JP7200906B2 - vehicle air conditioner - Google Patents

Description

The disclosure herein relates to vehicle air conditioners.

Patent Literature 1 discloses a cooling unit in which a vibration transmission reducing member is arranged at a node position of an evaporator. The contents of the prior art documents are incorporated by reference as descriptions of technical elements in this specification.

Japanese Utility Model Laid-Open No. 3-42708

In prior art configurations, a vibration transmission reduction member supports the evaporator. Therefore, if the position of the vibration transmission reducing member is displaced with respect to the case body, the evaporator may not be properly supported. In view of the above, or in other aspects not mentioned, there is a need for further improvements in vehicle air conditioners.

One object of the disclosure is to provide a vehicle air conditioner that can support a heat exchanger well.

The vehicle air conditioner of the first invention disclosed herein comprises an air conditioning case (21) through which air blown into the vehicle interior flows, and a heat exchanger ( 41), support portions (60u, 60d) that support the lower portion of the heat exchanger, and a cushioning material (74) disposed between the heat exchanger and the support portion, and the support portion is an air conditioning case. 1st support parts (64u, 64d) continuously provided integrally from the The second support is provided adjacent to the first support, and the heat exchanger is a vibration source that generates a standing wave vibration having a plurality of node positions, the first support and the second support support the position including the joint position through the cushioning material, and the position of the central part of the support including the first support and the second support is , consistent with the node position .
The vehicle air conditioner of the second invention disclosed herein comprises an air conditioning case (21) through which air blown into the vehicle interior flows, and a heat exchanger ( 41), support portions (60u, 60d) that support the lower portion of the heat exchanger, and a cushioning material (74) disposed between the heat exchanger and the support portion, and the support portion is an air conditioning case. 1st support parts (64u, 64d) continuously provided integrally from the The second contact surface (55u, 255u), which is the contact surface with the cushioning material in the second support part, is the first contact surface (65u), which is the contact surface with the cushioning material in the first support part, and the surface It is the same positional relationship.
The vehicle air conditioner of the third invention disclosed herein comprises an air conditioning case (21) through which air blown into the vehicle interior flows, and a heat exchanger ( 41), support portions (60u, 60d) that support the lower portion of the heat exchanger, and a cushioning material (74) disposed between the heat exchanger and the support portion, and the support portion is an air conditioning case. 1st support parts (64u, 64d) continuously provided integrally from the and a second contact surface (55u, 255u) that is a contact surface with the cushioning material in the second support part and a first contact surface (65u) that is a contact surface with the cushioning material in the first support part have.

According to the disclosed vehicle air conditioner, the supporting portion includes the first supporting portion continuously provided integrally with the air conditioning case, and the second supporting portion provided in the installation component which is a component separate from the air conditioning case. 2 supports. For this reason, a first support that does not shift relative to the air conditioning case and a second support that can support a desired position under the heat exchanger by changing its shape and position are used. Can support heat exchangers. Therefore, it is possible to provide a vehicle air conditioner that can support the heat exchanger satisfactorily.

The multiple aspects disclosed in this specification employ different technical means to achieve their respective objectives. Reference numerals in parentheses described in the claims and this section are intended to exemplify the correspondence with portions of the embodiments described later, and are not intended to limit the technical scope. Objects, features, and advantages disclosed in this specification will become clearer with reference to the following detailed description and accompanying drawings.

1 is a configuration diagram showing a schematic configuration of a vehicle air conditioner; FIG. It is a cross-sectional view showing the peripheral structure of the cooler. 1 is a perspective view of a laying component; FIG. FIG. 4 is a perspective view showing the installation part attached to the air conditioning case; FIG. 4 is a top view showing the installation part attached to the air conditioning case; FIG. 6 is a cross-sectional view showing a cross section along line VI-VI of FIG. 5 in a state where coolers are arranged; FIG. 4 is a configuration diagram showing a state in which a cooler is supported by a supporting portion; It is a block diagram which shows the support state of the cooler by the support part in 2nd Embodiment.

A number of embodiments will be described with reference to the drawings. In several embodiments, functionally and/or structurally corresponding and/or related parts may be labeled with the same reference numerals or reference numerals differing by one hundred or more places. For corresponding and/or associated parts, reference can be made to the description of other embodiments.

1ST EMBODIMENT The vehicle air conditioner 1 is an air conditioner mounted in a vehicle. The vehicle is, for example, an automobile equipped with a gasoline-powered engine. However, as the vehicle, an electric vehicle equipped with a driving motor, a hybrid vehicle equipped with both an engine and a motor, or the like can be adopted. The vehicle air conditioner 1 is a device that adjusts the temperature and humidity of the air taken in and blows the air into the vehicle interior. In other words, the vehicle air conditioner 1 is a device that performs air conditioning operations such as a heating operation, a cooling operation, and a dehumidifying operation in the passenger compartment.

