: Integral Shaker, which is manufactured by LMS International n. V.).

The inertance is at a contact portion of the air conditioner housing with the attachment portion 30 is detected as a detection position using a piezoresistive vibration acceleration sensor (Model No. 352C22 manufactured by PCB). The examination conditions in the 5 and 6 are identical to each other. The 5 represents the inertances at the respective frequencies, and the 6 represents a totality of inertances at 200 Hz to 1 kHz.

As it is in the 5 12, it has been found that the inertance at all the frequencies in the embodiment is lower than that in the comparative example. As a result, it has been found that the effect of reducing the noise vibration NV is greater in the embodiment compared to the comparative example. As it is in the 6 In the embodiment, the entirety of the inertances is lower at 200 Hz to 1 kHz. Therefore, it has been found that the effect of reducing the noise vibration NV is greater in the embodiment compared to the comparative example. How to get it out of the 5 and 6 understands, it is obvious that the mounting structure of the evaporator 10 according to this embodiment has the effect of reducing the noise vibration NV.

As described above, the evaporator is 10 according to this embodiment, attached to the air conditioner housing, which is arranged outside. Two fastening sections 30 for attaching the evaporator 10 on the air conditioning case are arranged on the surface, which from the first side 31 and the third page 33 is surrounded. Furthermore, the attachment section 30 at the position except for the four corners of the heat exchange surface 11a and with the exception of the position corresponding to the vibration belly portion of the natural vibration mode of the evaporator 10 corresponds, arranged. The position except for the four corners and the vibration abdominal part is a position where vibration is difficult to occur. In other words, the vibration belly part is the position that vibrates the most, and the four corners are also prone to vibrate. Since the attachment section 30 is provided under the avoidance of the positions where the vibration is easily generated, the evaporator is attached to the air conditioning case at portions which are hard to vibrate. This makes the vibration of the evaporator difficult 10 to the air conditioner housing through the attachment portion 30 transferred to. With a simple configuration for changing the position of the mounting section 30 can the Schwingungsübertagung of the evaporator 10 be prevented on the air conditioner housing. As a result, the noise caused by vibration from the air conditioner case can be suppressed while the evaporator 10 vibrates.

In this embodiment, the attachment portion is preferably 30 at the position except for the four corners of the heat exchange surface 11a such that the amplitude of the natural vibration mode of the heat exchanger at the position is less than the amplitude at the four corners. When the evaporator is mounted at the position where the amplitude is smaller than at the four corners, the vibration transmitted to the air conditioning case can be suppressed compared with the conventional art where the evaporator is at the four corners is attached. As a result, the effect of reducing the noise vibration NV can be achieved.

The position at which the attachment portion 30 is more preferably a position at which the composite vibration mode of not higher than 1000 Hz becomes minimum. The noise caused by the spread of the evaporator 10 is caused to the air conditioning apparatus for a vehicle is limited to 1000 Hz or lower. Therefore, the evaporator is fixed at the position where the composite vibration mode of not higher than 1000 Hz is minimum, thereby being able to further suppress the vibration transmitted to the air conditioning case.

The attachment section 30 is disposed at a position where a frequency of the vibration mode of the evaporator 10 is different from the natural frequency of a wall surface of the air conditioning case. The natural frequency of the air conditioner housing differs depending on a location. When the attachment section 30 is disposed at a position where the natural frequency of the air conditioning case is the same as the frequency of the vibration mode of the evaporator 10 , even then, during the vibration, which comes from the evaporator 10 is transmitted, is attenuated, the air conditioner housing strongly in vibration. The attachment section 30 is therefore located at a position where the frequency of the vibration mode of the evaporator 10 is different from the natural frequency of the wall surface of the air conditioning case, thereby being able to restrict the effect of reducing the noise vibration NV from being lowered from the air conditioner case due to the natural frequency.

