JP2012239284A - End member of rotor, motor including rotor end member, and compressor including motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To sufficiently cool a rotor by using a simple structure without increasing the output loss of a motor.SOLUTION: An end plate (93) of a rotor (90) includes a flat plate like end plate body (94) and is disposed on an axial end surface of a driving shaft (64) of a rotor core (91). The end plate body (94) protrudes in the axial direction of the driving shaft (64), is formed concentrically with the rotation center of the driving shaft (64), and includes an annular protruding part (95) radiating heat of the rotor core (91).

Description

    The present invention relates to an end member of a rotor, a motor including the rotor end member, and a compressor including the motor, and particularly relates to cooling of the rotor.

    Conventionally, a refrigeration apparatus including a refrigerant circuit that performs a refrigeration cycle by circulating refrigerant is known. As a compressor that compresses a refrigerant in this type of refrigerant circuit, a so-called turbo compressor (centrifugal compressor) that compresses the refrigerant using centrifugal force is known.

    Patent Document 1 discloses this type of turbo compressor. The turbo compressor includes a drive shaft that is rotationally driven by an electric motor, and an impeller (impeller) is connected to the drive shaft. When the impeller rotates with the rotation of the drive shaft, in the impeller chamber that houses the impeller, the axial refrigerant flows radially outward, and the centrifugal force of the impeller is applied to the refrigerant.

    In the turbo compressor described above, it is necessary to cool the rotor in order to prevent thermal demagnetization of the permanent magnet provided in the rotor.

    As a means for cooling the rotor, a means for cooling the rotor by providing a heat sink in contact with the rotating rotor core can be considered. As another rotor cooling means, a means is known in which a hollow portion is formed in a shaft integral with the rotor, and a cooling refrigerant is passed through the hollow portion to cool the rotor from the center of the shaft.

Japanese Unexamined Patent Publication No. 04-110388

    However, in the above-described rotor cooling means, the heat sink rotates together with the rotor core, so that the surrounding fluid becomes a stirring resistance and an output loss occurs.

    Further, the other rotor cooling means described above requires a mechanism for inflow and discharge of the cooling refrigerant in the hollow portion of the shaft, which increases the cost of the refrigeration apparatus. Further, in this cooling means, since the refrigerant passing through the hollow portion cools the rotor via the shaft, the rotor cannot be directly cooled, and thus the cooling performance is not sufficient.

    That is, the conventional rotor cooling means has a problem that the rotor cannot be sufficiently cooled with a simple configuration while suppressing the output loss of the motor.

    The present invention has been made in view of such a point, and an object of the present invention is to sufficiently cool a rotor with a simple configuration while suppressing output loss of a motor.

    A first aspect of the present invention is an end member of a rotor that includes a flat plate-like main body portion (94) and is disposed on one end surface in the axial direction of the rotation shaft (64) of the rotor core (91). ) Includes an annular protrusion (95) that protrudes in the axial direction of the rotating shaft (64) and is formed concentrically with the rotation center of the rotating shaft (64) to dissipate the heat of the rotor core (91). It is what.

    In the end member of the rotor according to the first aspect of the present invention, the flat plate-like main body portion (94) is formed concentrically with the center of the rotating shaft (64) and is an annular protruding portion protruding in the rotating shaft (64) direction ( 95). The heat of the rotor core (91) is transmitted to the protrusion (95) through the main body (94), and the protrusion (95) dissipates heat to the surrounding fluid, thereby cooling the rotor core (91).

    In the rotor end member of the first invention, since the protrusion (95) is formed in an annular shape concentric with the rotation center of the rotation shaft (64), even if the rotor rotates, the stirring resistance of the fluid around the rotor Increase is suppressed. For this reason, the output loss of the motor does not increase.

    In a second aspect based on the first aspect, the main body (94) is formed with a plurality of annular protrusions (95a, 95b, 95c) outward in the radial direction. In the projections (95a, 95b, 95c), the height of the projection (95c) formed radially outward is lower than the height of the projection (95b) formed radially inward. It is formed as follows.

    In the second aspect of the invention, the main body (94) is formed with a plurality of annular protrusions (95a, 95b, 95c) outward in the radial direction. The height of the radially outer protrusion (95c) is lower than the height of the protrusion (95b) formed on the inner side (inward in the radial direction). That is, the height of each protrusion (95a, 95b, 95c) is formed so as to decrease radially outward.