In FIG. 1, a vehicle air conditioner 1 includes a blower unit 10 that blows air and an air conditioning unit 20 that adjusts the air temperature. The blower unit 10 includes a blower case 11 and a blower 15 . The blower case 11 has two inlets, an inside air inlet 14a and an outside air inlet 14b. Inside the blower case 11, an inside/outside air switching door 12 for switching opening and closing of the inside air introduction port 14a and the outside air introduction port 14b is provided. The inside/outside air switching door 12 can execute an inside air circulation mode in which conditioned air circulates inside the room. The inside/outside air switching door 12 can execute an outside air introduction mode, which is a mode in which conditioned air is introduced from the outside.

The blower 15 is provided inside the blower case 11 . The blower 15 is an electric blower whose rotation speed can be controlled using an electric motor. The blower 15 is a device for sending the air taken in from the inlet from the blower unit 10 toward the air conditioning unit 20 . The blower 15 is, for example, a centrifugal blower, and a sirocco fan or a turbo fan can be used.

The air conditioning unit 20 includes an air conditioning case 21 , a heater device 32 and a cooler 41 . The heater device 32 is a device for heating air during air conditioning operation. The heater device 32 is a heater core in which high-temperature engine cooling water circulates. However, the heater device 32 may be composed of an electric heater capable of electrically controlling the magnitude of the output as well as the ON/OFF control of the output.

The cooler 41 is a device for evaporating a liquid-phase refrigerant into a gas-phase refrigerant. The cooler 41 is a heat exchanger that takes heat from the surroundings when evaporating the refrigerant. In other words, the cooler 41 is a cooling heat exchanger for cooling air during air conditioning operation. Inside the air-conditioning case 21 , the cooler 41 is provided upstream of the heater device 32 in the flow of air. In the cooler 41, vibration such as refrigerant passage noise may occur in the course of the passage of the refrigerant. In other words, the cooler 41 is a vibration source that can vibrate during air conditioning operation.

The air conditioning case 21 has three openings: a defroster opening 24a, a face opening 24b, and a foot opening 24c. The defroster opening 24a is an opening through which the conditioned air flows toward the front window. The face opening 24b is an opening through which the conditioned air flows toward the passenger's upper body including the face. The foot opening 24c is an opening through which the conditioned air flows toward the passenger's lower body including the feet.

An air mix door 25 is provided inside the air conditioning case 21 . The air mix door 25 is a door that adjusts the rate at which the air that has passed through the cooler 41 flows to the heater device 32 . Inside the air conditioning case 21, a defroster door 22a, a face door 22b, and a foot door 22c are provided. The defroster door 22a is a door that controls opening and closing of the defroster opening 24a. The face door 22b is a door that controls opening and closing of the face opening 24b. The foot door 22c is a door that controls opening and closing of the foot opening 24c.

The vehicle air conditioner 1 is required to create a comfortable environment in the vehicle interior through air conditioning operation. However, if a large amount of noise or the like is generated due to air-conditioning operation, the comfort in the passenger compartment is impaired. Therefore, the vehicle air conditioner 1 is required to have high quietness. For example, when the cooler 41 vibrates when the coolant passes through it, the vibration generated in the cooler 41 is transmitted to the air conditioning case 21 and may be transmitted into the vehicle interior as abnormal noise through the face opening 24b. If the passenger perceives such an abnormal sound, the comfort in the passenger compartment is reduced. Therefore, around the cooler 41, a structure for suppressing abnormal noise is required.

In FIG. 2, the cooler 41 includes a core portion 42, an upper tank 43 and a lower tank 44. As shown in FIG. The cooler 41 is configured such that a plurality of coolant channels are arranged in parallel in the core portion 42 . In the cooler 41 , the upper tank 43 and the lower tank 44 function as inlets or outlets for flowing coolant to the core portion 42 . The cooler 41 has a configuration called a multi-flow heat exchanger. Blowing air flows through the core portion 42 from the front surface to the rear surface. Therefore, the windward side of the cooler 41 corresponds to the front, and the leeward side corresponds to the rear. Instead of a refrigerant having a lower temperature than the surrounding air, the cooler 41 can be made to function as a heater by flowing a heat exchange medium having a higher temperature than the surrounding air. Cooler 41 provides an example of a heat exchanger.

