The present disclosure relates to an outdoor unit for an air conditioning device.
Outdoor units for air conditioning devices include a type of outdoor unit having a heat exchanger that includes heat transfer tubes provided with fins and a housing that houses the heat exchanger. The heat transfer tubes of the heat exchanger are disposed in parallel to one another and connected to refrigerant tubes at end portions of the heat transfer tubes.
In typical manufacture of a heat exchanger, heat transfer tubes are press-fit to and integrated with the fins by brazing, and then the heat transfer tubes integrated with the fins are bent. Variations in temperature distribution in the brazing process, dimensions or materials of the fins and the heat transfer tubes, and other factors may result in warpage or dimensional variations in the heat exchanger. Such warpage or dimensional variations may cause a gap between the heat exchanger and the housing in installation of the heat exchanger in the housing of the outdoor unit. To address this, various techniques have been developed to prevent deformation of the heat exchanger or cover the gap between the heat exchanger and the housing.
For example, Patent Literature 1 discloses an outdoor unit including a heat exchanger, enclosing members, and a housing, wherein the heat exchanger includes vertically-arranged heat transfer tubes and refrigerant tubes connected to end portions of the respective heat transfer tubes, the enclosing members cover connections between the refrigerant tubes and the end portions of the heat transfer tubes, and the housing has inner walls on which the enclosing members are fastened. Each enclosing member has a first side plate with openings through which the heat transfer tubes pass and a second side plate to be fastened on the inner wall of the housing. The first side plate encloses spaces between the heat transfer tubes, and the second side plate fills a gap between the heat transfer tubes and the housing.
Patent Literature 2 discloses an outdoor unit including a heat exchanger and two support members, wherein the heat exchanger includes vertically-arranged heat transfer tubes and refrigerant tubes each connected to end portions of the heat transfer tubes, and the two support members sandwich the end portions of the heat transfer tubes and refrigerant tubes connected to the end portions therebetween. In Patent Literature 2, the two support members correct warpage of the heat exchanger, thereby reducing deformation of the heat exchanger.
Patent Literature 1: Unexamined Japanese Patent Application Kokai
Publication No. 2013-137127
Patent Literature 2: Unexamined Japanese Patent Application Kokai Publication No. 2016-84994
In the outdoor unit of Patent Literature 1, however, gaps can occur between the enclosing member and the heat transfer tubes due to deformation of the enclosing member when warpage of the heat exchanger occurs. This gap may permit entry of rainwater entrained with outside air into a space enclosed by the enclosing member. The rainwater having entered the space enclosed by the enclosing member may spread, which may cause attachment of droplets to electrical components inside the housing.
In the outdoor unit of Patent Literature 2, each fin has grooves formed between portions of the fin. The support members abut tips of the fins. The support members, however, do not enclose the grooves. Thus this outdoor unit may permit inflow of the outside air through a space in the grooves. Rainwater entrained in the inflow air may spread inside the housing, which may cause attachment of spread rainwater to electrical components inside the housing.
Such attachment of rainwater to the electrical components may hasten deterioration and cause problems such as short circuits.
In view of the above disadvantages, an objective of the present disclosure is to provide an outdoor unit for an air conditioning device that can reduce attachment of rainwater to electrical components due to spreading of the rainwater inside the housing.
To achieve the above objective, an outdoor unit for an air conditioning device according to the present disclosure includes a heat exchanger, a first protective member, a second protective member, a first cover member, a second cover member, and a housing that houses the heat exchanger, the first protective member, the second protective member, the first cover member, and the second cover member. The heat exchanger includes heat transfer tubes arranged with a space provided therebetween and fins extending from the heat transfer tubes. The heat transfer tubes each have one end connected to a refrigerant tube, which allows heat of refrigerant contained in the refrigerant tubes to be transferred through the heat transfer tubes. The fins serve to exchange heat between the heat transfer tubes and the outside air. The first protective member has (i) a first flat plate that covers one-end portions of the heat transfer tubes and an endmost fin that is located nearest the one-end portions of the heat transfer tubes, and (ii) a first protrusion that protrudes from the first flat plate toward the space between the heat transfer tubes near the one-end portions of the heat transfer tubes. The second protective member has (i) a second flat plate that covers one-end portions of the heat transfer tubes and the endmost fin oppositely from the first flat plate, and (ii) a second protrusion that protrudes from the second flat plate toward the space near the one-end portions of the heat transfer tubes. The first cover member covers the first flat plate and the second cover member covers the second flat plate. The housing has an inner wall abutting the first cover member and an inner wall abutting the second cover member.
According to the configuration of the present disclosure, the one-end portions of the heat transfer tubes and the endmost fin are sandwiched between the first flat plate and the second flat plate, and the first protrusion and the second protrusion protrude toward the space near the one-end portions of the heat transfer tube, thereby enclosing the space between one-end portions of the heat transfer tubes. The inner walls of the housing abut the first cover member and the second cover member, thereby filling the gap between the inner wall of the housing and the first cover member and the gap between the inner wall of the housing and the second cover member. This can reduce entry of rainwater from an area near the one-end portions of the heat transfer tubes, thereby reducing spreading of the rainwater inside the housing. Consequently, attachment of rainwater to electrical components by spreading can be reduced.