    When the protrusions (95a, 95b, 95c) are formed as in the second invention, since the height of the protrusions (95c) is low outward in the radial direction, an increase in centrifugal force that is greater toward the outside is suppressed. For this reason, the protrusions (95a, 95b, 95c) are hardly deformed or damaged by centrifugal force.

    According to a third invention, in the first or second invention, the main body (94) is formed with a plurality of annular protrusions (95a, 95b, 95c) outward in the radial direction. In the plurality of protrusions (95a, 95b, 95c), the thickness of the protrusion (95c) formed radially outward is larger than the thickness of the protrusion (95b) formed radially inward. It is formed to be thick.

    In the third aspect of the invention, the main body (94) is formed with a plurality of annular protrusions (95a, 95b, 95c) outward in the radial direction. The thickness of the projecting portion (95c) radially outward is greater than the thickness of the projecting portion (95b) formed on the inner side (inward in the radial direction). That is, the thickness of each protrusion (95a, 95b, 95c) is formed so as to increase radially outward.

    When the protrusions (95a, 95b, 95c) are formed as in the third aspect of the invention, the protrusions (95c) are formed thicker on the outer side in the radial direction where the centrifugal force increases, so that they can withstand the centrifugal force. it can. For this reason, the protrusions (95a, 95b, 95c) are hardly deformed or damaged by centrifugal force.

    According to a fourth aspect of the present invention, there is provided a rotor (90) in which an end member (93) having a plate-like main body portion (94) is disposed on at least one end surface in the axial direction of the rotation shaft (64) of the rotor core (91). And a stator (62) disposed so as to surround an outer portion extending in the axial direction of the rotating shaft (64) of the rotor (90), and the main body (94) of the end member (93) An annular protrusion (95) that projects in the axial direction of the rotary shaft (64) and is concentric with the rotational center of the rotary shaft (64) to dissipate the heat of the rotor core (91) is formed.

    In the fourth aspect of the invention, the end member (93) having the flat plate-shaped main body portion (94) is disposed on at least one end surface in the axial direction of the rotating shaft (64) of the rotor core (91) to form the rotor (90). Has been. The main body (94) of the end member (93) includes an annular protrusion (95) that is formed concentrically with the center of the rotating shaft (64) and protrudes in the direction of the rotating shaft (64). The stator (62) is disposed so as to surround an outer portion extending along the axial direction of the rotation shaft (64) of the rotor (90).

    The heat of the rotor (90) is transferred to the protrusion (95) through the rotor core (91) and the main body (94), and the protrusion (95) dissipates heat to the surrounding fluid, so that the rotor (90) Is cooled.

    Here, when the rotor is rotated by driving the motor, the stirring resistance of the fluid around the rotor is increased by the end member attached to the rotor core. However, in the motor of the fourth invention, the protrusion (95) is formed on the end member (93) of the rotor (90) in an annular shape concentric with the rotation center of the rotation shaft (64). Even if the rotation of the rotor, the increase in the stirring resistance of the fluid around the rotor (90) can be suppressed. For this reason, the output loss of the motor does not increase.

    According to a fifth aspect of the present invention, the airtight container (41), the compression mechanism (40a, 40b) disposed in the airtight container (41), the airtight container (41), and the compression mechanism And a motor (61) for driving the portions (40a, 40b), wherein the motor (61) has an end member (93) having the flat plate-shaped main body portion (94) as a rotor core (91). ) And a rotor (90) formed on at least one end surface in the axial direction of the rotation shaft (64), and an outer portion extending in the axial direction of the rotation shaft (64) of the rotor (90). The main body (94) protrudes in the axial direction of the rotating shaft (64) and is concentric with the rotation center of the rotating shaft (64). ) In which an annular protrusion (95) for radiating heat is formed.

    In the fifth aspect of the invention, the compression mechanism (40a, 40b) and the motor (61) for driving the compression mechanism (40a, 40b) are arranged in the sealed container (41). The motor (61) includes a stator (62) and a rotor (90). The rotor (90) is formed by disposing an end member (93) having a flat plate-shaped main body portion (94) on at least one end surface in the axial direction of the rotation shaft (64) of the rotor core (91). The main body (94) of the end member (93) is provided with an annular protrusion (95) that is formed concentrically with the center of the rotating shaft (64) and projects in the axial direction of the rotating shaft (64). ing. The stator (62) is disposed so as to surround an outer portion extending along the axial direction of the rotation shaft (64) of the rotor (90).

    The heat of the rotor (90) is transferred to the protrusion (95) via the rotor core (91) and the main body (94), and the protrusion (95) dissipates heat to the surrounding fluid, so that the rotor core (91) Is cooled.