A laying part 51 is provided below the cooler 41 . The installation component 51 is provided between the air conditioning case 21 and the cooler 41 . The detailed structure and function of the installation component 51 will be described later.

An upper packing 73 is provided between the upper tank 43 and the air conditioning case 21 . The upper packing 73 is provided so as to face three surfaces of the upper tank 43, ie, the front surface, the upper surface, and the rear surface. The upper packing 73 is attached and fixed to the upper tank 43 .

The upper packing 73 fills the space between the upper tank 43 and the air-conditioning case 21 to prevent the blown air from flowing between the upper tank 43 and the air-conditioning case 21 . In other words, the upper packing 73 is a part that provides a wind leakage prevention function that controls the flow of blown air so that the blown air flows through the core portion 42 .

The upper packing 73 is arranged in a partially compressed state between the upper tank 43 and the air conditioning case 21 . This prevents the position of the cooler 41 from shifting in the front-rear direction and upward direction. In other words, the upper packing 73 is a component that provides a fixing function to fix the cooler 41 so that it can maintain its proper position. The upper packing 73 is made of a polymer material that is softer than the air conditioning case 21 made of resin and the cooler 41 made of metal. The upper packing 73 is a component that provides a vibration transmission suppression function that suppresses vibration transmission between the cooler 41 and the air conditioning case 21 .

A lower packing 74 is provided between the lower tank 44 and the installation component 51 . The lower packing 74 includes a windward lower packing 74u and a leeward lower packing 74d. The windward lower packing 74u is provided facing the front surface and the lower surface of the lower tank 44 . The leeward lower packing 74 d is provided facing the rear surface and the lower surface of the lower tank 44 . The windward lower packing 74 u and the leeward lower packing 74 d are attached and fixed to the lower tank 44 . A gap is formed between the windward lower packing 74u and the leeward lower packing 74d. Thereby, the condensed water generated on the outer surface of the cooler 41 can flow below the lower packing 74 . Lower packing 74 provides an example of a cushioning material.

The lower packing 74 fills the space between the lower tank 44 and the air-conditioning case 21 to suppress the blown air from flowing between the lower tank 44 and the air-conditioning case 21 . In other words, the lower packing 74 is a part that provides a wind leakage prevention function that controls the flow of blown air so that the blown air flows through the core portion 42 .

The lower packing 74 is arranged in a partially compressed state between the lower tank 44 and the air conditioning case 21 . This prevents the position of the cooler 41 from shifting in the front-rear direction and downward direction. In other words, the lower packing 74 is a part that provides a fixing function to fix the cooler 41 so that it can maintain its proper position. The lower packing 74 is made of a polymer material that is softer than the air conditioning case 21 made of resin and the cooler 41 made of metal. The lower packing 74 is a component that provides a vibration transmission suppression function that suppresses vibration transmission between the cooler 41 and the air conditioning case 21 .

In FIG. 3, the installation component 51 is formed with two windward second support portions 54u. The windward second support portion 54u is a portion that supports the lower tank 44 via the lower packing 74 . The windward second support portion 54u has a curved surface shape along the shape of the lower tank 44 . If the flat portion of the lower tank 44 were to be supported, the windward second support portion 54u would have a planar shape instead of a curved shape. The installation component 51 is provided with a connection portion that connects the two windward side second support portions 54u. The windward second support portion 54u provides an example of a second support portion.

The installation component 51 is formed with two leeward side second support portions 54d. The leeward side second support portion 54 d is a portion that supports the lower tank 44 via the lower packing 74 . The leeward side second support portion 54 d has a curved surface shape along the shape of the lower tank 44 . If the flat portion of the lower tank 44 were to be supported, the leeward side second support portion 54d would have a planar shape instead of a curved shape. The installation component 51 is provided with a connection portion that connects the two leeward side second support portions 54d. The leeward side second support 54d provides an example of a second support.

The installation component 51 is provided with a connection portion that connects the windward side second support portion 54u and the leeward side second support portion 54d. A plurality of drain holes 52 are formed in this connecting portion. The drain hole portion 52 is a hole portion for allowing condensed water generated on the outer surface of the cooler 41 to flow below the installation component 51 . The drain hole 52 is a triangular opening. Each connecting portion connecting the windward side second support portion 54 u and the leeward side second support portion 54 d is a portion that does not contact the lower packing 74 and does not support the lower tank 44 . However, each connecting portion may be configured to contact the lower packing 74 as long as it does not contribute to supporting the lower tank 44 .

Two mounting holes 58 are formed in the installation component 51 . The two assembly holes 58 are provided adjacent to the outside of the second leeward support portion 54d along the direction in which the two second leeward support portions 54d are arranged. The assembly hole 58 is a rectangular opening.