An outdoor unit for an air conditioning device according to embodiments of the present disclosure is described below in detail with reference to the drawings. The same reference signs are used to refer to the same or like parts throughout the drawings. An orthogonal coordinate system XYZ in the drawings indicates directions of the outdoor unit when an air discharge vent side of the outdoor unit is taken as a front side of the outdoor unit; specifically, the X axis indicates a left-right direction, the Z axis indicates an up-down direction, and the Y axis indicates a direction perpendicular to the X and Z axes. This coordinate system is used as appropriate in the following description.
An outdoor unit for an air conditioning device according to Embodiment 1 includes a fan, a heat exchanger, and a housing that houses the fan and the heat exchanger. The configuration of the outdoor unit for the air conditioning device is described below with reference to
The outdoor unit 1 includes a housing 10 having a rectangular parallelepiped shape, as illustrated in
The front panel 10A includes a first front panel section 101 that forms most of the front-side outer wall of the outdoor unit 1, a second front panel section 102 that forms an upper right portion of the front-side outer wall and a portion of the right-side outer wall, and a third front panel section 103 that forms an lower right portion of the front-side outer wall and a portion of the right-side outer wall. The first front panel section 101 has an air discharge vent 11. The first front panel section 101 is provided with a fan guard 13 that covers the air discharge vent 11 to provide enhanced safety.
The rear panel 10C includes (i) a first rear panel section 111 that forms a portion of the rear-side outer wall and a portion of the right-side outer wall (illustrated on the left side in
The air inlets 12A and 12B and the air discharge vent 11 of the housing 10 as described above may permit entry of rainwater into the housing 10 when the outdoor unit 1 is installed outdoors. Such entry may lead to spreading of the rainwater inside the housing 10, which may cause attachment of droplets to electrical components inside the housing 10. To reduce attachment of rainwater to the electrical components due to the spreading inside the housing 10, the housing 10 is provided therein with a separator plate 10F for partitioning the housing 10 into a space that permits entry of rainwater and a space that does not permit the entry. The structure of the housing 10 interior is next described with reference to
As illustrated in
The machine chamber 100A is a space more shielded from the outside air than the fan chamber 100B. The machine chamber 100A contains a compressor, a receiver, a valve, refrigerant tubes 20E that connect the compressor, the receiver, the valve, and a heat exchanger 20 described later to one another, and an electric circuit that controls the compressor, the valve, and other components. To facilitate understanding, the electrical components, such as the compressor and the valve, and the electric circuit are not illustrated in
In contrast to the machine chamber 100A, the fan chamber 100B is a space that communicates with the air inlets 12A and 12B and the air discharge vent 11 and is thus exposed to the outside air. The fan chamber 100B contains a fan 60 that blows the outside air from the air inlets 12A and 12B toward the air discharge vent 11, a motor 61 that rotates the fan 60, and a fan frame 62 that supports the motor 61 and is fastened to the bottom panel 10E and the front panel 10A.
The fan chamber 100B further contains the heat exchanger 20 that causes exchange of heat with the outside air blown by the fan 60. Specifically, most of the heat exchanger 20 that is located on the +X side thereof is contained in the fan chamber 100B. The −Y end of the separator plate 10F is connected to a +Y-side surface that is located on the −X side of the heat exchanger 20, specifically, a cover member 22B described later located on the +Y side. The −X end of the heat exchanger 20 is located in the machine chamber 100A that is located on the −X side of the separator plate 10F. The −X end of the heat exchanger 20 is connected to the refrigerant tube 20E in the machine chamber 100A. The heat exchanger 20 is provided with the protective members 21A and 21B and cover members 22A and 22B, not illustrated in
Next, the configuration of the heat exchanger 20, the protective members 21A and 21B, and the cover members 22A and 22B is described. The configuration of the heat exchanger 20 with reference to
In
As illustrated in
As illustrated in
The heat transfer tubes 20A take the form of flat tubes to improve heat-exchange efficiency, as illustrated in
The fins 20B have a rectangular and plate-like shape. Plate surfaces of the fins 20B are arranged in parallel to the YZ plane, and the longitudinal direction of the fins 20B is oriented in the Z direction. The fins 20B are spaced apart from one another in the X direction to allow through flow of the outside air between the fins 20B. The fins 20B are each perpendicular to the heat transfer tubes 20A. The overall structure of the fins 20B and the heat transfer tubes 20A is thus grid-like. The fins 20B are made of an aluminum alloy to improve the heat-exchange efficiency.
