JP5720621B2 - Air conditioner outdoor unit - Google Patents

Description

    The present invention relates to an outdoor unit for an air conditioner, and particularly relates to a vibration preventing structure.

    Conventionally, an air conditioner including an outdoor unit is known (see Patent Document 1). In the outdoor unit of this air conditioner, a compressor, a heat exchanger, a blower, an electric motor (motor) for the blower, and a motor support are accommodated in the outdoor unit.

    Moreover, in the said outdoor unit, the contact sound (battering sound) resulting from the contact between a heat exchanger and a top plate arises by vibration of a compressor etc. For this reason, in the said outdoor unit, an elastic material is interposed between the heat exchanger and the top plate, or between the flange portion of the motor support and the top plate, so that the top plate and the heat exchanger or the top plate Generation of contact noise (billing noise) due to contact with the flange portion was prevented.

    By the way, in the said outdoor unit, although the vibration resulting from this electric motor for a fan and an air blower generate | occur | produces because the electric motor for an air blower rotates, the motor support and the flange part are attached and fixed with respect to the heat exchanger. Therefore, the top board did not vibrate due to this vibration.

Japanese Utility Model Publication No. 3-107632

    Here, when the heat exchanger and the motor support are made of dissimilar metals and the heat exchanger is made of a member having a higher ionization tendency than the motor support, if the two are brought into electrical contact, the galvanic corrosion (electrical current) Therefore, it is necessary to arrange the heat exchanger and the motor support so that they are electrically insulated.

    However, if the motor support is not fixed to the heat exchanger, vibration caused by the electric motor is transmitted to the top plate via the elastic material. That is, in the conventional outdoor unit, there is a problem that it is impossible to suppress the vibration of the top plate while suppressing the generation of the contact sound (chatting noise) between the top plate and the flange portion.

    The present invention has been made in view of such points, and in an outdoor unit, the top plate vibrates while preventing the generation of contact noise (chattering noise) due to contact between the top plate and the motor base. The purpose is to prevent.

The first invention includes a compressor (21), a heat exchanger (23), a blower fan (15), and a blower fan (15) in a casing (40) to which a top plate (43) is attached. An outdoor unit of an air conditioner in which an electric motor base (90) that supports an electric motor (17) to be rotated is disposed, wherein the top plate (43) is supported on the outer periphery of the casing (40) and the casing ( 40), the motor base (90) extends vertically from the bottom of the casing (40) toward the top plate (43), and the base body (91) to which the motor (17) is attached. ) And the upper end of the base body (91) along the top plate (43) to one end of the top plate (43) to cover the upper end of the heat exchanger (23) In addition, a first gap (101) is formed with the top plate (43), and a second gap (10 is formed with the upper end of the heat exchanger (23). 3), and an elastic member (100) is provided only on one end side of the top plate (43) in the first gap (101), and the top plate (43 ) And the upper end portion (92) are solid laminated portions (104) in which the upper end portion (92), the elastic member (100), and the top plate (43) are laminated on one end side of the top plate (43). ) And a hollow laminated portion (105) in which an upper end portion (92), a part of the first gap (101), and the top plate (43) are laminated on the side opposite to the one end side of the top plate (43). In the first gap (101), one end of the top plate (43) on one side end side of the elastic member (100) is the top plate of the heat exchanger (23). (43) located on one side end side of the top plate (43) rather than one end portion on one side end side, the other end portion on the opposite side to the one side end side of the top plate (43) Above the other end of the heat exchanger (23) opposite to the one end of the top plate (43) It is provided so as to be positioned at one end side of the top plate (43).

    In the said 1st invention, when a compressor (21) drives, the vibration by the drive of a compressor (21) will be transmitted to the whole casing (40). At this time, since the elastic member (100) is provided between the upper end (92) and the top plate (43) on one end side of the top plate (43), the upper end (92) and the top plate ( 43) is not in direct contact. Therefore, even if the vibration resulting from the compressor (21) occurs, it is possible to suppress the contact sound (chatter noise) generated by the direct contact between the upper end portion (92) and the top plate (43).

    Further, when the electric motor (17) is driven, the blower fan (15) rotates. The vibration due to the drive of the electric motor (17) is transmitted to the electric motor base (90), but a second gap (103) is formed between the upper end portion and the upper end portion (92) of the heat exchanger (23). Therefore, it does not propagate to the heat exchanger (23). On the other hand, the vibration caused by the drive of the electric motor (17) is transmitted to the electric motor base (90) and is transmitted to the top plate (43) through the elastic member (100).