    Here, when the rotor is rotated by driving the motor, the stirring resistance of the fluid around the rotor is increased by the end member attached to the rotor core. However, in the compressor according to the fifth aspect, the protrusion (95) is formed in the end member (93) of the rotor (90) in an annular shape concentric with the rotation center of the rotation shaft (64). ) Can be prevented from increasing the stirring resistance of the fluid around the rotor (90). For this reason, the output loss of the motor (61) does not increase.

    According to the first aspect, since the annular protrusion (95) is provided on the main body (94), the surface area of the end member of the rotor can be increased. Thereby, the cooling performance to the rotor core (91) can be improved with a simple configuration. On the other hand, since the shape of the protrusion (95) is formed in an annular shape concentric with the rotation center of the rotation shaft (64), the stirring resistance of the fluid around the rotating rotor (90) can be suppressed. As a result, the rotor can be sufficiently cooled without increasing the output loss of the motor and with a simple configuration.

    According to the second aspect of the present invention, since the plurality of protrusions (95) are formed so as to become radially outward, the increase in centrifugal force applied to the radially outward protrusion (95c) is suppressed. Can do. Thereby, when the end member of the rotor is attached to the rotating rotor core (91), it is possible to reliably prevent the protrusion (95c) from being deformed or damaged by the centrifugal force of the rotation.

    According to the third aspect of the invention, since the plurality of protrusions (95) are formed so as to become thicker radially outward, the strength of the radially outward protrusion (95c) can be increased. Thereby, when the end member of the rotor is attached to the rotating rotor core (91), it is possible to reliably prevent the protrusion (95c) from being deformed or damaged by the centrifugal force of the rotation.

    According to the fourth aspect of the invention, since the annular protrusion (95) is provided on the main body (94), the surface area of the end member of the rotor can be increased. Thereby, the cooling performance to the rotor core (91) can be improved with a simple configuration. On the other hand, since the shape of the protrusion (95) is formed in an annular shape concentric with the rotation center of the rotation shaft (64), the stirring resistance of the fluid around the rotating rotor (90) can be suppressed. As a result, the rotor (90) can be sufficiently cooled without increasing the output loss of the motor and with a simple configuration.

    According to the fifth aspect, since the annular protrusion (95) is provided on the main body (94), the surface area of the end member of the rotor (90) can be increased. Thereby, the cooling performance to the rotor core (91) can be improved with a simple configuration. On the other hand, since the shape of the protrusion (95) is formed in an annular shape that is concentric with the rotation center of the rotation shaft (64), it is possible to prevent the rotor (90) rotating in the sealed container (41) from becoming a stirring resistance. . As a result, the rotor (90) can be sufficiently cooled with a simple configuration without increasing the output loss of the motor (61).

It is a piping system figure showing the air harmony device concerning an embodiment. It is a longitudinal section showing a compressor concerning an embodiment. The drive shaft and rotor which concern on embodiment are shown, Comprising: (A) is the figure which looked at the drive shaft and the rotor from upper direction, (B) is a figure which shows the BB cross section of (A).

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

    As shown in FIG. 1, the air conditioner (10) includes an outdoor unit (20) and three indoor units (30, 30, 30), and performs indoor air conditioning. The number of indoor units (30) is merely an example.

    The air conditioner (10) includes a refrigerant circuit (11) that is filled with a refrigerant and performs a refrigeration cycle. The refrigerant circuit (11) includes an outdoor circuit (12) accommodated in the outdoor unit (20) and indoor circuits (13, 13, 13) accommodated in the indoor units (30). These indoor circuits (13) are connected to the outdoor circuit (12) by the liquid side connecting pipe (14) and the gas side connecting pipe (15). Each indoor circuit (13) is connected in parallel to the outdoor circuit (12).

<Configuration of outdoor circuit>
The outdoor circuit (12) is provided with a compressor (40), an outdoor heat exchanger (21), an outdoor expansion valve (22), and a four-way switching valve (23).

    The compressor (40) constitutes a so-called turbo (centrifugal) compressor. The compressor (40) has a discharge side connected to the second port (P2) of the four-way switching valve (23) and a suction side connected to the first port (P1) of the four-way switching valve (23). Details of the compressor (40) will be described later.

