JP5045153B2 - Compressor - Google Patents

Description

  The present invention relates to a compressor used in a refrigerator, and particularly to a compressor with an external accumulator.

  Conventionally, a refrigerator includes a compressor for compressing a refrigerant, and an accumulator on the suction side of the compressor for performing gas-liquid separation of the refrigerant and sucking only the gas refrigerant into the compressor. Yes. From the viewpoint of space saving and layout, a compressor is known in which the accumulator is externally attached and fixed to the compressor casing.

  Patent document 1 is mentioned as a prior art of such a compressor with an accumulator.

  FIG. 4 shows a longitudinal sectional view of a compressor with an accumulator in Patent Document 1.

  The compressor main body (70) provided in the compressor of Patent Document 1 includes a cylindrical body (71) and a bowl-shaped end plate (72) that is welded and fixed to the top and bottom of the body (71). A casing (71, 72) is provided, a compression mechanism (73) for compressing the refrigerant in the casing (71, 72), and a drive connected by the compression mechanism (73) and the drive shaft (75) A motor (74) is housed. The casing (71, 72) penetrates the discharge pipe (78) provided so as to penetrate the upper end of the casing (71, 72) and the side part of the casing (71, 72). And an inlet tube (79b) connected to the suction port (73a) of the compression mechanism (73). The drive motor (74) includes a stator (77) fixed to the inner peripheral surface of the body (71) by shrink fitting or the like, and a rotor (not shown) that is rotatably arranged inside the stator (77). 76).

  On the other hand, the accumulator (80) provided in the compressor of Patent Document 1 includes a cylindrical casing (81) closed at both ends, and a refrigerant outlet pipe (through the lower end portion of the casing (81) ( 79a) is provided, and a refrigerant inlet pipe (82) is provided so as to penetrate the upper end. One end of the refrigerant outlet pipe (79a) is located in the internal space of the accumulator (80), and the other end is connected to the inlet tube (79b) of the compressor body (70). ) And the refrigerant outlet pipe (79a) form a suction pipe (79) to constitute a refrigerant suction path for the compressor body (70).

  An accumulator fixing plate (83) is attached between the body (71) of the compressor body (70) and the accumulator (80). That is, the accumulator (80) is externally attached and fixed to the compressor body (70) by the suction pipe (79) and the accumulator fixing plate (83).

  By the way, in the compressor of Patent Document 1, a magnetic force is generated in the stator (77) by energizing the stator (77), and the rotor (76) rotates by receiving the generated magnetic force. At this time, the stator (77) vibrates by alternately receiving a force attracted to or separated from the rotor (76). By this vibration, the casing body (71) to which the stator (77) is fixed is directly vibrated. Then, it is conceivable that the vibration of the trunk portion (71) causes the accumulator (80) to vibrate via the accumulator fixing plate (83) connected to the trunk portion (71).

In order to reduce the vibration of the accumulator (80) by such a drive motor (74), in the compressor of this patent document 1, the root of the teeth of the laminated steel plate forming the stator (77) of the drive motor (74) is described. A space is provided. By providing this space, it is possible to absorb vibration propagated from the stator (77) to the body (71). Thereby, the vibration of the trunk part (71) is reduced, and the vibration propagating to the accumulator (80) through the accumulator fixing plate (83) connected to the trunk part (71) can be reduced. It becomes.
JP 2003-343439 A

  However, in Patent Document 1, since a space is provided at the base of the teeth of the laminated steel sheet forming the stator, magnetic saturation is easily performed, and even if the vibration of the accumulator can be reduced, the torque and efficiency of the drive motor are reduced. May fall.

  The present invention has been made in view of such points, and an object of the present invention is to reduce vibration propagating to an accumulator via an accumulator fixing plate without reducing the efficiency of a drive motor in a compressor with an accumulator. It is intended to suppress an increase in operation sound due to vibration of the accumulator, generation of abnormal noise, vibration propagation to a refrigerator equipped with the compressor with the accumulator, and damage to the compressor.

The first invention comprises a compressor body (10) and an accumulator (50) attached to the compressor body (10) via a support member (2). The compressor body (10) is a casing. (14) and its inner wall in a fixed compression mechanism (20) and a motor (30) for driving the compression mechanism (20), the casing (14), the compression mechanism (20) and the motor ( 30) attached to the first casing member (11) having both ends or one end opened, and the second casing member (12, 13) fixed to both ends or one end opening end of the first casing member (11). It assumes a compressor consisting of

In the present invention, in the compressor, the compression mechanism (20) and the outer surface of the electric motor (30) are fixed to the inner wall of the first casing member (11) , and the second casing member (12, 13) is fixed. ), The support member (2) is fixed.