    Specifically, on one end side of the top plate (43), the upper end portion (92), the elastic member (100), and the top plate (43) constitute a solid laminated portion (104). In other words, the elastic member (100) is provided on one end side of the top plate (43) that hardly vibrates, between the upper end portion (92) and the top plate (43). Since the vibration of the electric motor (17) is transmitted to one end side of the top plate (43) via the elastic member (100), the vibration of the top plate (43) is suppressed.

    On the other side of the top plate (43) that easily vibrates, a hollow laminated portion (105) is formed by the upper end portion (92), a part of the first gap (101), and the top plate (43). Has been. That is, a portion of the first gap (101) is formed between the upper end portion (92) and the top plate (43) on the side opposite to the one end side of the top plate (43) that easily vibrates. For this reason, since the vibration of the electric motor (17) is not transmitted to the top plate (43), the top plate (43) can be prevented from vibrating.

In a second aspect based on the first aspect, the upper end (92) includes a fastening portion (98) fastened to one side end of the top plate (43) or the casing (40), The elastic member (100) is provided only on the fastening portion (98) side in the first gap (101).

In the said 2nd invention, the upper end part (92) of a motor stand (90) is fastened by the one side end side or casing (40), and fastening part (98) of a top plate (43). That is, the fastening portion (98) restrains the upper end portion (92) and the one end side of the top plate (43) or the casing (40). For this reason, in the fastening portion (98), the vibration of the electric motor (17) is easily transmitted. And the elastic member (100) is provided in the fastening part (98) side in the 1st clearance gap (101). Therefore, a constraining point by the fastening portion (98) is formed on one end side of the top plate (43) which is less likely to vibrate, between the upper end portion (92) and the top plate (43). Therefore, since the vibration of the electric motor (17) is transmitted from the upper end (92) to one end of the top plate (43) through the restraint point of the fastening portion (98), the vibration of the top plate (43) can be suppressed. .

    According to a third invention, in the first or second invention, the heat exchanger (23) is formed of an aluminum material, and the second gap (103) is formed between the heat exchanger (23) and an upper end portion. (92) is spaced apart and electrically non-contact.

    In the third aspect of the invention, when the heat exchanger (23) formed of an aluminum material and the upper end (92) made of, for example, a steel plate are electrically contacted and fixed, a heat exchanger having a high ionization tendency Although there is a possibility that (23) may be galvanic corrosion (electric corrosion), the heat exchanger (23) and the upper end portion (92) are not in electrical contact by the second gap (103). For this reason, a heat exchanger (23) does not carry out galvanic corrosion (electric corrosion).

    On the other hand, since the vibration caused by the electric motor (17) is transmitted to one end side of the top plate (43) via the elastic member (100), the vibration of the top plate (43) can be suppressed.

    According to the first aspect of the present invention, the hollow laminated portion including the upper end portion (92), a part of the first gap (101), and the top plate (43) on the opposite side of the one end side of the top plate (43) that easily vibrates. (105) is formed, and a solid laminated portion (104) composed of an upper end portion (92), an elastic member (100), and the top plate (43) is formed on one end side of the top plate (43) that hardly vibrates. The vibration caused by (17) can be transmitted only to one end side of the top plate (43) through the elastic member (100). For this reason, it can suppress reliably that a top plate (43) vibrates by the vibration of an electric motor (17).

    Further, since the elastic member (100) is provided between the upper end portion (92) and the top plate (43), it is possible to prevent the upper end portion (92) and the top plate (43) from coming into direct contact. For this reason, even if a compressor (21) etc. vibrate, the contact sound (billing sound) which generate | occur | produces when an upper end part (92) and a top plate (43) contact can be suppressed.

    As a result, in the outdoor unit, while preventing the generation of contact noise (chattering noise) due to direct contact between the top plate (43) and the upper end (92) due to vibration of the compressor (21) etc., the electric motor The vibration of the top plate (43) due to the vibration of (17) can be reliably prevented.

    According to the second aspect of the invention, since the elastic member (100) is provided on the fastening portion (98) side in the first gap (101), vibration of the electric motor (17) is transmitted from the upper end portion (92) to the fastening portion (98). It can be transmitted from the restraint point to the one end side of the top plate (43) which does not vibrate easily. Thereby, the vibration of the top plate (43) can be suppressed.

    According to the third aspect, since the second gap (103) is provided, the heat exchanger (23) and the upper end portion (92) can be brought into electrical non-contact. For this reason, it can prevent that a heat exchanger (23) carries out galvanic corrosion (electric corrosion).

    On the other hand, since the vibration of the electric motor (17) is transmitted to one end side of the top plate (43) via the elastic member (100), the vibration of the top plate (43) can be suppressed.