In FIG. 4, the air conditioning case 21 is formed with two windward first support portions 64u. The windward first support portion 64u is provided so as to protrude upward from the air conditioning case 21 . The windward first support portion 64u is a portion that supports the lower tank 44 via the lower packing 74 . The windward first support portion 64u has a curved shape that follows the shape of the lower tank 44 . If the flat portion of the lower tank 44 were to be supported, the windward first support portion 64u would have a planar shape instead of a curved shape. In a state in which the installation component 51 is attached to the air conditioning case 21, the two windward first support portions 64u are arranged outside the windward second support portions 54u along the direction in which the two windward second support portions 54u are arranged. will be located adjacent to the The windward first support portion 64u provides an example of a first support portion.

The air conditioning case 21 is formed with two leeward side first support portions 64d. The leeward side first support portion 64 d is provided so as to protrude upward from the air conditioning case 21 . The leeward side first support portion 64 d is a portion that supports the lower tank 44 via the lower packing 74 . The leeward side first support portion 64 d has a curved surface shape along the shape of the lower tank 44 . If the flat portion of the lower tank 44 were to be supported, the leeward side second support portion 54d would have a planar shape instead of a curved shape. The leeward side first support 64d provides an example of a first support.

When the installation component 51 is attached to the air conditioning case 21 , the two leeward side first support portions 64 d are inserted into the two assembly holes 58 . Thereby, it is possible to prevent the installation component 51 from being displaced in the left-right direction and the front-rear direction. In other words, the relative positional relationship of the installation component 51 with respect to the air conditioning case 21 is stably maintained in an appropriate state, and it is easy to suppress lifting and rattling. In addition, the windward first support portion 64 u also contributes to the maintenance of the installation state of the installation component 51 to the air conditioning case 21 . The leeward side first support portion 64 d provides an example of an assembly portion provided in the air conditioning case 21 .

In FIG. 5, the windward side first support portion 64u and the windward side second support portion 54u that are adjacent to each other constitute the windward side support portion 60u. The windward support portion 60u is a portion that supports the lower tank 44 via the windward lower packing 74u. The windward first support portion 64u and the windward second support portion 54u are provided adjacent to each other without a gap. The windward support 60u provides an example of a support.

The leeward first support portion 64d and the leeward second support portion 54d adjacent to each other constitute the leeward side support portion 60d. The leeward support portion 60d is a portion that supports the lower tank 44 via the leeward lower packing 74d. The leeward side first support portion 64d and the leeward side second support portion 54d are provided adjacent to each other without a gap. The leeward support 60d provides an example of a support.

A drain hole portion 52 is positioned between the windward side support portion 60u and the leeward side support portion 60d. As a result, the condensed water generated on the outer surface of the cooler 41 can be guided below the installation component 51 .

In FIG. 6 , the windward lower packing 74 u is deformed by the gravity from the cooler 41 and the drag from the installation part 51 . In other words, the windward lower packing 74u is sandwiched and compressed between the lower tank 44 and the windward second support portion 54u. The thickness of the uncompressed portion of the windward lower packing 74u is Tu0. Tu0 is the thickness of the windward lower packing 74u before compression. The thickness of the most compressed portion of the windward lower packing 74u is Tu1. In this case, the compression rate of the windward lower packing 74u is represented by (Tu0-Tu1)/Tu0. If the windward lower packing 74u were not compressed at all, Tu1 and Tu0 would have the same value, and the compression ratio would be 0%. If the windward lower packing 74u is compressed to a thickness of 1/10 of the thickness before compression, the compression rate will be 90%.

A portion of the windward lower packing 74u located between the windward support portion 60u and the lower tank 44 is substantially uniformly compressed. On the other hand, the portion of the windward lower packing 74u protruding from between the windward support portion 60u and the lower tank 44 is not compressed. Packings such as the windward lower packing 74u are in a harder state with a greater reaction force as they are compressed. Therefore, the higher the compressibility of the packing, the easier it is to transmit vibration, and the lower the vibration transmission suppressing function. Therefore, in the windward lower packing 74u, vibration is likely to be transmitted to the portion sandwiched between the windward support portion 60u and the lower tank 44 and having a high compressibility.

The leeward lower packing 74d is located between the leeward support portion 60d and the lower tank 44 and is substantially evenly compressed. The compression ratio of the compressed portion of the leeward lower packing 74d is substantially equal to the compression ratio of the compressed portion of the windward lower packing 74u. Therefore, the windward lower packing 74u and the leeward lower packing 74d exhibit the same degree of vibration transmission suppressing function.