As illustrated in
The refrigerant tube 20E, as illustrated in
Each coupling 20D is connected to the end portion of the corresponding heat transfer tube 20A, and a space S lies between each coupling 20D and the most-negative-X-side fin 20B of the fins 20B.
As described above, most of the heat exchanger 20 that is located on the +X side is disposed in the fan chamber 100B, whereas the −X end of the heat exchanger 20 is disposed in the machine chamber 100A. The above-described coupling 20D is located across a portion between the fan chamber 100B and the machine chamber 100A. Thus the outside air may flow into the machine chamber 100A through the spaces S. Specifically, as illustrated in
Specifically, the protective member 21A and the cover member 22A are disposed against the −X-side opening of the space S. The protective member 21A covers the most-negative-X-side fin 20B, the heat transfer tubes 20A, and the couplings 20D from the −Y side of the heat exchange unit 200A. The cover member 22A covers the protective member 21A from the −Y side of the heat exchange unit 200A and abuts the inner wall of the rear panel 10C. Similarly, the protective member 21B and the cover member 22B are disposed against the +X-side opening of the space S. The protective member 21B covers the most-negative-X-side fin 20B, the heat transfer tubes 20A, and the couplings 20D from the +Y-side of the heat exchange unit 200B. The cover member 22B covers the protective member 21B from the +Y side of the heat exchange unit 200B, and the −Y end of the separator plate 10F abuts the cover member 22B. The configuration of the protective members 21A and 21B and the cover members 22A and 22B is next described with reference to
The protective member 21A has substantially the same configuration as the protective members 21B, and the cover member 22A has substantially the same configuration as the cover member 22B. In the following description, the same reference signs are used to refer to the same or like configurations, and the configurations are identified by suffixes A and B added to the end of the reference signs.
As illustrated in
The protective members 21A and 21B are made of a material deformable to accommodate the shape of the heat exchanger 20 even when the heat exchanger 20 becomes warped. That is, the protective members 21A and 21B are made of a more flexible material than the material of the heat transfer tubes 20A. Specifically, the protective members 21A and 21B are made of a polypropylene resin.
As illustrated in
As illustrated in
The protective member 21A has a recessed shape that is recessed from the −Y ends of protrusions 215A toward the +Y side, as illustrated in
As illustrated in
As illustrated in
With reference again to
The protrusions 215B of the protective member 21B, as illustrated in
The locking claws 216P and 216Q engage with the same heat transfer tube 20A and hold the heat transfer tube 20A therebetween. The locking claws 216P and 216Q thereby fasten the protective member 21B to the heat transfer tubes 20A to maintain the state in which the protrusions 215B fill the space. As a result, the protective member 21B protects the heat transfer tubes 20A of the heat exchange unit 200B and blocks a path of entry of the outside air and rainwater. To facilitate attachment of the protective member 21B when the heat transfer tubes 20A deform, the locking claws 216P and 216Q are not provided along the entire flat plates 211B, but rather are provided in just three locations that are the middle portion and both end portions of the flat plate 211B in the longitudinal direction. Specifically, the pair of locking claws 216P and 216Q is provided in the middle portion and another pair of locking claws 216P and 216Q is provided on each of both the end sides in the Z direction. With the similar arrangement, the protective member 21A protects the heat transfer tubes 20A of the heat exchange unit 200A and blocks the path of entry of the outside air and rainwater.
The protrusions 215B between the locking claws 216P and 216Q, as illustrated in
Next, the configuration of the cover members 22A and 22B is described.
As illustrated in
The flat plates 221A and 221B have a longitudinal length extending in the Z direction to cover the entire protective members 21A and 21B, and a transverse width that is greater than the X-direction widths of the protective members 21A and 21B. The cover members 22A and 22B are made of an aluminum alloy, and the flat plates 221A and 221B are folded sheet metal of the aluminum alloy.
The cover members 22A and 22B may be made of a material other than the aluminum alloy, and may be made of a material having higher or lower stiffness than the aluminum alloy.
As illustrated in
The top surface portion 222A is a folded portion of the flat plate 221A made folded in the +Y direction. The top surface portion 222A is provided with a locking claw 224A that is a +Y-end portion of the top surface portion 222A folded in the −Z direction and protruding toward the −Z side, as illustrated in
In contrast, the protrusion 222B protrudes from the flat plate 221B toward the −Y side, as illustrated in
With reference again to
The lower side surface portion 223A is located on a plane stepped relative to the flat plate 221A in the −Y direction The lower side surface portion 223A has an insertion hole 410 for insertion of a screw 41 for fastening the later-described lower support portion 223B of the cover member 22B, as illustrated in
The lower support portion 223B, as illustrated in
The side walls 228A and 228B of the flat plates 221A and 221B, respectively, have the restraint holes 227A and 227B for restraining the protruding claws 217A and 217B of the protective members 21A and 21B for connection between the cover member 22A and the protective member 21A and connection between the cover member 22B and the protective member 21B, as illustrated in
The lower support portion 223B has the stop 229 on the bottom surface thereof, as illustrated in
The flat plates 221A and 221B have threaded holes for fastening the cover members 22A and 22B to the housing 10 by screws. As illustrated in
Although not illustrated, the flat plate 221B has a threaded hole into which a screw 44 for fastening the separator plate 10F is threadably received. The flat plate 221B is fastened to the separator plate 10F by the screw 44, with the flat plate 221B abutting the −Y end of the separator plate 10F, as illustrated in
Next, a method for assembling the outdoor unit 1 is described.