It is a piping system diagram showing the refrigerant circuit concerning this embodiment. It is a perspective view which shows the external appearance of the outdoor unit which concerns on this embodiment. It is the outdoor unit which concerns on this embodiment, Comprising: It is a typical top view which shows the state which removed the top plate. It is a figure which shows the internal structure of the outdoor unit which concerns on this embodiment. It is the figure which looked at the motor stand concerning this embodiment from the front. It is the figure which looked at the motor stand concerning this embodiment from the side. It is a figure which expands and shows the motor stand and top plate which concern on this embodiment. It is the top view which looked at the motor stand concerning this embodiment from the upper part. It is a part of outdoor unit concerning this embodiment, Comprising: It is a perspective view which shows a baseplate and an outdoor heat exchanger. It is a figure which shows the outdoor heat exchanger which concerns on this embodiment. It is XI-XI sectional drawing of FIG.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

    Hereinafter, the air conditioner (10) will be described first, and then the outdoor unit (11) and the outdoor heat exchanger (23) will be described in detail.

<Overall configuration of air conditioner>
As shown in FIG. 1, the air conditioner (10) includes an outdoor unit (11) and an indoor unit (12). The outdoor unit (11) and the indoor unit (12) are connected via a liquid side connecting pipe (13) and a gas side connecting pipe (14). A refrigerant circuit (20) is formed by the outdoor unit (11), the indoor unit (12), the liquid side connection pipe (13), and the gas side connection pipe (14).

    The refrigerant circuit (20) includes a compressor (21), a four-way switching valve (22), an outdoor heat exchanger (23), an expansion valve (24), an indoor heat exchanger (25), and an accumulator (26). Yes. The compressor (21), the four-way switching valve (22), the outdoor heat exchanger (23), the expansion valve (24) and the accumulator (26) are accommodated in the outdoor unit (11). The outdoor unit (11) is provided with an outdoor fan (15) for supplying outdoor air to the outdoor heat exchanger (23). On the other hand, the indoor heat exchanger (25) is accommodated in the indoor unit (12). The indoor unit (12) is provided with an indoor fan (16) for supplying room air to the indoor heat exchanger (25). The outdoor fan (15) constitutes a blower fan according to the present invention.

    The compressor (21) has its discharge side connected to the first port of the four-way switching valve (22) and its suction side connected to the second port of the four-way switching valve (22) via the accumulator (26). Yes. In the refrigerant circuit (20), the outdoor heat exchanger (23), the expansion valve (24), and the indoor heat exchanger (in order) from the third port to the fourth port of the four-way switching valve (22). 25) is arranged.

    The compressor (21) is a scroll type or rotary type hermetic compressor. The four-way switching valve (22) includes a first state (state indicated by a solid line in FIG. 1) in which the first port communicates with the third port and the second port communicates with the fourth port; The port is switched to a second state (state indicated by a broken line in FIG. 1) in which the port communicates with the fourth port and the second port communicates with the third port. The expansion valve (24) is a so-called electronic expansion valve.

    The outdoor heat exchanger (23) exchanges heat between the outdoor air and the refrigerant. The outdoor heat exchanger (23) will be described later. On the other hand, the indoor heat exchanger (25) exchanges heat between the indoor air and the refrigerant. The indoor heat exchanger (25) is constituted by a so-called cross fin type fin-and-tube heat exchanger provided with a heat transfer tube which is a circular tube.

    The accumulator (26) gas-liquid-separates the refrigerant and sucks only the gas refrigerant into the compressor (21).

<Configuration of outdoor unit>
Next, the outdoor unit (11) will be described with reference to FIGS. “Up”, “Down”, “Left”, “Right”, “Front”, and “Rear” used in the description here are directions when the outdoor unit (11) is viewed from the front side unless otherwise specified. I mean.

    The outdoor unit (11) includes a casing (40). The casing (40) is a steel plate box that is vertically long and formed in a substantially rectangular parallelepiped shape. The casing (40) has a bottom plate (41) and a front side plate (42a), a left side plate (42b), a rear side plate (42c) and a right side plate (42d) which are erected on the bottom plate (41). However, the left and right direction is the longitudinal direction. A top plate (43) is attached to the upper end of each side plate (42a to 42d) in the casing (40). That is, the top plate (43) is attached and supported on the outer peripheral end of the upper portion of the casing (40). The top plate (43) is formed in a substantially rectangular steel plate. The top plate (43) is formed with an attachment portion (43a) that is fastened to an upper end portion (92) of a motor base (90) described later.