In FIG. 7, the windward first support portion 64u has a windward first contact surface 65u that is in contact with the windward lower packing 74u. The windward side second support portion 54u includes a windward side second contact surface 55u that is in contact with the windward lower packing 74u. The windward first contact surface 65u and the windward second contact surface 55u are flush with each other. The contact area between the windward second contact surface 55u and the windward lower packing 74u is equal to the contact area between the windward first contact surface 65u and the windward lower packing 74u. The windward first contact surface 65u provides an example of a first contact surface. The windward second contact surface 55u provides an example of a second contact surface.

The windward lower packing 74u is compressed by the windward first contact surface 65u and the windward second contact surface 55u. Temporarily, when the windward side 2nd support part 54u is not provided, the windward lower packing 74u will be compressed only by the windward side 1st support part 64u. In this case, the compressive stress concentrates on the windward first contact surface 65u. Therefore, in the windward lower packing 74u, the compression progresses until the thickness Tu1 of the most compressed portion becomes a smaller value, and the compressibility tends to increase. However, by providing the windward side second support portion 54u, it is possible to disperse the portions to which the compressive stress is applied and reduce the compressibility. Here, as the size of the windward second contact surface 55u is increased, the compressive stress can be dispersed, and the vibration transmission suppressing function can be enhanced.

The cooler 41 is supported by the windward first support portion 64u and the windward second support portion 54u. The position of the central portion of the windward side support portion 60u, which is a combination of the windward side first support portion 64u and the windward side second support portion 54u, coincides with the node position in the vibration of the standing wave of the cooler 41 . Here, the node position is a position where the amplitude is always zero in the vibration mode generated by the vibration when the refrigerant passes through the cooler 41 . By supporting the cooler 41 so that the windward side support portion 60u includes the node position, the windward side support portion 60u supports the cooler 41 so that the windward side support portion 60u does not include the node position. can reduce the vibration transmitted to the The vicinities around the node position have a smaller amplitude than the antinode position. Therefore, it is particularly preferable to align the node position with the position of the central portion of the windward side support portion 60u.

In the windward side support portion 60 u , the central portion of the windward side first support portion 64 u that is integrally formed continuously with the air conditioning case 21 is located at a position shifted from the node position of the cooler 41 . Here, the position of the center portion of the windward side second support portion 54u is opposite to the position of the center portion of the windward side first support portion 64u across the node position. As a result, the middle position between the central portion of the windward first support portion 64u and the central portion of the windward second support portion 54u coincides with the node position.

Regarding the leeward side support portion 60d, similarly to the upwind side support portion 60u, the position of the central portion between the leeward side first support portion 64d and the leeward side second support portion 54d coincides with the node position in the vibration of the cooler 41. ing. In summary, the windward side support portion 60u and the leeward side support portion 60d support the peripheral portion including the vibration node position of the cooler 41 .

The cooler 41 is supported by the windward first support portion 64u, the windward second support portion 54u, the leeward first support portion 64d, and the leeward second support portion 54d. In other words, the windward side second support portion 54u and the leeward side second support portion 54d compensate for the ability to stably support the cooler 41 with the windward side first support portion 64u and the leeward side first support portion 64d. ing. The installation component 51 in which the windward side second support portion 54u and the leeward side second support portion 54d are formed is detachable at least when the vehicle air conditioner 1 is manufactured. Therefore, by changing the shape of the installation part 51, it is possible to freely change the method of supplementing the supporting capacity of the cooler 41. FIG.

According to the above-described embodiment, the windward side support portion 60u includes the windward side first support portion 64u that is integrally provided continuously from the air conditioning case 21, and the installation component 51 that is a component separate from the air conditioning case 21. The windward side second support portion 54u provided in the. Here, the windward first support portion 64u is a portion that does not shift relative to the air conditioning case 21 . On the other hand, the windward side second support portion 54u is a portion whose position and shape can be easily changed appropriately according to the air conditioning case 21 and cooler 41 . Therefore, the air conditioning case 21 and the cooler 41 can be stably supported by the first windward support portion 64u and the second windward support portion 54u. Similarly, regarding the leeward side support portion 60d, the leeward side first support portion 64d and the leeward side second support portion 54d support the air conditioning case 21 and the cooler 41 in a stable and favorable state. can be done. By the above, the vehicle air conditioner 1 which can support the cooler 41 favorably can be provided.