    The outdoor heat exchanger (21) is configured as a cross fin type fin-and-tube heat exchanger. An outdoor fan (24) is provided in the vicinity of the outdoor heat exchanger (21). In the outdoor heat exchanger (21), heat is exchanged between the outdoor air and the refrigerant. One end of the outdoor heat exchanger (21) is connected to the third port (P3) of the four-way switching valve (23), and the other end is connected to the outdoor expansion valve (22). The fourth port (P4) of the four-way selector valve (23) is connected to the gas side communication pipe (15).

    The outdoor expansion valve (22) is provided between the outdoor heat exchanger (21) and the liquid side end of the outdoor circuit (12). The outdoor expansion valve (22) is configured as an electronic expansion valve with a variable opening.

    The four-way selector valve (23) is in a first state in which the first port (P1) and the fourth port (P4) communicate with each other and the second port (P2) and the third port (P3) communicate with each other (FIG. 1). In the second state (shown in FIG. 1), the first port (P1) and the third port (P3) communicate with each other, and the second port (P2) and the fourth port (P4) communicate with each other. The state shown by a broken line) can be switched freely.

<Indoor circuit configuration>
Each indoor circuit (13, 13, 13) has an indoor heat exchanger (31, 31, 31), an indoor expansion valve (32, 32, 32) in order from the gas side end to the liquid side end. Is provided.

    The indoor heat exchanger (31) is configured as a cross-fin type fin-and-tube heat exchanger. An indoor fan (33) is provided in the vicinity of the indoor heat exchanger (31). In the indoor heat exchanger (31), heat is exchanged between the indoor air and the refrigerant. The indoor expansion valve (32) is configured as an electronic expansion valve with a variable opening.

<Compressor configuration>
The compressor (40) shown in FIG. 2 constitutes a so-called oilless compressor that does not require lubricating oil for each sliding portion. The compressor (40) constitutes a multistage compressor that compresses the refrigerant in two stages to increase the pressure. Further, the compressor (40) constitutes a so-called low-pressure dome type compressor in which the inside is filled with a low-pressure refrigerant.

    The compressor (40) includes a horizontally long casing (41) in the form of a closed container. The casing (41) constitutes a sealed container according to the present invention. The casing (41) includes a substantially cylindrical main body casing (42), and a first side plate (43) formed at one end (the left end in FIG. 2) of the main body casing (42) in the axial direction; The main body casing (42) includes a second side plate (44) formed at the other axial end portion (the right end portion in FIG. 2).

    The main casing (42) is formed in a bottomed cylindrical shape in which the right end is open and the left end is covered by the closing portion (46). A first bearing portion (51) that bulges toward the second side plate (44) is formed on the axial center side of the closing portion (46). In addition, two leg portions (45, 45) are attached to the lower part of the outer peripheral surface of the main casing (42). The leg portions (45, 45) support the casing (41) from below.

    The first partition member (47) and the second partition member (48) are fitted in the open portion on the right side of the main casing (42) so as to be adjacent to each other. A second bearing portion (52) that bulges toward the first side plate (43) is formed on the axial center side of the first partition member (47). Moreover, the recessed part (49) depressed toward the 1st side plate (43) is formed in the center of the right side surface of the 1st partition member (47). The second partition member (48) is in contact with the first partition member (47) so as to close the recess (49).

    In the compressor (40), the motor chamber (60) is defined between the main casing (42) and the first partition member (47), and the first chamber (42) is positioned between the first side plate (43) and the main casing (42). A first impeller chamber (70) is formed, and a second impeller chamber (80) is formed between the second side plate (44) and the second partition member (48).

    The motor chamber (60) houses a motor (61) as an electric motor. The motor (61) has a stator (62) fixed to the inner peripheral wall surface of the main casing (42), and a rotor (90) disposed inside the stator (62). That is, the stator (62) is disposed in the main casing (42) so as to cover the outer peripheral surface of the rotor (90). A drive shaft (64) extending in the axial direction of the main casing (42) is fixed to the central portion of the rotor (90). One end portion of the drive shaft (64) passes through the blocking portion (46) and is pivotally supported by the first bearing portion (51). The other end of the drive shaft (64) passes through the first partition member (47) and is pivotally supported by the second bearing portion (52). The rotor (90) will be described later.

    The first impeller chamber (70) and the second impeller chamber (80) are formed in a substantially truncated cone shape whose cross-section is enlarged toward the main body casing (42) side. The first impeller chamber (70) accommodates the first impeller (71), and the second impeller chamber (80) accommodates the second impeller (81). Each impeller (71, 81) has a plurality of triangular plate-shaped wings (71a, 81a) formed radially around its axis. Each impeller (71, 81) is connected to the end of the drive shaft (64), and is rotatable in each impeller chamber (70, 80). Each impeller (71, 81) configured as described above constitutes a radial impeller that generates a radial flow toward the outer peripheral side.