    Inside the casing (40), a partition plate (44) is erected from the front plate (42a) toward the rear (in the short direction) in an arc shape in plan view. The internal space of the casing (40) is partitioned by the partition plate (44) into a left blower chamber (S1) and a right machine chamber (S2). In the blower room (S1), an outdoor heat exchanger (23), an outdoor fan (15), a fan motor (17) for rotationally driving the outdoor fan (15), and a motor carrying the fan motor (17) A stand (90) is housed. Specifically, in the blower room (S1), the outdoor fan (15), fan motor (17), motor base (90) and outdoor heat exchanger (23) are arranged in this order from the front side to the rear side. Yes. The fan motor (17) constitutes an electric motor according to the present invention, and the motor base (90) constitutes an electric motor base according to the present invention.

    On the other hand, the machine room (S2) includes a compressor (21), a four-way switching valve (22) (not shown in FIG. 3), an expansion valve (24) (not shown in FIG. 3), and an accumulator (26). And is housed.

    The rear plate (42c) of the casing (40) has a rear suction port (45a) on the fan chamber (S1) side, and the left plate (42b) has a left suction port (45b). . These two suction ports (45a, 45b) are for sucking air (outdoor air) into the blower chamber (S1).

    In the front plate (42a) of the casing (40), an air outlet (46) is opened on the fan chamber (S1) side. This blower outlet (46) is for blowing off air (outdoor air) from the inside of the blower chamber (S1) to the outside. A fan grill (47) is fitted into the air outlet (46).

    As shown in FIGS. 3 to 8, the motor base (90) is a base that supports the fan motor (17) of the outdoor fan (15). The motor base (90) is erected between the outdoor heat exchanger (23) inside the blower chamber (S1) and the outdoor fan (15). The motor base (90) is attached to the bottom plate (41) and the top plate (43) of the casing (40). The motor base (90) includes a lower end part (95), a motor base body (91), and an upper end part (92).

    A lower end part (95) is a member which comprises the lower part of a motor stand (90). A lower end part (95) is formed in the substantially flat plate shape made from a steel plate, and is extended along the bottom plate (41) of a casing (40). The lower end (95) extends from the lower end of the motor base body (91) in the orthogonal direction of the motor base body (91). The lower end (95) is fastened to the side of the motor base body (91) by screws (96). The lower end (95) is attached to the bottom plate (41). By doing so, the motor base (90) is fixed to the casing (40).

    The motor base body (91) is a member constituting the main body of the motor base (90), and constitutes a base body according to the present invention. The motor base body (91) is formed in a substantially flat plate shape made of a steel plate, and is disposed in the fan chamber (S1) so as to be separated from the outdoor heat exchanger (23), and from the bottom plate (41) to the top plate (43). It extends in the vertical direction toward the substantially central portion. A fan mounting portion (97) for supporting the fan motor (17) is formed at the center of the motor base body (91) in the height direction. The fan motor (17) is mounted on the fan mounting portion (97), whereby the fan motor (17) is carried on the motor base (90). The motor base body (91) has a lower end (95) attached to its lower end and an upper end (92) attached to its upper end.

    An upper end part (92) is a member which comprises the upper part of a motor stand (90). The upper end portion (92) is formed in a substantially flat plate shape made of steel plate. The upper end (92) is bent from the upper end of the motor base body (91) and extends horizontally along the top plate (43) toward the outer end of the top plate (43). The upper end portion (92) has an upper surface facing the inner surface of the top plate (43) with a first gap (101), and a lower surface facing the upper end surface of the outdoor heat exchanger (23) and a second gap ( 103) and are arranged to face each other. The base end of the upper end portion (92) is fixed to the motor base body (91) by screws (94).

    The upper end portion (92) is formed with an attachment piece (93) that is bent downward from the outer end thereof. The mounting piece (93) is formed to have a predetermined distance from the outdoor heat exchanger (23). The attachment piece (93) is fastened to the attachment portion (43a) of the top plate (43) by a fastening screw (98). By doing so, the motor base (90) is attached to the top plate (43). The fastening screw (98) constitutes a fastening portion of the present invention.

    Next, the configuration between the upper end (92) and the outdoor heat exchanger (23) will be described, and then the configuration between the upper end (92) and the top plate (43) will be described.

    Between the lower surface of the upper end (92) and the upper end of the outdoor heat exchanger (23), a second gap (103) and a second sealing material (102) are interposed. Specifically, the second gap (103) is formed between the lower surface of the upper end portion (92) and the upper end surface of the outdoor heat exchanger (23). A second sealing material (102) is disposed in the second gap (103). The second sealing material (102) is formed into a substantially U-shaped sealing member in cross-sectional view. The 2nd sealing material (102) is attached so that the upper end part of an outdoor heat exchanger (23) may be covered. The second sealing material (102) prevents water leakage from the outdoor heat exchanger (23).