The windward second support portion 54u is provided adjacent to the windward first support portion 64u. Therefore, it is easy to compare the shape of the windward side second support portion 54u with the windward side first support portion 64u. For example, when the installation component 51 is assembled, the size relationship between the windward second support portion 54u and the windward first support portion 64u can be quickly checked to prevent an inappropriate installation component 51 from being assembled. Alternatively, when the installation component 51 is assembled, the presence or absence of a step between the windward second support portion 54u and the windward first support portion 64u is quickly checked to prevent incomplete assembly of the installation component 51. can be suppressed.

The leeward side second support portion 54d is provided adjacent to the leeward side first support portion 64d. Therefore, it is easy to compare the shape of the leeward side second support portion 54d with the leeward side first support portion 64d. Therefore, it is possible to quickly confirm whether or not the installation component 51 after assembly is in an appropriate state.

The windward side support portion 60u, which is a combination of the windward side first support portion 64u and the windward side second support portion 54u, supports positions including node positions via the windward lower packing 74u. Therefore, the cooler 41 can be supported at a node position where the amplitude is always zero and at a position near the node position with a relatively small amplitude. Therefore, the vibration transmitted to the windward side support portion 60u can be easily reduced compared to the case where the windward side support portion 60u supports a position that does not include the node position.

A leeward side support portion 60d, which is a combination of the leeward side first support portion 64d and the leeward side second support portion 54d, supports positions including node positions via the leeward side lower packing 74d. Therefore, the vibration transmitted to the leeward side support portion 60d can be easily reduced as compared with the case where the leeward side support portion 60d supports a position that does not include the node position.

The position of the central portion of the windward side support portion 60u, which is a combination of the windward side first support portion 64u and the windward side second support portion 54u, coincides with the node position. Therefore, the cooler 41 can be supported at a node position where the amplitude is always zero and at a position near the node position where the amplitude is relatively small. Therefore, compared to the case where the position of the central portion of the windward support portion 60u does not match the node position, it is easier to reduce the vibration transmitted to the windward support portion 60u.

The position of the central portion of the leeward side support portion 60d, which is a combination of the leeward side first support portion 64d and the leeward side second support portion 54d, coincides with the node position. Therefore, compared to the case where the position of the central portion of the leeward side support portion 60d does not match the node position, it is easier to reduce the vibration transmitted to the leeward side support portion 60d.

The windward side second contact surface 55u is flush with the windward side first contact surface 65u. Therefore, it is possible to suppress the concentration of compressive stress on a specific contact surface. Therefore, in the windward lower packing 74u, the compressibility of the portion in contact with the windward second contact surface 55u and the compressibility of the portion in contact with the windward first contact surface 65u can be made substantially equal. Therefore, it is possible to prevent the compression ratio of a part from becoming too high, and to reduce the vibration transmitted between the air conditioning case 21 and the cooler 41 .

The installation part 51 has an assembly hole 58 for inserting the installation part 51 into the leeward side first support part 64 d and assembling the installation part 51 to the air conditioning case 21 . Therefore, it is possible to prevent the installation component 51 from being displaced in the front-rear direction and the left-right direction, which are directions orthogonal to the direction of insertion into the first leeward support portion 64d. Here, by providing two or more insertion points for the leeward side first support portion 64d and the assembly hole portion 58, it is possible to prevent the installation component 51 from rotating around the leeward side first support portion 64d. . Alternatively, by forming the leeward side first support portion 64d and the assembly hole portion 58 into a shape having corners such as a rectangular shape, it is possible to prevent the installation component 51 from rotating around the leeward side first support portion 64d. .

A case where the installation component 51 includes the windward side second support portion 54u and the leeward side second support portion 54d has been described as an example, but for example, it may be configured to include only the windward side second support portion 54u. Alternatively, the windward side second support portion 54u and the leeward side second support portion 54d may be formed as separate parts, and the laying part 51 may be composed of a plurality of parts.

Second Embodiment This embodiment is a modification based on the preceding embodiment. In this embodiment, the windward second contact surface 255u is smaller than the windward first contact surface 65u.

In FIG. 8, the installation component 51 includes two windward second support portions 254u. The windward side second support portion 254u includes a windward side second contact surface 255u that is in contact with the windward lower packing 74u. The windward first contact surface 65u and the windward second contact surface 255u are flush with each other. The windward second support 254u provides an example of a second support. The windward second contact surface 255u provides an example of a second contact surface.

The contact area between the windward second contact surface 255u and the windward lower packing 74u is smaller than the contact area between the windward first contact surface 65u and the windward lower packing 74u. The windward second support portion 54u has a position and size such that the position of the center portion of the windward side support portion 60u combined with the adjacent windward first support portion 64u coincides with the node position.