    A first spiral chamber (72) is formed between the first side plate (43) and the main casing (42) on the outer peripheral side of the first impeller chamber (70), and the outer peripheral side of the second impeller chamber (80). A second spiral chamber (82) is formed between the second side plate (44) and the second partition member (48). In addition, a first diffuser (73) for communicating both chambers (71, 72) is formed between the first impeller chamber (70) and the first spiral chamber (72), and the second impeller chamber (80). A second diffuser (83) that communicates both chambers (81, 82) is formed between the second spiral chamber (82) and the second spiral chamber (82). Each diffuser (73, 83) constitutes a flow path for converting the dynamic pressure of the refrigerant released to the outer peripheral side by the centrifugal force of each impeller (71, 81) into a static pressure. Each spiral chamber (72, 82) constitutes a space for collecting the pressurized refrigerant and guiding it to the outside of the casing (41).

    The first impeller chamber (70), the first impeller (71), the first spiral chamber (72), the first diffuser (73), and the first inlet (74) are connected to the first compression mechanism (40a). It is composed. The second impeller chamber (80), the second impeller (81), the second spiral chamber (82), the second diffuser (83), and the second inlet (84) are connected to the second compression mechanism (40b). It is composed. These 1st compression mechanism parts (40a) and the 2nd compression mechanism part (40b) comprise the compression mechanism part which concerns on this invention.

    A suction pipe (54), a first relay pipe (55), a second relay pipe (56), and a discharge pipe (57) are connected to the compressor (40). The suction pipe (54) has an inflow end connected to the low-pressure line of the refrigerant circuit (11), and an outflow end of the suction pipe (54) facing the motor chamber (60) through the main body casing (42). That is, the motor chamber (60) is an atmosphere of low-pressure refrigerant in the refrigerant circuit (11). The inflow end of the first relay pipe (55) passes through the main body casing (42) and faces the motor chamber (60), and the outflow end of the first relay pipe (55) passes through the top of the first side plate (43). A first inflow port (74) is formed in the axial center of the first side plate (43), and the first relay pipe (55) and the first impeller chamber ( 70). The outflow end of the suction pipe (54) and the inflow end of the first relay pipe (55) are arranged so as to sandwich the motor (61). That is, the low-pressure refrigerant flowing out from the suction pipe (54) flows through the motor chamber (60), passes through the motor (61), and then flows into the first relay pipe (55). Thereby, in the motor chamber (60), the motor (61) is cooled by the low-pressure refrigerant.

    The inflow end of the second relay pipe (56) communicates with the first spiral chamber (72), and the outflow end passes through the top of the second side plate (44). A second inlet (84) is formed in the axial center of the second side plate (44), and the second relay pipe (56) and the second impeller chamber ( 80). The discharge pipe (57) has an inflow end communicating with the second spiral chamber (82) and an outflow end connected to the high-pressure line of the refrigerant circuit (11).

    Herringbone grooves (65, 65) are respectively formed on the outer peripheral surfaces of both ends of the drive shaft (64). The herringbone groove (65, 65) is formed at a position corresponding to each of the bearing portions (51, 52) described above. The herringbone groove (65, 65) forms a gas film due to gas pressure in the gap between the bearing portion (51, 52) and the drive shaft (64) as the drive shaft (64) rotates. That is, a dynamic pressure gas bearing that supports the drive shaft (64) and the bearing portions (51, 52) in a non-contact state between the rotating drive shaft (64) and the bearing portions (51, 52). A journal gas bearing (66) is formed.

    In addition, labyrinth seals (67, 67) are also formed on the outer peripheral surfaces of both ends of the drive shaft (64). The labyrinth seal (67, 67) is formed closer to the end of the drive shaft (64) than the herringbone groove (65, 65). The labyrinth seal (67, 67) is configured by arranging a plurality of circular grooves in the axial direction. Each labyrinth seal (67, 67) constitutes a non-contact seal for preventing leakage of refrigerant from the impeller chamber (70, 80) to the motor chamber (60).

    A thrust bearing plate (68) is accommodated in the recess (49) of the first partition member (47). The thrust bearing plate (68) is integrally connected to the end of the drive shaft (64). Helical grooves (not shown) are formed on both end faces of the thrust bearing plate (68). The spiral groove forms a gas film due to gas pressure in the gap between the thrust bearing plate (88) and the partition member (47, 48) as the drive shaft (64) rotates. That is, a thrust gas bearing that supports the drive shaft (64) in the thrust direction is formed between the rotating thrust bearing plate (68) and the partition members (47, 48).