    Since each constituent member of the outdoor heat exchanger (23) is made of aluminum, when the upper end (92) made of a steel plate is brought into direct contact, iron and aluminum, which are metals having different ionization tendencies, come into contact with each other. Thus, galvanic corrosion (electric corrosion) of the outdoor heat exchanger (23) having a high ionization tendency is promoted. For this reason, by providing the 2nd clearance gap (103) between an outdoor heat exchanger (23) and an upper end part (92), both are prevented from contacting electrically.

    A first gap (101) is formed between the upper end (92) and the top plate (43). The first gap (101) is a gap formed between the upper surface of the upper end (92) and the inner surface of the top plate (43). In the first gap (101), the first sealing material (100) is interposed only on the outer end side of the top plate (43). The upper end part (92) and the top plate (43) constitute a solid laminated part (104) and a hollow laminated part (105).

    The solid laminated portion (104) is positioned on the outer end side of the top plate (43), and is configured by laminating the upper end portion (92), the first sealing material (100), and the top plate (43). .

    The hollow laminated portion (105) is located inside the top plate (43) (on the side opposite to the outer end of the top plate (43)), and a part of the upper end (92) and the first gap (101) (first A portion where the first sealing material (100) is not provided) and the top plate (43) are laminated in one gap (101).

    The first sealing material (100) is formed in a substantially U-shaped sealing member in plan view. The first sealing material (100) is disposed on the outer end side of the top plate (43) on the upper surface of the upper end portion (92) of the motor base (90), and the upper surface of the upper end portion (92) and the top plate (43) It is interposed between the inner surface. The first sealing material (100) has a thickness of about 1 mm.

    In the present embodiment, the solid laminated portion (104) is provided in a region that occupies approximately half of the upper surface of the upper end portion (92) in the longitudinal direction, and the remaining approximately half region in the longitudinal direction of the upper surface of the upper end portion (92). The hollow laminated part (105) is formed in the.

<Configuration of outdoor heat exchanger>
Next, the outdoor heat exchanger (23) will be described with reference to FIG. 3 and FIGS.

    As shown in FIGS. 3 and 9, the outdoor heat exchanger (23) is formed in a substantially L shape in plan view, and faces the two suction ports (45a, 45b) in the blower chamber (S1). Is installed.

    As shown in FIG. 10, the outdoor heat exchanger (23) includes a first header collecting pipe (51), a second header collecting pipe (52), a large number of flat tubes (53), and a large number of fins (55). ). The first header collecting pipe (51), the second header collecting pipe (52), the flat tube (53), and the fin (55) are all made of aluminum and are joined to each other by brazing.

    Both the first header collecting pipe (51) and the second header collecting pipe (52) are formed in an elongated cylindrical shape with both ends closed. As shown in FIG. 3, in the fan chamber (S1), the first header collecting pipe (51) is erected between the rear side plate (42c) and the partition plate (44), and the second header collecting pipe ( 52) is erected on the corners of the front plate (42a) and the left plate (42b).

    As shown in FIG. 11, the flat tube (53) is a heat transfer tube whose cross-sectional shape is a flat oval shape, and a plurality of fluid passages (54) arranged in a row are formed inside. Yes. As shown in FIG. 10, the plurality of flat tubes (53) are arranged in the vertical direction with a certain distance from each other with their flat side surfaces facing each other, and are substantially parallel to each other.

    As shown in FIGS. 3 and 9, the flat tube (53) is formed in a substantially L shape in a plan view and extends in the left-right direction (longitudinal direction) in FIG. 3, and in FIG. And a short side portion (53b) extending in the front-rear direction (short direction). The long side portion (53a) of the flat tube (53) faces the rear suction port (45a), and its end portion is inserted into the first header collecting pipe (51), and a plurality of fluid passages (54 ) Communicates with the internal space of the first header collecting pipe (51). On the other hand, the short side portion (53b) of the flat tube (53) faces the left suction port (45b), and its end portion is inserted into the second header collecting pipe (52), and a plurality of fluid passages ( 54) communicates with the internal space of the second header collecting pipe (52).

    As shown in FIGS. 10 and 11, the fin (55) is a vertically long plate-like fin formed by pressing a metal plate. The plurality of fins (55) are arranged in the extending direction of the flat tube (53) at a constant interval from each other, and a ventilation path (58) is formed between adjacent fins (55). Air (outdoor air) passes through the ventilation path (58) from the suction port (45a, 45b) side to the blower chamber (S1) side. In the fin (55), notches (56) are formed at regular intervals in the vertical direction on the inlet (45a, 45b) side, which is the windward side. And the flat tube (53) is inserted in the leeward part of each notch part (56).