Further, in this embodiment, if the length is from the first side 31 is defined as L, the attachment portion 30 at a position separated by 0.25 L ± 0.05 L and at a position separated by 0.75 L ± 0.05 L from the end of the first side 31 arranged. As it is in the 3 are shown, the position of 0.25 L and the position of 0.75 L positions of nodes. Since the attachment section 30 is arranged in the vicinity (± 0.05 L) from the positions of the nodes of vibration, the effect of reducing the noise vibration NV can be achieved, as described above.

In other words, in this embodiment, for the purpose of reducing the noise vibration NV in the vehicle air conditioning apparatus, attention is paid to the vibration mode of the evaporator 10 focused, and the mounting position of the evaporator 10 is optimized to prevent the propagation of vibration to the air conditioning device. Even more accurate is the evaporator 10 at the position except the vicinity of the vibro-belly parts of the evaporator 10 fixed, thereby being able to reduce the noise vibration NV in the air conditioning apparatus. Since the transmission of a major vibration mode of the evaporator 10 on the air conditioner housing by pressing the vibration nodes of the evaporator 10 can be suppressed, the noise vibration NV can be reduced in the air conditioning device for a vehicle.

Second embodiment

A second embodiment of the present invention will be described with reference to FIGS 7 and 8th to be discribed. The 7 illustrates an air conditioning device for a vehicle, and an evaporator 10A is shown as an element forming the air conditioning device. The evaporator 10A , which forms the air conditioning device used in the 7 is integral with an expansion valve 40 intended. The evaporator 10A is with a discharge side of the expansion valve 40 connected in a refrigeration cycle device, and a refrigerant, which through the expansion valve 40 reduced in pressure, flows into the evaporator 10A , In the present embodiment, the attachment portion is 30 arranged in six places. The respective attachment section 30 is formed by a projection part in a similar manner to the first embodiment.

As it is in the 7 is shown, the fastening portions 30 in each of an upper tank unit 12 and a lower tank unit 13 at positions separated by 0.25 L ± 0.05 L and positions separated by 0.75 L ± 0.05 L from one end of a first side 31 arranged. Because the positions of the attachment sections 30 in the first page 31 they may be the same as those in the first embodiment described above the same operations and effects are achieved.

The widening are the attachment sections 30 on respective side plates 16 arranged, which are arranged at both ends in the longitudinal direction X. More precisely, if it is believed that a length is from a second side 32 W is the attachment sections 30 preferably arranged at positions which are from one end of the second side 32 separated by 0.5 W ± 0.05 W. In the present specification, 0.5 W has the meaning of 0.5 × W. Regarding the second page 32 is how it is in the 8th is shown, a position of 0.5 W, a position which a vibration node in the second side 32 forms. Because the attachment sections 30 are arranged in the vicinity (± 0.05 W) from the position of the vibration node, the effect of reducing the noise vibration NV as well as the position of the mounting portions 30 from the first page 31 be achieved. In this embodiment, since the evaporator 10 attached at six places in the outer perimeter, the evaporator 10 even more firmly attached to the air conditioner housing.

Third embodiment

A third embodiment of the present invention will be described with reference to FIGS 9 to be discribed. In the 9 is a configuration of a mounting portion 30B from that at the evaporator 10 different from the first embodiment. The attachment section 30B of the evaporator 10B according to this embodiment is defined by a projecting portion, which of a lower tank unit 13 Outstanding as it is described above. Furthermore, the projection portion is covered with an elastic member, for example, a rubber for vibration damping.

The attachment section 30B is integrally formed with the projection portion and the elastic member, thereby being able to securely bring the elastic member into contact with the air conditioning case. With the above configuration, the vibration caused by the attachment portion 30B is transferred to the air conditioner housing, further attenuated.