    As shown in FIGS. 2 and 3, the rotor (90) includes a rotor core (91) and end plates (93, 93) attached to both end faces in the axial direction of the rotor core (91).

    The rotor core (91) is formed in a substantially cylindrical shape, and a shaft hole (92) through which the drive shaft (64) is inserted is formed at the center of the shaft. The rotor core (91) is attached to the drive shaft (64) with the drive shaft (64) inserted through the shaft hole (92). The rotor core (91) is configured to rotate integrally with the drive shaft (64).

    The said end plate (93) is a member which comprises the both ends of the axial direction of the said rotor (90), Comprising: The end member which concerns on this invention is comprised. The end plate (93) is made of, for example, an aluminum alloy such as duralumin, and has an end plate main body (94) and a protrusion (95) formed on the surface of the end plate main body (94). ing. In addition, the material which comprises an end plate (93) is not restricted to the aluminum alloy mentioned above, What is necessary is just a high-strength and lightweight metal material. The end plate (93) is attached to the drive shaft (64) by press fitting or shrink fitting.

    The said end plate main body (94) suppresses the magnet embedded in a rotor core (91) from the both end surfaces of the axial direction of a rotor core (91), and comprises the main-body part which concerns on this invention. The end plate body (94) is formed in a substantially disc shape, and a shaft hole portion (96) through which the drive shaft (64) is inserted is formed at the center of the end plate body (94). The end plate body (94) is disposed on each end face of the rotor core (91) in the axial direction.

    The protrusion (95) is a heat radiating member that is formed on the surface of the end plate body (94) and radiates heat from the rotor core (91). The protrusion (95) is composed of first to third protrusions (95a, 95b, 95c) that are formed in order from the periphery of the drive shaft (64) toward the radially outer side. The first to third protrusions (95a, 95b, 95c) are formed to protrude in the axial direction of the drive shaft (64) from the surface of the end plate body (94). The first to third protrusions (95a, 95b, 95c) are all formed in an annular shape concentric with the rotation center of the drive shaft (64). And the 1st-3rd projection part (95a, 95b, 95c) is formed so that it may become a large diameter toward the outward of radial direction. That is, the first protrusion (95a) formed on the innermost side in the radial direction is formed with the smallest diameter, and the third protrusion (95c) formed on the outermost side in the radial direction is formed with the largest diameter, The 2nd protrusion part (95b) formed in the intermediate position of a direction is formed in the diameter between them.

-Operation of air conditioner-
The operation of the air conditioner (10) will be described with reference to FIG. The air conditioner (10) can perform a cooling operation and a heating operation, and switching between the cooling operation and the heating operation is performed by a four-way switching valve (23).

<Cooling operation>
During the cooling operation, the four-way selector valve (23) is set to the first state. When the compressor (40) is operated in this state, the high-pressure refrigerant discharged from the compressor (40) releases heat to the outdoor air and condenses in the outdoor heat exchanger (21). The refrigerant condensed in the outdoor heat exchanger (21) is distributed to each indoor circuit (13). In each indoor circuit (13), the refrigerant flowing in is depressurized by the indoor expansion valve (32), and then absorbs heat from the indoor air in the indoor heat exchanger (31) and evaporates. On the other hand, the room air is cooled and supplied to the room.

    The refrigerant evaporated in each indoor circuit (13) merges with the refrigerant evaporated in the other indoor circuit (13) and returns to the outdoor circuit (12). In the outdoor circuit (12), the refrigerant returned from each indoor circuit (13) is compressed again by the compressor (40) and discharged.

<Heating operation>
During the heating operation, the four-way selector valve (23) is set to the second state. When the compressor (40) is operated in this state, the high-pressure refrigerant discharged from the compressor (40) is distributed to each indoor circuit (13). In each indoor circuit (13), the inflowing refrigerant dissipates heat to the indoor air and condenses in the indoor heat exchanger (31). On the other hand, room air is heated and supplied indoors. The refrigerant condensed in the indoor heat exchanger (31) joins in the outdoor circuit (12).

    The refrigerant merged in the outdoor circuit (12) is depressurized by the outdoor expansion valve (22), and then absorbs heat from the outdoor air and evaporates in the outdoor heat exchanger (21). The refrigerant evaporated in the outdoor heat exchanger (21) is compressed again by the compressor (40) and discharged.