    As shown in FIG. 10, the outdoor heat exchanger (23) is divided into an upper main heat exchange region (61) and a lower auxiliary heat exchange region (62), and each heat exchange region (61, 62). ) Is divided into three heat exchanging parts (61a to 61c, 62a to 62c). Specifically, in the main heat exchange region (61), the first main heat exchange part (61a), the second main heat exchange part (61b), and the third main heat exchange part in order from bottom to top. (61c) is formed. In the auxiliary heat exchange region (62), in order from bottom to top, a first auxiliary heat exchange unit (62a), a second auxiliary heat exchange unit (62b), and a third auxiliary heat exchange unit (62c) Is formed. The number of flat tubes (53) constituting each main heat exchange part (61a to 61c) is larger than the number of flat tubes (53) constituting each auxiliary heat exchange part (62a to 62c).

    The internal space of the first header collecting pipe (51) is partitioned into an upper space (71) and a lower space (72) by a partition plate (51a). The upper space (71) communicates with all the flat tubes (53) constituting the main heat exchange region (61), and the lower space (72) is all the flat tubes constituting the auxiliary heat exchange region (62). Communicates with (53). In addition, a gas side connecting pipe (75) and a liquid side connecting pipe (76) are connected to the first header collecting pipe (51). The gas side connection pipe (75) has one end connected to the upper part of the first header collecting pipe (51) and communicated with the upper space (71), and the other end connected to the third port of the four-way switching valve (22). Has been. The liquid side connection pipe (76) has one end connected to the lower part of the first header collecting pipe (51) and communicating with the lower space (72), and the other end connected to the expansion valve (24).

    The internal space of the second header collecting pipe (52) is divided into a main communication space (81) corresponding to the main heat exchange area (61) and an auxiliary communication space (82) corresponding to the auxiliary heat exchange area (62). Has been. The main communication space (81) is divided into a first partial space (81a), a second partial space (81b), and a third partial space (81c) in order from the bottom to the top by the two partition plates (52a). It is partitioned. Each partial space (81a-81c) is connected with all the flat tubes (53) which comprise each main heat exchange part (61a-61c).

    The auxiliary communication space (82) is divided into a fourth partial space (82a), a fifth partial space (82b), and a sixth partial space (82c) in order from the bottom to the top by the two partition plates (52b). It is partitioned. Each partial space (82a-82c) is connected with all the flat tubes (53) which comprise each auxiliary heat exchange part (62a-62c).

    Two connecting pipes (85, 86) are attached to the second header collecting pipe (52). The first connection pipe (85) has one end connected to the second partial space (81b) and the other end connected to the fifth partial space (82b). The second connection pipe (86) has one end connected to the third partial space (81c) and the other end connected to the fourth partial space (82a). In the second header collecting pipe (52), the first partial space (81a) and the sixth partial space (82c) form one continuous space.

    As shown in FIG. 9, the outdoor heat exchanger (23) is supported from below by three rubber members (31 to 33) disposed on the bottom plate (41) of the casing (40), and further, each header collecting pipe (51, 52) are fixed to the side plates (42b, 42c) of the casing (40) by two mounting members (57) provided on each side.

    The rubber members (31 to 33) are formed of an insulating rubber material, and the outdoor heat exchanger (23) is damped, and the header collecting pipe (51, 52) and the bottom plate (41) of the casing (40) Is insulated.

    The mounting member (57) includes a bracket (not shown) fixed to the header collecting pipe (51, 52), a mounting plate (not shown) fixed to the side plates (42b, 42c), and an insulating resin cover ( And the bracket and the mounting plate are insulated inside the resin cover.

    Thus, the outdoor heat exchanger (23) avoids electrical contact between the header collecting pipe (51, 52) and the casing (40) by the rubber member (31-33) and the mounting member (57). In addition, the corrosion (electric corrosion) of the header collecting pipe (51, 52) is prevented.

-Air conditioner operation-
The air conditioner (10) selectively performs a cooling operation and a heating operation.

    In the refrigerant circuit (20) during the cooling operation, the refrigeration cycle is performed with the four-way switching valve (22) set to the first state. In this state, the refrigerant circulates in the order of the outdoor heat exchanger (23), expansion valve (24), indoor heat exchanger (25), and accumulator (26), and the outdoor heat exchanger (23) functions as a condenser. The indoor heat exchanger (25) functions as an evaporator. In the outdoor heat exchanger (23), the gas refrigerant flowing from the compressor (21) dissipates heat to the outdoor air and condenses, and the condensed refrigerant flows out toward the expansion valve (24).