First, the heat exchanger 20, the protective members 21A and 21B, and the cover members 22A and 22B, having shapes described above, are made. Each of a set of three protective members 21A and a set of three protective members 21B is prepared for the corresponding Y-direction side surface of the single heat exchanger 20. Each of the cover members 22A and 22B is prepared for the corresponding Y-direction side surface of the single heat exchanger 20. For preparation of the heat exchanger 20, the heat transfer tubes 20A, the fins 20B, and the refrigerant tubes 20E that are made of an aluminum alloy are first assembled into the above-described arrangement and integrated together by brazing to fabricate the heat exchange units 200A to 200D. The fabricated heat exchange units 200A to 200D are then combined to produce the heat exchanger 20. The protective members 21A and 21B are made in the above-described shape and size by injection molding. Examples of materials used for injection molding include polypropylene, which is a thermoplastic resin. The cover members 22A and 22B are made by pressing an aluminum alloy plate.
Together such the preparation, the front panel 10A, the left side panel 10B, the rear panel 10C, the top panel 10D, the bottom panel 10E, and the separator plate 10F are made. Specifically, a steel plate with surface coating is pressed to make the front panel 10A, the left side panel 10B, the rear panel 10C, and the top panel 10D. A steel plate with a plated layer formed thereon is pressed to make the bottom panel 10E and the separator plate 10F.
Then, the protective members 21A and 21B are attached to the heat exchanger 20. First, the protective member 21A is disposed on the −Y side of the heat exchanger 20 and is then positioned relative to the heat transfer tubes 20A while being abutted at the positioning ribs 218 against the transfer tubes 20A. Then, the locking claws 216P and 216Q of the protective member 21A are engaged with the heat transfer tubes 20A. The positioning of the protective member 21A and the engagement of the locking claws 216P and 216Q are repeatedly performed to finish attachment of the three protective members 21A to the heat exchanger 20 on the −Y side thereof. The protective members 21B are disposed on the +Y-direction heat exchanger 20 side, and are then positioned while being abutted at the positioning ribs 218 against the heat transfer tubes 20A. Then, the locking claws 216P and 216Q of the protective members 21B are engaged with the heat transfer tubes 20A, following the above-described engagement steps of the locking claws 216P and 216Q. Similarly, the positioning of the protective members 21B and the engagement of the locking claws 216P and 216Q are repeated performed to finish attachment of the three protective members 21B to the heat exchanger 20 on the +Y side thereof.
Then, the cover members 22A and 22B are attached to the heat exchanger 20 with the protective members 21A and 21B attached. In the first step of this attachment process, the heat exchanger 20 with the protective members 21A and 21B attached is sandwiched by the cover members 22A and 22B. Then, the protruding claws 217A and 217B of the protective members 21A and 21B are inserted into the restraint holes 227A and 227B of the cover members 22A and 22B. The cover members 22A and 22B are thereby held by the protective members 21A and 21B, as illustrated in
Next, the heat exchanger 20 with the protective members 21A and 21B and the cover members 22A and 22B attached is mounted on the support 121 of the bottom panel 10E. The cover members 22A and 22B after being attached to the heat exchanger 20 are temporarily retained with the protruding claws 217A and 217B restrained in the restraint holes 227A and 227B. Thus the cover members 22A and 22B are not positioned relative to the protective members 21A and 21B in the Z direction illustrated in
Next, components such as a compressor and a receiver are attached to the heat exchanger 20, and components such as the fan 60 and the motor 61 are installed on the bottom panel 10E. The front panel 10A, the left side panel 10B, the rear panel 10C, the top panel 10D, and the separator plate 10F are assembled together with the bottom panel 10E to construct the housing 10. Assembling of the outdoor unit 1 is completed in the above manner.
In the above-described assembling method, the protective members 21A and 21B are attached to the heat exchanger 20, and then the cover members 22A and 22B are attached to the protective members 21A and 21B. However, the cover members 22A and 22B may be attached to the protective members 21A and 21B beforehand, and then the members integrated together may be attached to the heat exchanger 20. In this case, the cover members 22A and 22B may be attached to the protective members 21A and 21B by inserting the protruding claws 217A and 217B of the protective members 21A and 21B into the restraint holes 227A and 227B of the cover members 22A and 22B.
The protective members 21A and 21B and the cover members 22A and 22B described above may be designed to have shapes and sizes as described below, in order to achieve attachment thereof to the heat exchanger 20 even when misalignment of the heat exchange units 200A to 200D occurs.