Here, the compression mechanism (20) and the electric motor (30) constitute an excitation source of the compressor, and the excitation source is fixed to the inner wall of the first casing member (11). Thereby, the first casing member (11) is directly vibrated from the inner wall . On the other hand, the second casing member (12, 13) is not attached with the excitation source and is not directly excited, but the vibration of the excitation source is not transmitted through the first casing member (11). Attenuated and transmitted. As described above, the vibration caused by the excitation source is lower in the second casing member (12, 13) that is indirectly excited than in the first casing member (11) that is directly excited. Become.

  In the first invention, one end of the support member (2) is attached to the accumulator (50), the other end is attached to the second casing member (12, 13), and the accumulator (50) is attached to the compressor body (10). It is fixed to. Thus, by attaching the support member (2) to the second casing (12, 13) indirectly excited from the excitation source, the excitation source is passed through the support member (2). Vibration propagating to the accumulator (50) can be kept low.

The second invention comprises a compressor body (10) and an accumulator (50) attached to the compressor body (10) via a support member (2). The compressor body (10) is a casing. (14) and a compression mechanism (20) fixed to the inner wall thereof, and an electric motor (30) for driving the compression mechanism (20). The casing (14) includes the compression mechanism (20) and the electric motor (30 ) And the first casing member (11) having both ends or one end opened and the second casing member (12, 13) fixed to both ends or one end opening end of the first casing member (11). It is assumed that the compressor. The compression mechanism (20) and the electric motor (30) are fixed to the first casing member (11) of the compressor, and the support member (2) is fixed to the second casing member (12, 13). the second casing member (12, 13) has a spherical or substantially spherical curved surface, the support member (2) is characterized by being attached to the spherical or substantially spherical curved surface. Here, when comparing the second casing member (12, 13) having a spherical or substantially spherical curved surface with the second casing member (12, 13) not having a spherical or substantially spherical curved surface, A spherical curved surface has higher rigidity. The second casing members (12, 13) need not all be formed in a spherical or substantially spherical curved surface, but may be partially formed in a spherical or substantially spherical shape. When a partially spherical or substantially spherical curved surface is formed, the support member (2) is preferably attached on the spherical or substantially spherical curved surface.

  In the second invention, the rigidity of the second casing member (12, 13) can be reliably increased, so that the first casing member (11) propagates to the second casing member (12, 13). Vibration can be reliably reduced. Thereby, vibration propagating from the excitation source to the accumulator (50) via the support member (2) can be suppressed to a low level.

  A third invention is characterized in that, in the first or second invention, an attachment band (2a) for holding the accumulator (50) is provided at the other end of the support member (2). .

  In the first and second inventions, it can be considered that the support member (2) and the accumulator (50) are joined by welding. In the third invention, the support member (2) and the accumulator (50) are considered. The accumulator (50) is fastened with the mounting band (2a) provided on the support member (2) without welding the support member (2), thereby fixing the support member (2) and the accumulator (50). can do. That is, since the support member (2) and the accumulator (50) are not joined by welding, the support member (2), the accumulator (50), the first casing member (11), and the second casing member. The number of options for the assembly process with respect to the assembly order between (12, 13) increases, and the degree of freedom in the assembly process increases. Even if the support member (2) is not attached to the second casing member (12, 13) at an accurate position, the first casing member (11) and the second casing member (12) , 13) Since it is a separate member, its position can be adjusted. From this, for example, without forcibly deforming the refrigerant pipe or the like serving as the suction path (15), the mounting error can be adjusted by adjusting the position of the first and second casing members (11, 12, 13) and the mounting band ( It can be absorbed with 2a).

  As described above, the vibration propagating from the excitation source to the accumulator (50) through the support member (2) can be suppressed to a low level while increasing the degree of freedom in the assembly process and absorbing the mounting error.

  According to the present invention, the vibration propagating from the excitation source to the accumulator (50) through the support member (2) by attaching the support member (2) to the second casing member (12, 13). Can be kept low. This suppresses the increase in operating noise due to the vibration of the accumulator (50), the generation of abnormal noise, the propagation of vibration to the refrigerator equipped with the compressor (1) with the accumulator and the damage to the compressor (1). Can do.

  According to the second invention, the second casing member (12, 13) has a spherical or substantially spherical curved surface, and the support member (2) is attached to the spherical or substantially spherical curved surface, thereby The vibration propagating from the vibration source to the second casing member (12, 13) via the first casing member (11) can be reliably suppressed to a low level. Thereby, the vibration propagated from the second casing member (12, 13) to the accumulator (50) via the support member (2) can be suppressed low.