    In the refrigerant circuit (20) during the heating operation, the refrigeration cycle is performed with the four-way switching valve (22) set to the second state. In this state, the refrigerant circulates in the order of the indoor heat exchanger (25), expansion valve (24), outdoor heat exchanger (23), and accumulator (26), and the indoor heat exchanger (25) functions as a condenser. The outdoor heat exchanger (23) functions as an evaporator. The refrigerant that has expanded into the gas-liquid two-phase state flows into the outdoor heat exchanger (23) when passing through the expansion valve (24). The refrigerant that has flowed into the outdoor heat exchanger (23) absorbs heat from the outdoor air and evaporates, and then flows out toward the compressor (21).

-Casing vibration-
When the operation of the air conditioner (10) is started, the compressor (21) is driven, and vibration due to this drive is transmitted to the entire casing (40). At this time, since the first sealing material (100) is provided between the upper end (92) and the top plate (43), the upper end (92) and the top plate (43) are in direct contact with each other. There is nothing. Therefore, even if the vibration resulting from the compressor (21) occurs, it is possible to suppress the contact sound (chatter noise) generated by the direct contact between the upper end portion (92) and the top plate (43).

    When the fan motor (17) is driven, the outdoor fan (15) rotates. The vibration caused by the drive of the fan motor (17) is transmitted to the motor base (90), but a second gap (103) is formed between the upper end and the upper end (92) of the outdoor heat exchanger (23). Therefore, it is difficult to propagate to the outdoor heat exchanger (23). On the other hand, the vibration caused by the drive of the fan motor (17) is transmitted to the motor base (90), and is transmitted to the top plate (43) through the periphery of the first seal member (100) and the fastening screw (98).

    Specifically, on the outer end side of the top plate (43), the upper end portion (92), the first sealing material (100), and the top plate (43) constitute a solid laminated portion (104). That is, the 1st sealing material (100) is provided in the outer end side of the top plate (43) which is hard to vibrate among the upper end part (92) and the top plate (43). For this reason, since the vibration of the fan motor (17) is transmitted to the outer end side of the top plate (43) via the first sealing material (100), the vibration of the top plate (43) is suppressed.

    In addition, on the side opposite to the outer end side of the top plate (43) that is likely to vibrate (on the motor base body (91) side), a part of the upper end portion (92) and the first gap (101) and the top plate (43) And the hollow laminated portion (105) is formed. In other words, between the upper end (92) and the top plate (43), the first gap (101) is provided on the side opposite to the outer end side (the motor base body (91) side) of the top plate (43) that easily vibrates. Part of is formed. For this reason, since vibration of the fan motor (17) is not transmitted to the top plate (43), vibration of the top plate (43) can be suppressed.

    The upper end portion (92) of the motor base (90) is fastened to the mounting piece (93) and the mounting portion (43a) of the top plate (43) by fastening screws (98). That is, the fastening screw (98) restrains the upper end (92) and the top plate (43). For this reason, the vibration of the fan motor (17) is easily transmitted at the restraint point by the fastening screw (98). And the 1st sealing material (100) is provided in the fastening screw (98) side in the 1st crevice (101). Therefore, a restraint point by the fastening screw (98) is formed on one end side of the top plate (43) which is hard to vibrate, between the upper end portion (92) and the top plate (43). Therefore, the vibration of the fan motor (17) is transmitted from the upper end portion (92) to the one end side of the top plate (43) through the restraint point by the fastening screw (98), so that the vibration of the top plate (43) can be suppressed. .

    When the outdoor heat exchanger (23) made of aluminum material and the upper end (92) made of, for example, a steel plate are fixed in electrical contact, the outdoor heat exchanger (23) having a high ionization tendency is galvanically corroded. Although there is a possibility of (electric corrosion), the outdoor heat exchanger (23) and the upper end portion (92) are not in electrical contact with each other by the second gap (103). For this reason, the outdoor heat exchanger (23) does not galvanically corrode (electric corrosion).

-Effect of the embodiment-
According to the present embodiment, the top plate (92) and a part of the first gap (101) on the side opposite to the outer end side (the motor base body (91) side) of the top plate (43) that easily vibrates and the top plate A hollow laminate part (105) made of (43) is formed, and the top end part (92), the first sealing material (100), and the top board (43) are formed on the outer end side of the top board (43) which is hard to vibrate. Since the actual laminated portion (104) is formed, the vibration caused by the fan motor (17) can be transmitted only to the outer end side of the top plate (43) through the first seal material (100). For this reason, it can suppress reliably that a top plate (43) vibrates by the vibration of a fan motor (17).