In the vehicle air conditioner 1, the air conditioning case 21 having the same shape may be used for different vehicle types. However, the node positions in the cooler 41 change depending on the shape, size, and the like of the cooler 41 . Therefore, when different coolers 41 are installed in the air conditioning case 21 having the same shape, the joint position of the cooler 41 and the position of the central portion of the windward first support portion 64u may not match. Similarly, the node position of the cooler 41 and the position of the central portion of the leeward side first support portion 64d may not match.

In order to correspond to the coolers 41 that differ for each vehicle type, a plurality of installation components 51 having different shapes of the windward side second support portion 54u and the leeward side second support portion 54d are used as the first installation component having an assembly mechanism of the same shape. A second installation part can be provided. As an assembling mechanism, a structure including an assembling hole portion 58 provided in the installation component 51 and a first leeward support portion 64d provided in the air conditioning case 21 can be employed. Accordingly, when manufacturing the vehicle air conditioner 1 , it is possible to select and lay an appropriate installation component 51 suitable for each cooler 41 . Therefore, the position of the center portion of the windward side support portion 60 u and the position of the center portion of the leeward side support portion 60 d can be easily aligned with the node positions of the cooler 41 . Therefore, it is not necessary to separately manufacture the entire air conditioning case 21 for the purpose of supporting the cooler 41 corresponding to different node positions of the cooler 41 .

The assembly mechanism is not limited to the structure of the assembly hole portion 58 provided in the installation component 51 and the leeward side first support portion 64 d provided in the air conditioning case 21 . For example, the installation part 51 may be provided with a convex shape, and the air conditioning case 21 may be provided with a concave shape to be fitted and fixed. Alternatively, fastening fixation using screws or adhesion fixation using an adhesive may be employed.

In the vehicle air conditioner 1, when the air conditioning case 21 having the same shape is used for different vehicle types, the air conditioning case 21 is required to have a shape corresponding to various vehicle types. Therefore, various restrictions occur in designing the air conditioning case 21 . An example of a constraint is to have a shape that allows installation of coolers 41 of various sizes. An example of the restriction is that a fixing portion is provided for each part in order to configure the air conditioning case 21 by combining a plurality of parts. An example of the constraint is to ensure the required strength of the air conditioning case 21 . In order to satisfy such various design constraints, it may not be possible to select a shape that prioritizes vibration transmission suppression as the shape of the windward first support portion 64u and the leeward first support portion 64d.

In order to meet various restrictions for each vehicle type, the plurality of installation components 51 having different shapes of the windward side second support portion 54u and the leeward side second support portion 54d are provided with a first installation component and a first installation component having assembly mechanisms of the same shape. 2 installation parts can be prepared. Accordingly, at the time of manufacturing the vehicle air conditioner 1, it is possible to select and install an appropriate installation component 51 suitable for various vehicle types. Therefore, the position of the center portion of the windward side support portion 60 u and the position of the center portion of the leeward side support portion 60 d can be aligned with the node positions of the cooler 41 . Therefore, while adopting the air-conditioning case 21 having the same shape for different types of vehicles, the cooler 41 can be supported corresponding to the node position of the cooler 41 by the optimum combination of the installation parts 51 and the air-conditioning case 21 .

According to the above-described embodiment, the air-conditioning case 21 functions as an assembly portion that can be assembled with either the first installation component or the second installation component having different shapes of the windward side second support portion 254u. A first support portion 64d is provided. Therefore, in vehicle air conditioners 1 of different types and specifications, it is possible to reduce vibration transmission between the cooler 41 and the air conditioning case 21 while adopting the same shape of the air conditioning case 21 . Therefore, it is easy to provide the vehicle air conditioner 1 with low cost and high quietness.

The contact area between the windward second contact surface 255u and the windward lower packing 74u is smaller than the contact area between the windward first contact surface 65u and the windward lower packing 74u. Therefore, it is easy to reduce the size of the windward side second support portion 254u and reduce the size and weight of the installation component 51 . Therefore, it is easy to improve the workability when performing the work of assembling the installation component 51 to the air conditioning case 21 .

Other Embodiments The disclosures in this specification, drawings, etc. are not limited to the illustrated embodiments. The disclosure encompasses the illustrated embodiments and variations thereon by those skilled in the art. For example, the disclosure is not limited to the combinations of parts and/or elements shown in the embodiments. The disclosure can be implemented in various combinations. The disclosure can have additional parts that can be added to the embodiments. The disclosure encompasses omitting parts and/or elements of the embodiments. The disclosure encompasses permutations or combinations of parts and/or elements between one embodiment and another. The disclosed technical scope is not limited to the description of the embodiments. The disclosed technical scope is indicated by the description of the claims, and should be understood to include all changes within the meaning and range of equivalents to the description of the claims.