In a case in which misalignment of the protective members 21A and 21B in the X direction occurs, the flat plates 221A and 221B may have changes in the X-direction width in the Z-direction middle portion, that is, at a section of boundary between the heat exchange units 200A to 200D to achieve attachment of the cover members 22A and 22B to the heat exchanger 20. Specifically, a step may be formed on the flat plate 221A at the −X end since the flat plate 221A has on the +X end the side wall 228A, and with this step, the flat plate 221A may have an X-direction width greater on the +Z side than on the −Z side. That is, widths W1 and W2 indicated in
In this case, although not illustrated, the flat plate 221B may also have changes in the X-direction width in the Z-direction middle portion. Changes in the X-direction width of the flat plate 221B may be made with steps formed both the +X end and −X end since the flat plate 221B has the side walls 228B on both the +X end and the −X end. Then the steps may be provided in positions corresponding to a boundary at which the heat exchange unit 200A is adjacent to the heat exchange unit 200C or a boundary at which the heat exchange unit 200B is adjacent to the heat exchange unit 200D. This allows the cover members 22A and 22B to fully cover the protective member 21A with the cover members 22A and 22B attached to the heat exchanger 20, even when misalignment between the heat exchange units 200A and 200C or misalignment between the heat exchange units 200B and 200D occurs. Steps may be formed on the −X ends of the flat plate 221A and the flat plate 221B.
In addition, in this case, the cover member 22A may be attached to the protective member 21A so that a distance between the side wall 228A of the cover member 22A and the side wall 212A of the protective member 21A is smaller on the +Z side than on the −Z side. Similarly, the cover member 22B may be attached to the protective member 21B so that a distance between the side wall 228B of the cover member 22B and the side wall 212B of the protective member 21B is smaller on the +Z side than on the −Z side. In other words, a clearance L1 between the side wall 228A and the side wall 212A illustrated in
As illustrated in
As described above, the clearance C2 in the Z-direction middle portion of the protective members 21A and 21B may be preferably smaller than clearances C2 on both the Z-direction sides of the protective members 21A and 21B. Such arrangement of the clearances C2 enables the protective members 21A and 21B to follow heat transfer tubes 20A with an average amount of deformation among the multiple heat transfer tubes 20A covered with the protective members 21A and 21B. This results in decreased clearances C2 on both of the Z-direction sides.
As described above, in the outdoor unit 1 for the air conditioning device according to this embodiment, the −X-side end portions of the heat transfer tubes 20A and the fin 20B located on the −X-side end portion of the heat exchange units 200A and 200B are sandwiched by the flat plates 211A and 211B of the protective members 21A and 21B. The protrusions 215A and 215B of the protective members 21A and 21B each protrude in the Z direction toward a space between the heat transfer tubes 20A. Thus this can reduce entry of the outside air and rainwater through the space. As a result, the outdoor unit 1 achieves reduction of spreading of rainwater into the machine chamber 100A.
In the outdoor unit 1, the flat plates 211A and 211B of the protective members 21A and 21B are covered with the flat plates 221A and 221B of the cover members 22A and 22B. The cover member 22B in turn abuts the rear panel 10C. This reduces entry of the outside air and rainwater from between the protective member 21B and the rear panel 10C.
The separator plate 10F is fastened to the cover member 22B in abutment therewith. This reduces entry of the outside air and rainwater from between the protective member 21B and the separator plate 10F.
The flat plate 221A of the cover member 22A has the side wall 228A covering the −X-side end surface of the flat plate 211A of the protective member 21A. The flat plate 221B of the cover member 22B has the side walls 228B each covering the corresponding one of the +X-side end surface and the −X-side end surface of the flat plate 211B of the protective member 21B. The side walls 228A and 228B face these end surfaces of the flat plates 211A and 211B of the protective members 21A and 21B. This arrangement can prevent spreading of rainwater from the end surfaces of the flat plates 211A and 211B even if entry of rainwater via the flat plates 211A and 211B of the protective members 21A and 21B occurs.
The protective members 21A and 21B cover the −X-side end portions of the heat transfer tubes 20A and the fin 20B from both sides in the Y direction. The cover members 22A and 22B cover the protective members 21A and 21B from both sides in the Y direction. Even if deformation of the −X-side end portions of the heat transfer tubes 20A and the fin 20B occur, the protective members 21A and 21B deform in accordance with the deformation without correcting the deformation of the heat transfer tubes 20A and the fin 20B. The cover members 22A and 22B also deform in accordance with the shapes of the separator plate 10F and the rear panel 10C without correcting the deformation of the heat transfer tubes 20A and the fin 20B. Thus the cover members 22A and 22B and the protective members 21A and 21B are not required to have high stiffness for correction of the deformation of the heat transfer tubes 20A and the fin 20B. Thus the flat plates 221A and 221B of the cover members 22A and 22B and the flat plates 211A and 211B of the protective members 21A and 21B can be formed by a thin plate such as sheet metal or a resin sheet. This provides a further weight saving benefit to the outdoor unit 1.