−Operation of compressor−
Next, the operation of the compressor (40) will be described in detail with reference to FIG. In the compressor (40), the low-pressure refrigerant in the refrigerant circuit (11) is increased to an intermediate pressure in the first impeller chamber (70), and the intermediate-pressure refrigerant after the pressure increase is increased to a high pressure in the second impeller chamber (80). Is done. That is, the compressor (40) performs so-called two-stage compression.

    When the motor (61) is energized, the drive shaft (64) is driven at a high speed (for example, 100,000 rpm). When the drive shaft (64) rotates, the journal gas bearing (66) between the first bearing portion (51) and the drive shaft (64) or between the second bearing portion (52) and the drive shaft (64). Is formed. Thus, the drive shaft (64) is supported in the radial direction in a non-contact state with the bearing portions (51, 52). A thrust gas bearing is formed between the thrust bearing plate (68) and the first partition member (47), or between the thrust bearing plate (68) and the second partition member (48). As a result, the drive shaft (64) is supported in the thrust direction. As described above, when the compressor (40) is operated, a gas film is formed on the radial / thrust bearings of the drive shaft (64), so that no lubricating oil for lubricating these bearings is required, so-called oilless Compression operation is possible.

    When the drive shaft (64) rotates, the first impeller (71) and the second impeller (81) connected to the drive shaft (64) rotate. When both the impellers (71, 81) rotate, the low-pressure refrigerant in the refrigerant circuit (11) is introduced into the motor chamber (60) through the suction pipe (54). The refrigerant flowing into the motor chamber (60) passes through the motor (61) in the axial direction and then flows out to the first relay pipe (55). At this time, the motor (61) is cooled by the low-pressure refrigerant, and the heat generation of the motor (61) is suppressed.

    The refrigerant flowing through the first relay pipe (55) is drawn into the axial center side of the first impeller chamber (70) through the first inlet (74). In the first impeller chamber (70), the axial refrigerant flows along the plurality of blades (71a) and flows radially outward. At this time, the centrifugal force of the first impeller (71) is applied to the refrigerant. The refrigerant sent to the outer peripheral side of the first impeller chamber (70) flows into the first diffuser (73). In the first diffuser (73), the refrigerant is decelerated to change from dynamic pressure to static pressure, flows into the first spiral chamber (72) in a pressurized state, and then flows out to the second relay pipe (56).

    The refrigerant flowing through the second relay pipe (56) is sucked into the axial center side of the second impeller chamber (80) through the second inlet (84). In the second impeller chamber (80), the refrigerant on the axial center side flows along the plurality of blades (81a) and flows radially outward. At this time, the centrifugal force of the second impeller (81) is applied to the refrigerant. The refrigerant sent to the outer peripheral side of the second impeller chamber (80) flows into the second diffuser (83). In the second diffuser (83), the refrigerant is decelerated to change from dynamic pressure to static pressure, flows into the second spiral chamber (82) in a pressurized state, and then discharged from the discharge pipe (57) to the refrigerant circuit (11). Is done.

    When the motor (61) is driven, the drive shaft (64) rotates together with the rotor (90). At this time, the rotor core (91) generates heat due to the energization resistance of the coil. The heat of the rotor core (91) is transmitted to the end plate main body (94) of the end plate (93), and is radiated from the protrusion (95) to the low-pressure refrigerant in the motor chamber (60). In this embodiment, since the rotor (90) rotates at a high speed, the relative speed between the rotor (90) and the refrigerant around the rotor (90) is increased, and thus the cooling performance is further improved.

    On the other hand, since the protrusion (95) is formed in an annular shape concentric with the rotation center of the drive shaft (64), the stirring resistance of the low-pressure refrigerant in the motor chamber (60) is increased even when the rotor (90) rotates. It can be suppressed. For this reason, an increase in output loss of the motor (61) due to the protrusion (95) can be suppressed. In this embodiment, the output loss of the motor (61) refers to a loss (loss) due to the resistance of the fluid (the low-pressure refrigerant in the motor chamber (60)) with respect to the rotation of the rotor (90).

-Effect of the embodiment-
According to this embodiment, since the annular protrusion (95) is provided on the end plate main body (94), the surface area of the end member of the rotor can be increased. For this reason, the cooling performance to the rotor core (91) can be improved with a simple configuration. Thereby, the cost of a compressor (40) can be reduced.