The disclosure in the specification, drawings, etc. is not limited by the description in the claims. The disclosure in the specification, drawings, etc. encompasses the technical ideas described in the claims, and extends to more diverse and broader technical ideas than the technical ideas described in the claims. Therefore, various technical ideas can be extracted from the disclosure of the specification, drawings, etc., without being bound by the scope of claims.

1 vehicle air conditioner 21 air conditioning case 41 cooler (heat exchanger) 51 installation part 52 drain hole 54u windward second support (second support) 54d leeward second support (second support portion) 55u windward second contact surface (second contact surface) 58 assembly hole portion 60u windward support portion (support portion) 60d leeward side support portion (support portion) 64u windward side second contact surface 1 support portion (first support portion), 64d leeward side first support portion (first support portion, mounting portion), 65u windward first contact surface (first contact surface), 74 lower packing (cushioning material), 74u windward lower packing 74d leeward lower packing 254u windward second support portion (second support portion) 255u windward second contact surface (second contact surface)

Claims (10)

an air conditioning case (21) through which air blown into the vehicle interior flows;
a heat exchanger (41) installed in the air conditioning case, in which a heat exchange medium flows;
support portions (60u, 60d) that support the lower portion of the heat exchanger;
A cushioning material (74) disposed between the heat exchanger and the support,
The support part is
a first support portion (64u, 64d) provided continuously and integrally from the air conditioning case;
a second support portion (54u, 54d) provided in a laying part (51) which is a separate part from the air conditioning case,
The second support is provided adjacent to the first support,
The heat exchanger is a vibration source that generates a standing wave vibration having a plurality of node positions,
The support portion, which is a combination of the first support portion and the second support portion, supports a position including the joint position via the cushioning material,
A vehicle air conditioner, wherein a position of a center portion of the support portion, which is a combination of the first support portion and the second support portion, coincides with the node position. A second contact surface (55u, 255u), which is a contact surface of the second support portion with the cushioning material, and a first contact surface (65u), which is a contact surface of the first support portion with the cushioning material, The vehicle air conditioner according to claim 1, comprising: The vehicle air conditioner according to claim 2, wherein the second contact surface is flush with the first contact surface. an air conditioning case (21) through which air blown into the vehicle interior flows;
a heat exchanger (41) installed in the air conditioning case, in which a heat exchange medium flows;
support portions (60u, 60d) that support the lower portion of the heat exchanger;
A cushioning material (74) disposed between the heat exchanger and the support,
The support part is
a first support portion (64u, 64d) provided continuously and integrally from the air conditioning case;
a second support portion (54u, 54d) provided in a laying part (51) which is a separate part from the air conditioning case,
The second contact surface (55u, 255u), which is the contact surface of the second support portion with the cushioning material, is the same as the first contact surface (65u), which is the contact surface of the first support portion with the cushioning material. A vehicle air conditioner with a single positional relationship. an air conditioning case (21) through which air blown into the vehicle interior flows;
a laying part (51) which is a separate part from the air conditioning case;
a heat exchanger (41) installed in the air conditioning case, in which a heat exchange medium flows;
support portions (60u, 60d) that support the lower portion of the heat exchanger;
A cushioning material (74) disposed between the heat exchanger and the support,
The support part is
a first support portion (64u, 64d) provided continuously and integrally from the air conditioning case;
and second support portions (54u, 54d) provided on the installation component,
a second contact surface (55u, 255u) that is a contact surface of the second support portion with the cushioning material;
A vehicle air conditioner having a first contact surface (65u) that is a contact surface of the first support portion with the cushioning material. The vehicle air conditioner according to claim 5, wherein the second contact surface is flush with the first contact surface. The vehicle air conditioner according to any one of claims 4 to 6, wherein the second support portion is provided adjacent to the first support portion. The heat exchanger is a vibration source that generates a standing wave vibration having a plurality of node positions,
8. The vehicle air conditioner according to claim 7, wherein said supporting portion including said first supporting portion and said second supporting portion supports a position including said node position via said cushioning material. The vehicle air conditioner according to any one of claims 2 to 8, wherein a contact area between said second contact surface (255u) and said cushioning material is smaller than a contact area between said first contact surface (255u) and said cushioning material. Device. 10. The vehicle according to any one of claims 1 to 9, wherein the installation part is provided with an assembly hole (58) for inserting the installation part into the first support part and assembling the installation part to the air conditioning case. Air conditioner .

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