Fourth embodiment

A fourth embodiment of the present invention will be described with reference to FIGS 10 to be discribed. In the 10 is the position of the attachment section 30 from that at the evaporator 10 the first embodiment, which is described above, different. The positions of the attachment sections 30 according to this embodiment are on respective side plates 16 arranged, which are arranged at both ends in the longitudinal direction X. More precisely, if it is believed that a length is from a second side 32 W is the attachment sections 30 preferably at positions separate from one end from the second side 32 arranged by 0.5 W ± 0.05 W (positions which are defined by imaginary lines 21 in the 10 are indicated). Regarding the second page 32 is how it is in the 8th is shown, a position of 0.5 W, a position which a vibration node in the second side 32 forms. Since the attachment section 30 is arranged in the vicinity (± 0.05 W) from the positions of the nodes of vibration, the effect of reducing the noise vibration NV can be achieved.

Other embodiments

In the foregoing, the preferred embodiments of the present invention are described herein. However, the present invention is not intended to be limited to the embodiments described above, and various modifications may be made so long as they do not depart from the gist thereof.

The structures of the embodiments described above are merely examples, and the scope of the present invention is not intended to be limited to the above described scope. The scope of the present invention is set forth in the claims and encompassed equivalent meanings to those of the claims and all changes within the scope.

In the first embodiment described above, the attachment portions are 30 but it is not limited to two places, and at least one fixing portion 30 can be on at least one of a surface, which from the first page 31 and the third page 33 is surrounded, and a surface, which from the second side 32 and the third page 33 surrounded, be arranged. Therefore, for example, the attachment portion 30 on only the side plate 16 be arranged.

In the first embodiment described above, the evaporator forms 10 the air conditioning apparatus for a vehicle, but it is not limited to the vehicle, and the evaporator can form domestic air conditioning devices. The present invention is not limited to being applied to the evaporator, but may be applied to a radiator or a condenser when the heat exchanger has a rectangular shape of a parallelepiped in which a refrigerant flows.

Claims (5)

Fixing structure for fixing a heat exchanger ( 10 . 10A . 10B . 10C ) on a housing, wherein the heat exchanger has a rectangular shape of a parallelepiped, in which refrigerant flows, wherein, when sides which form the heat exchanger, which has the rectangular shape of a parallelepiped, a first side ( 31 ), a second page ( 32 ) and a third page ( 33 ), the length of the third side is the shortest, a surface which is surrounded by the first side and the second side, a heat exchange surface ( 11a ) of the heat exchanger, wherein the attachment structure comprises: at least one attachment section ( 30 . 30B ) disposed on at least one of a surface surrounded by the first side and the third side and a surface surrounded by the second side and the third side, the attachment portion being at a position other than four corners of the heat exchanging surface and with the exception of a position corresponding to a vibration abutting part of a natural vibration mode of the heat exchanger is arranged. The fixing structure according to claim 1, wherein the fixing portion is disposed at the position where an amplitude of the natural vibration mode of the heat exchanger is smaller than an amplitude at the four corners except for the four corners of the heat exchange surface. The fixing structure according to claim 1, wherein the fixing portion is disposed at the position where a composite vibration mode of not higher than 1000 Hz is minimum. Fixing structure for fixing a heat exchanger ( 10 . 10A . 10B . 10C ) on a housing, wherein the heat exchanger has a rectangular shape of a parallelepiped, in which a refrigerant flows, wherein, when sides, which form the heat exchanger, which has the rectangular shape of a parallelepiped, a first side ( 31 ), a second page ( 32 ) and a third page ( 33 ), a length from the first side is the longest and a length from the third side is the shortest, wherein a surface which is surrounded by the first side and the second side, a heat exchange surface ( 11a ) of the heat exchanger, the mounting structure comprising: at least one attachment section ( 30 . 30B ) disposed on a surface surrounded by the first side and the third side, wherein when the length from the first side is defined as L, the attachment portion is separated by at least one position by 0.25 L ± 0 , 05 L and a position separated by 0.75 L ± 0.05 L from one end of the first side. The fixing structure according to any one of claims 1 to 4, wherein the fixing portion is disposed at the position where a frequency of a vibration mode of the heat exchanger is different from a natural frequency of a wall surface of the housing.

Images