The heat transfer tubes 20A are made of an aluminum alloy, and the protective members 21A and 21B are made of polypropylene. This also enables reduction of weight of the outdoor unit 1. The protective members 21A and 21B have a flexibility higher than that of the heat transfer tubes 20A, and thus even if the heat exchanger 20 deforms by warpage, the protective members 21A and 21B can deform in accordance with the deformation of the heat exchanger 20. This flexibility can reduce entry of rainwater. In addition, even if a gap is created between the protective members 21A and 21B and the cover members 22A and 22B due to deformation of the heat exchanger 20, spreading of rainwater can be prevented by the cover members 22A and 22B having the side walls 228A and 228B as described above.
The cover members 22A and 22B are made of an aluminum alloy. This also enables reduction of weight of the outdoor unit 1. The cover members 22A and 22B have a flexibility higher than that of the rear panel 10C or the separator plate 10F, and thus even if the rear panel 10C or the separator plate 10F deforms by warpage, the cover members 22A and 22B can deform in accordance with the deformation of the rear panel 10C or the separator plate 10F. This flexibility can reduce entry of rainwater. In addition, even if a gap is created between the protective members 21A and 21B and the cover members 22A and 22B due to deformation of the rear panel 10C or the separator plate 10F, spreading of rainwater can be prevented by the cover members 22A and 22B having the side walls 228A and 228B as described above.
An outdoor unit for an air conditioning device according to Embodiment 2, is an outdoor unit with a protective member having air vents through which air passes. The configuration of the outdoor unit for the air conditioning device according to Embodiment 2 is described below with reference to
As illustrated in
Some embodiments of the present disclosure are described above, but the present disclosure is not limited to the above-described embodiments. For example, three protective members 21A are used for a single cover member 22A in Embodiments 1 and 2, and three protective members 21B are used for a single cover member 22B. However, the present disclosure is not limited to such configuration. According to the present disclosure, it is sufficient that a first cover member covers a first flat plate of a first protective member, and a second cover member covers a second flat plate of a second protective member. In this case, it is sufficient the first cover member, together with the second cover member, sandwich the first flat plate of the first protective member and the second flat plate of the second protective member therebetween. Here, in Embodiments 1 and 2, the cover members 22A and 22B correspond to the first cover member and the second cover member of the present disclosure, respectively. The protective members 21A and 21B correspond to the first protective member and the second protective member, respectively. The flat plates 211A and 211B correspond to the first flat plate and the second flat plate, respectively.
Thus, it is sufficient that the outdoor unit 1 includes at least one cover member 22A and at least one cover member 22B. It is also sufficient that the outdoor unit 1 includes at least one protective member 21A and at least one protective member 21B. For example, the outdoor unit 1 may include a single cover member 22A and a single cover member 22B, and at least four protective members 21A and at least four protective members 21B.
Protective members 21C and 21D illustrated in
The protective members 21C and 21D may partially cover the heat transfer tubes 20A of the heat exchanger 20. This decreases the effect of reducing entry of the outside air and rainwater. However, this can provide protection of the heat transfer tubes 20A against the screw 43 for fastening the cover member 22A, by the protective members 21C and 21D covering only the heat transfer tubes 20A located near a place in which the cover member 22A is fastened by screws.
In Embodiments 1 and 2, the heat transfer tubes 20A are flat tubes, but the present disclosure is not limited to such configuration. The heat transfer tubes 20A of the present disclosure may have any shape as long as one end of each heat transfer tube 20A has a shape to allow connection to the refrigerant tube 20E to achieve heat exchange. For example, the heat transfer tubes 20A may be cylindrical tubes. Alternatively, the heat transfer tubes 20A may include a flat tube and a cylindrical tube. However, use of flat tubes as heat transfer tubes 20A is desired since the flat tubes contributes to reduction in size and weight of the outdoor unit 1.
According to the present disclosure, it is sufficient that the heat transfer tube 20A is connected at one end thereof to the refrigerant tube to allow flow of refrigerant. Thus inclusion of the collector tube is optional. The term “refrigerant tube” refers to a tube for passing refrigerant and also includes a tube that is referred to as a connection tube. Examples of components for use of connection to the refrigerant tube include, in addition to the coupling 20D, a component that is referred to as a connection member.
In Embodiments 1 and 2, the heat transfer tubes 20A are connected through the couplings 20D and the refrigerant tubes 20E to the collector tube 31. However, the present disclosure is not limited to such configuration. According to the present disclosure, the heat transfer tubes 20A may be connected directly to the collector tube.