  According to the third invention, by providing the mounting band (2a), the degree of freedom in the assembly process is increased, and the mounting error between the second casing member (12, 13) and the support member (2) is increased. The vibration propagating from the excitation source to the accumulator (50) through the support member (2) can be suppressed low. As a result, it is possible to suppress an increase in operation sound due to vibration of the accumulator (50), generation of abnormal noise, vibration propagation to the refrigerator equipped with the compressor with the accumulator, and damage to the compressor. In addition, by providing the mounting band (2a), the performance of the compressor due to the damage of the pipe itself due to the deformation of the refrigerant pipe or the like serving as the suction path (15) and the reduction of the suction cross-sectional area due to the damage of the pipe itself The decrease can be suppressed.

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

  The compressor (compressor) (1) with an accumulator of this embodiment is one in which an accumulator (50) is externally attached to a casing (14) of a compressor body (10) from the viewpoints of space saving and layout.

-Configuration of compressor with accumulator-
FIG. 1 is a longitudinal sectional view of the compressor with accumulator (1). The compressor with accumulator (1) includes a compressor body (10) and an accumulator (50), as shown in the figure. The accumulator (50) is connected to the compressor body (10) by an accumulator fixing plate (2). It is fixed to the casing (14).

<Compressor body>
The compressor body (10) includes a compressor mechanism (20) for compressing a refrigerant as a working fluid, and a compressor motor (a drive motor coupled to the compressor mechanism (20) by a drive shaft (31)). 30) is housed in a casing (14) and formed into a completely sealed type, so-called high pressure dome type.

  The casing (14) includes a cylindrical body (first casing member) (11) and an end plate (second casing) having a substantially spherical curved surface that is welded and fixed to the upper and lower ends of the body (11). Member) (12, 13). An inlet tube (15b) penetrating the trunk portion (11) is provided at a lower portion of the trunk portion (11). One end of the inlet tube (15b) is connected to an inlet (21a) provided in the compression mechanism (20), and the other end is connected to a refrigerant outlet pipe (15a) of an accumulator (50) described later. Yes. Here, a suction pipe (15) is formed by the inlet tube (15b) and the refrigerant outlet pipe (15a), and the suction pipe (15) forms a refrigerant suction path to the compressor body (10). Yes. On the other hand, a discharge pipe (16) penetrating the body (11) is provided at the upper part of the body (11), and the discharge pipe (16) constitutes a refrigerant discharge path to the compressor body (10). is doing. The upper end plate (12) is provided with a terminal (17) that is connected to an external power source (not shown) and supplies power to the compressor motor (30). It should be noted that illustration of electrical wiring connecting the terminal (17) and the compressor motor (30) is omitted.

  The compression mechanism (20) includes a cylinder (21) and a rotary piston (25) disposed in the cylinder (21) .The cylinder (21) includes a cylinder body (22) and a front head ( 23) and a rear head (24). The cylinder body (22) is formed in a cylindrical shape, is fixed to the inner surface of the casing (14) by welding, and is disposed concentrically with the casing (14). The front head (23) and the rear head (24) are provided so as to sandwich the cylinder body (22) from above and below, and are fastened by bolts (29) and assembled integrally with the cylinder body (22). .

  The front head (23) is formed with a shaft hole (23a) penetrating the center up and down, and the drive shaft (31) is rotatably fitted in the shaft hole (23a). The drive shaft (31) is integrally formed with an eccentric portion (32) fitted into the rotary piston (25). A compression chamber (26) is defined in the cylinder (21), and the rotary piston (25) swings or revolves within the compression chamber (26) as the drive shaft (31) rotates. By doing so, the refrigerant is compressed.

  Although not shown, the front head (23) has a discharge hole for discharging the high-pressure refrigerant inside the compression chamber (26). The discharge hole is provided with a discharge valve (not shown), and when the refrigerant pressure inside the compression chamber (26) rises, the discharge valve opens, and the inside of the compression chamber (26) and the casing (14) It is possible to communicate with the inside.

  The compressor motor (30) includes a stator (34) as a stator and a rotor (35) as a rotor, and is disposed above the compression mechanism (20).

  The stator (34) includes a cylindrical stator core (36), an upper end plate (37) and a lower end plate (38) made of insulating members disposed at the upper end and the lower end of the stator core (36), The stator core (36) and three-phase windings (39) wound around both end plates (37, 38) are provided. Here, the stator core (36) is shrink-fitted in the body (11) of the casing (14). The stator (34) is configured to generate a rotating magnetic field by energizing each winding (39) through the terminal (17).

  The rotor (35) includes a cylindrical rotor core (41) in which a large number of electromagnetic steel sheets as magnetic materials are laminated in the axial direction, and upper and lower ends of the rotor core (41). And an end plate (42) provided.

  The upper part of the drive shaft (31) is shrink-fitted and fixed at the center of the rotor (35), and the rotor (35) is located between the stator (34) and the stator (34). An air gap (47) with a slight gap is formed and is rotatably arranged. Although not shown, the rotor (35) is fitted with a plate-like permanent magnet so as to form square sides around the drive shaft (31). Thus, the rotor (35) rotates inside the stator (34) by a rotating magnetic field generated in the stator (34), and applies a rotational driving force to the compression mechanism (20) to thereby compress the compression mechanism (20 ).