    On the other hand, since the shape of the protrusion (95) is formed in an annular shape concentric with the rotation center of the drive shaft (64), an increase in the stirring resistance of the refrigerant around the rotor (90) rotating at high speed can be suppressed.

    As a result, the rotor (90) can be sufficiently cooled with a simple configuration while suppressing the output loss of the motor (61).

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

    The plurality of protrusions (95a, 95b, 95c) may be formed such that the thickness (width in the radial direction) of the protrusion (95) gradually increases toward the outside in the radial direction. Specifically, the third protrusion (95c) is formed to be the thickest, and the first protrusion (95a) is formed to be the thinnest. The second protrusion (95b) is formed to be thicker than the first protrusion (95a) and thinner than the third protrusion (95c). By doing so, the strength of the protrusion (95c) formed outward in the radial direction is increased.

    Since the radially outward protrusion (95c) is formed thick, it can withstand centrifugal force that increases toward the outside. Thereby, when attaching the end plate (93) of the rotor (63) to the rotating rotor core (91), it is possible to suppress the third projecting portion (95c) from being deformed / damaged by the centrifugal force of the rotation.

    The plurality of protrusions (95a, 95b, 95c) may be formed such that the height of the protrusion (95) gradually decreases toward the outside in the radial direction. In this case, the height of the third protrusion (95c) is the lowest and the height of the first protrusion (95a) is the highest. By carrying out like this, the raise of this centrifugal force can be suppressed in the outward of the radial direction to which the most centrifugal force is applied. Thereby, when attaching the end plate (93) of the rotor (63) to the rotating rotor core (91), it is possible to suppress the third projecting portion (95c) from being deformed / damaged by the centrifugal force of the rotation.

    The plurality of protrusions (95a, 95b, 95c) may be formed so that the thickness (the width in the radial direction) of the protrusion (95) gradually increases toward the outer side in the radial direction. .

    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 the rotor end member, the motor including the rotor end member, and the compressor including the motor.

40a 1st compression mechanism part 40b 2nd compression mechanism part 41 Casing 61 Motor 62 Stator 64 Drive shaft 90 Rotor 91 Rotor core 93 End plate 94 End plate main body 95 Protrusion part 95a 1st protrusion part 95b 2nd protrusion part 95c 3rd protrusion part

Claims (5)

An end member of a rotor that includes a flat plate-shaped main body (94) and is disposed on one end surface in the axial direction of the rotation shaft (64) of the rotor core (91),
The main body (94) protrudes in the axial direction of the rotary shaft (64) and is formed concentrically with the rotational center of the rotary shaft (64) to dissipate heat from the rotor core (91). (95) It is provided with the end member of the rotor characterized by the above-mentioned. In claim 1,
The main body (94) has a plurality of annular protrusions (95a, 95b, 95c) formed radially outward.
In the plurality of protrusions (95a, 95b, 95c), the height of the protrusion (95c) formed radially outward is higher than the height of the protrusion (95b) formed radially inward. An end member of a rotor, wherein the end member is formed to be low. In claim 1 or 2,
The main body (94) has a plurality of annular protrusions (95a, 95b, 95c) formed radially outward.
In the plurality of projections (95a, 95b, 95c), the thickness of the projection (95c) formed radially outward is larger than the thickness of the projection (95b) formed radially inward. An end member of a rotor, wherein the end member is formed as follows. A rotor (90) formed by disposing an end member (93) having a flat plate-shaped main body portion (94) on at least one end surface in the axial direction of the rotation shaft (64) of the rotor core (91);
A stator (62) disposed so as to surround an outer portion extending in the axial direction of the rotation shaft (64) of the rotor (90),
The main body (94) of the end member (93) protrudes in the axial direction of the rotating shaft (64) and is concentric with the rotational center of the rotating shaft (64) to heat the rotor core (91). An annular projection (95) for radiating heat is formed. A sealed container (41), a compression mechanism (40a, 40b) disposed in the sealed container (41), and disposed in the sealed container (41), and the compression mechanism (40a, 40b) And a motor (61) for driving the compressor,
The motor (61) is formed by arranging an end member (93) having the flat plate-shaped main body portion (94) on at least one end surface in the axial direction of the rotation shaft (64) of the rotor core (91) ( 90) and a stator (62) disposed so as to surround an outer portion extending in the axial direction of the rotating shaft (64) of the rotor (90),
The main body (94) has an annular protrusion that protrudes in the axial direction of the rotating shaft (64) and is concentric with the rotational center of the rotating shaft (64) to dissipate heat from the rotor core (91). A compressor characterized in that a portion (95) is formed.

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