In Embodiments 1 and 2, the fins 20B have a flat rectangular shape. In addition, fin 20B portions adjacent to each other in the Z direction are connected to each other to form an integral component. However, the present disclosure is not limited to such configuration. According to the present disclosure, it is sufficient that the fins 20B extend from the heat transfer tubes 20A. In addition, with the heat transfer tubes 20A arranged with a space provided therebetween, the fins 20B preferably extend toward the spaces. Thus fin 20B portions are each formed separately for the adjacent heat transfer tubes 20A in the Z direction. Cuts may be formed in the fins 20B or the fins 20B may be made bent.
In Embodiments 1 and 2, the heat exchanger 20 includes the multiple heat transfer tubes 20A, but the present disclosure is not limited to such configuration. According to the present disclosure, it is sufficient that the heat exchanger 20 includes two or more heat transfer tubes 20A and the two or more heat transfer tubes 20A are arranged with a space provided therebetween.
In Embodiments 1 and 2, the heat exchanger 20 includes heat exchange units 200A to 200D, but the present disclosure is not limited to such configuration. According to the present disclosure, it is sufficient that the heat exchanger 20 includes heat transfer tubes 20A and fins 20B extending from the heat transfer tubes 20A. Thus the number of the heat exchange units 200A to 200D is not limited to such configuration. In addition, the heat exchanger 20 not including a component that is referred to as the heat exchange units 200A to 200D may also be possible as long as the heat exchanger 20 has the heat transfer tubes 20A and the fins 20B.
According to the present disclosure, it is sufficient that when the heat exchanger includes the heat exchange units, the first heat exchange unit and the second heat exchange unit are located adjacent to each other, and one-end portions of the heat transfer tubes 20A and a fin 20B of the fins 20B that is located on the one-end portion side of the heat transfer tubes 20A of the first heat exchange unit are covered with a first flat plate (that is, flat plate 211A). Similarly, one-end portions of the heat transfer tubes 20A and a fin 20B of the fins 20B that is located nearest the one-end portion side of the second heat exchange unit are covered with a second flat plate (that is, the flat plate 211B) at the opposite side of the second heat exchange unit side adjacent to the first heat exchange unit. In this case, the first heat exchange unit may be located directly or indirectly adjacent to the second heat exchange unit. For example, the first heat exchange unit and the second heat exchange unit may be located adjacent to each other via another heat exchange unit. In Embodiments 1 and 2, the heat exchange unit 200A corresponds to the first heat exchange unit of the present disclosure and the heat exchange unit 200B corresponds to the second heat exchange unit of the present disclosure.
As illustrated in
In Embodiments 1 and 2, the housing 10 contains the machine chamber 100A, and the machine chamber 100A contains electrical components and electric circuits. However, the present disclosure is not limited to such configuration. According to the present disclosure, it is sufficient that the electrical components that operate by power are contained in the machine chamber 100A. For example, the machine chamber 100A may contain an electric circuit for the fan 60. The machine chamber 100A may also contain electric circuits for various types of sensors.
In Embodiments 1 and 2, the protective members 21A and 21B are made of polypropylene. The cover members 22A and 22B are made of an aluminum alloy. However, the present disclosure is not limited to such configuration. According to the present disclosure, it is sufficient that the protective member 21A, that is, the first protective member has (i) a first flat plate that covers one-end portions of the heat transfer tubes 20A and an endmost fin 20B of the fins 20B that is located nearest the one-end portion side of the heat transfer tubes 20A, and (ii) first protrusions that protrude from the first flat plates toward spaces on the one-end portion side of the heat transfer tubes 20A. It is also sufficient that the protective member 21B, that is, the second protective member has (i) a second flat plate that sandwiches, together with the first flat plate, the one-end portions of the heat transfer tubes 20A and the endmost fin 20B, and (ii) second protrusions that protrude from the second flat plate toward spaces on the one-end portion side. The protective members 21A and 21B may be made of any material as long as such a configuration is obtained. Here, in Embodiments 1 and 2, the flat plates 211A and 211B correspond to the first flat plate and the second flat plate of the present disclosure, and the protrusions 215A and 215B correspond to the first protrusion and the second protrusion of the present disclosure.
Thus the protective members 21A and 21B may be made with metals other than an aluminum alloy, resins other than polypropylene, or the like. The protective members 21A and 21B may be advantageously made of a resin material to achieve reduction in size and weight of the outdoor unit 1. The cover members 22A and 22B may be advantageously made of an aluminum alloy. With such materials, the resin protective members 21A and 21B can prevent electrolytic corrosion of the cover members 22A and 22B.