    Moreover, since the first sealing material (100) is provided between the upper end (92) and the top plate (43), it is possible to prevent the upper end (92) and the top plate (43) from coming into direct contact. it can. For this reason, even if a compressor (21) etc. vibrate, the contact sound (billing sound) which generate | occur | produces when an upper end part (92) and a top plate (43) contact can be suppressed.

    As a result, in the outdoor unit (11), the generation of contact noise (chattering noise) due to direct contact between the top plate (43) and the upper end (92) due to vibration of the compressor (21), etc. is prevented. However, the vibration of the top plate (43) due to the vibration of the fan motor (17) can be reliably prevented.

    Further, since the first sealing material (100) is provided on the side of the fastening screw (98) in the first gap (101), the vibration of the fan motor (17) is caused from the upper end (92) from the restraint point by the fastening screw (98). Can be transmitted to the outer end side of the top plate (43), which is less likely to vibrate. Thereby, the vibration of the top plate (43) can be suppressed.

    Furthermore, since the second gap (103) is provided, the outdoor heat exchanger (23) and the upper end portion (92) can be brought into electrical non-contact. For this reason, it can prevent that an outdoor heat exchanger (23) carries out galvanic corrosion (electric corrosion).

    On the other hand, since the vibration of the fan motor (17) is transmitted to the outer end side of the top plate (43) via the first sealing material (100), the vibration of the top plate (43) can be suppressed.

<Other embodiments>
The present invention may be configured as follows with respect to the above embodiment.

    In the above embodiment, the first sealing material (100) is disposed so as to cover a substantially half region of the upper surface in the longitudinal direction of the upper end portion (92), and the remaining half region on the upper surface of the upper end portion (92). Although the 1st clearance gap (101) was formed, this invention is not restricted to this, The contact sound by the direct contact of a top plate (43) and upper end part (92) resulting from the vibration of a compressor (21) ( Any structure that can reliably prevent vibration of the top plate (43) due to vibration of the fan motor (17) while preventing occurrence of chattering noise) may be used.

    In the above embodiment, the top plate (43) and the upper end portion (92) of the motor base (90) are fastened. However, the present invention is not limited to this, and the upper end portion of the motor base (90) ( 92) and the casing (40) may be fastened.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for an outdoor unit of an air conditioner.

15 Outdoor fan 17 Fan motor 21 Compressor 23 Air heat exchanger 40 Casing 43 Top plate 53 Flat tube 54 Fluid passage 55 Fin 90 Motor base 91 Motor base body 92 Upper end 98 Fastening screw 100 First seal material 101 First gap 103 Second gap 104 Solid laminated part 105 Hollow laminated part

Claims (3)

A compressor (21), a heat exchanger (23), a blower fan (15), and an electric motor (17) for rotating the blower fan (15) in a casing (40) to which the top plate (43) is attached An air conditioner outdoor unit in which an electric motor base (90) supporting
The top plate (43) is supported on the outer periphery of the casing (40) and covers the upper portion of the casing (40),
The motor base (90) extends in a vertical direction from the lower part of the casing (40) toward the top plate (43), and has a base body (91) to which the motor (17) is attached, and the base body (91 ) Extending from the upper end of the heat exchanger (23) to one end of the top plate (43) along the top plate (43) and covering the upper end of the heat exchanger (23), and the top plate (43) A first gap (101) is formed between the upper end of the heat exchanger (23) and a second gap (103) is formed with the upper end (92).
The first gap (101) is provided with an elastic member (100) only on one end side of the top plate (43),
The top plate (43) and the upper end portion (92) are formed by laminating the upper end portion (92), the elastic member (100), and the top plate (43) on one side end side of the top plate (43). An upper end portion (92), a part of the first gap (101), and the top plate (43) are laminated on the side opposite to the one side end side of the actual laminated portion (104) and the top plate (43). Comprising a hollow laminate (105) ,
In the first gap (101), the elastic member (100)
One end of one side end of the top plate (43) is one side end of the top plate (43) than one end of one side end of the top plate (43) in the heat exchanger (23). Located on the side
The other end of the top plate (43) opposite to the one end is more than the other end of the heat exchanger (23) opposite to the one end of the top plate (43). An outdoor unit for an air conditioner, which is provided so as to be positioned on one side end side of the top plate (43) . In claim 1,
The upper end portion (92) includes a fastening portion (98) fastened to one end side of the top plate (43) or the casing (40),
The outdoor unit for an air conditioner, wherein the elastic member (100) is provided only on the fastening portion (98) side in the first gap (101). In claim 1 or 2,
The heat exchanger (23) is formed of an aluminum material,
The second gap (103) is formed such that the heat exchanger (23) and the upper end (92) are separated from each other so as not to be in electrical contact with each other. .

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