In Embodiments 1 and 2, the protective members 21A and 21B cover the most-negative-X-side fin 20B, that is, the endmost fin 20B on the −X side. However, the present disclosure is not limited to such configuration. According to the present disclosure, as described above, it is sufficient that the flat plate 211A, that is, the first flat plate covers the one-end portions of the heat transfer tubes 20A and the endmost fin 20B of the fins 20B that is located near the one-end portions of the heat transfer tubes 20A. In addition, it is sufficient that the flat plate 211B, that is, the second flat plate, together with the first flat plate, sandwich the one-end portions of the heat transfer tubes 20A and the endmost fin 20B therebetween. Of course, the first flat plate may cover a fin 20B next to the endmost fin 20B in addition to the endmost fin 20B located near the one-end portions of the heat transfer tubes 20A as long as the first flat plate covers the endmost fin 20B of the fins 20B that is located near the one-end portions of the heat transfer tubes 20A. It is sufficient that the first flat plate covers at least the endmost fin 20B of the fins 20B that is located near the one-end portions of the heat transfer tubes 20A. The second flat plate, together with the first flat plate, sandwich the endmost fin 20B located near the one-end portions of the heat transfer tubes 20A as well as a fin 20B next to the endmost fin 20B. It is sufficient that the second flat plate, together with the first flat plate, sandwiches at least the endmost fin 20B of the fins 20B that is located near the one-end portions of the heat transfer tubes 20A.
It is sufficient that the cover members 22A and 22B are disposed to sandwich the first flat plate and the second flat plate therebetween to cover the first flat plate and the second flat plate and the cover members 22A and 22B are fastened to the separator plate 10F. The cover members 22A and 22B may be made of any material as long as such a configuration is obtained. For example, the cover members 22A and 22B may be made with resins other than polypropylene, metals other than an aluminum alloy, or the like. The cover members 22A and 22B contribute to reduction of breakage and wear of the heat transfer tubes 20A, and thus the cover members 22A and 22B are advantageously made of a material with stiffness lower than that of the heat transfer tubes 20A. When the cover members 22A and 22B are formed of a metal material, an anti-corrosive layer is advantageously formed on the cover members 22A and 22B to prevent electrolytic corrosion.
In Embodiments 1 and 2, the housing 10 is separated by the separator plate 10F into the machine chamber 100A and the fan chamber 100B. However, the present disclosure is not limited to such configuration. According to the present disclosure, the housing 10 may have a separator member that separates the housing 10 into multiple spaces. In this case, the separator member may be, for example, a film-like member or a cloth-like member.
In Embodiments 1 and 2, the flat plate 221A of the cover member 22A has an inverted L-shape in the XY cross section. The flat plate 221B of the cover member 22B has a U-shape in the XY cross section. However, the present disclosure is not limited to such configuration. According to the present disclosure, it is sufficient that when the flat plates 221A and 221B have walls (specifically, the side walls 228A and 228B), the side walls 228A and 228B face the end portions of the flat plates 211A and 211B of the protective members 21A and 21B at the −X ends of the heat transfer tubes 20A, that is, at end portions, located near the machine chamber 100A, of the heat transfer tubes 20A. This configuration can reduce spreading of rainwater having reached the −X end of the flat plates 211A and 211B into the machine chamber 100A. Thus, according to the present disclosure, the flat plates 221A and 221B having side walls 228A and 228B only on the −X-end side are also possible. In other words, the flat plates 221A and 221B may both have an L-shape in the XY cross section.
According to the present disclosure, the first flat plate and the second flat plate may have a first locking claw and a second locking claw that engage with the heat transfer tubes. The first flat plate and the second flat plate may have a first air vent and a second air vent. Here, in Embodiments 1 and 2, the locking claws 216P and 216Q correspond to the first locking claw and the second locking claw of the present disclosure, and the air vents 512 of the protective member 51A and the protective member 51B correspond to the first air vent and the second air vent of the present disclosure.
The foregoing describes some example embodiments for explanatory purposes. Although the foregoing discussion has presented specific embodiments, persons skilled in the art will recognize that changes may be made in form and detail without departing from the broader spirit and scope of the invention. Accordingly, the specification and drawings are to be regarded in an illustrative rather than a restrictive sense. This detailed description, therefore, is not to be taken in a limiting sense, and the scope of the invention is defined only by the included claims, along with the full range of equivalents to which such claims are entitled.
This application claims the benefit of Japanese patent Application No. 2016-203656, filed on Oct. 17, 2016, the entire disclosure of which is incorporated by reference herein.
Number | Date | Country | Kind |
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JP2016-203656 | Oct 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2017/037159 | 10/13/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/074354 | 4/26/2018 | WO | A |
Number | Name | Date | Kind |
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20140131019 | Kagawa | May 2014 | A1 |
20170370597 | Kaneda | Dec 2017 | A1 |
Number | Date | Country |
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2013137127 | Jul 2013 | JP |
2016084994 | May 2016 | JP |
Entry |
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International Search Report (PCT/ISA/210) dated Dec. 12, 2017, by the Japan Patent Office as the International Searching Authority for International Application No. PCT/JP2017/037159. |
Written Opinion (PCT/ISA/237) dated Dec. 12, 2017, by the Japan Patent Office as the International Searching Authority for International Application No. PCT/JP2017/037159. |
Number | Date | Country | |
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20200088422 A1 | Mar 2020 | US |