<accumulator>
The accumulator (50) is connected to the suction pipe (15a) of the compressor body (10) and performs gas-liquid separation of the refrigerant on the suction side of the compressor body (10). The accumulator (50) has a storage space (55) for storing the liquid refrigerant in the lower part inside the casing (51). A refrigerant inlet pipe (54) and a suction pipe (15a) of the compressor body (10) are disposed so as to penetrate the casing (51) of the accumulator (50).

  The casing (51) includes a cylindrical upper container (52) closed at one end and a cylindrical lower container (53) closed at one end, and the upper container (52) and the lower container (53) It is comprised by welding an opening part mutually.

  In the casing (51), a refrigerant inlet pipe (54) is disposed so as to penetrate the upper end portion of the casing (51), and a through hole (56) is provided in the lower end portion. The suction pipe (15a) of the compressor body (10) is inserted into the through hole (56) at the lower end. Note that the end of the inserted suction pipe (15a) extends to the vicinity of the upper part inside the accumulator (50). With this configuration, the storage space (55) capable of storing the liquid refrigerant from the bottom in the casing (51) to the end of the suction pipe (15a) is formed.

  Further, in order for the refrigerant flowing in from the refrigerant inlet pipe (54) to flow into the storage space (55) without directly flowing into the suction pipe (15a), the suction pipe ( A partition plate (57) is provided in the vicinity of the upper side of the end of 15a).

  The accumulator (50) is provided with an accumulator mounting plate (support member) (2) for fixing the accumulator (50) to the compressor body (10). One end of the accumulator mounting plate (2) is welded and fixed to the outer surface of the accumulator (50), and the other end is welded to the substantially spherical curved surface portion of the end plate (12) provided above the compressor body (10). It is fixed.

−Operation of compressor with accumulator−
When electric power is supplied to the compressor motor (30) through the terminal (17) of the compressor body (10), the winding (39) of the stator core (36) is energized, and a rotating magnetic field is applied to the stator (34). Will occur. Due to this rotating magnetic field, a permanent magnet (not shown) of the rotor (35) receives a magnetic force to rotate the rotor (35). The rotation of the rotor (35) causes the drive shaft (31) to rotate, and the rotary piston (25) swings or revolves within the compression chamber (26). Thereby, the gas refrigerant sucked into the compression chamber (26) through the suction pipe (15a) is compressed. When the pressure in the compression chamber (26) reaches a predetermined pressure, the discharge hole opens and high-pressure refrigerant is discharged from the compression chamber (26) into the casing (14). The high-pressure refrigerant in the casing (14) is discharged from the discharge pipe (16).

  Here, when the rotor (35) rotates in response to the rotating magnetic field of the stator (34), the stator (34) exerts a force attracted to or separated from the rotor (35). Vibrate alternately. This vibration is directly propagated to the body part (11) to which the stator (34) is fixed, and the body part (11) vibrates in the same manner as the stator (34). The body (11) also vibrates by driving the compression mechanism (20). The vibration of the body part (11) generated by these is attenuated and propagated to the end plates (12, 13) welded to the opening portions on both sides of the body part (11). Therefore, the vibration of the end plate (12, 13) is lower than the vibration of the body (11).

-Effect of the embodiment-
According to this embodiment, the end plate (12) has a substantially spherical curved surface having a rigidity higher than that of the cylindrical shape, and the accumulator mounting plate (2) is attached to the substantially spherical curved surface portion. Thus, vibration propagating from the above-described excitation source to the accumulator (50) can be suppressed to a low level. This suppresses the increase in operating noise due to the vibration of the accumulator (50), the generation of abnormal noise, the propagation of vibration to the refrigerator equipped with the compressor (1) with the accumulator and the damage to the compressor (1). Can do.

-Modification 1 of embodiment-
In Modification 1 of the embodiment, as shown in FIG. 2, the accumulator mounting plate (2) is provided with a mounting band (2a). With this configuration, for example, even if the accumulator mounting plate (2) is not mounted at an accurate position with respect to the compressor main body (10), the mounting error is reduced to the body (11) and the end plate (12, 13). ) And the mounting band (2a) so that the accumulator mounting plate (2) can be securely fixed to the accumulator (50).

  Further, since the accumulator mounting plate (2) and the accumulator (50) are not fixed by welding, the accumulator mounting plate (2), the accumulator (50), the body (11), and the end plate (12, 13) As a result, the number of options for the assembly process with respect to the assembly order increases, and the degree of freedom in the assembly process increases.

  As described above, the degree of freedom in the assembly process is increased, and the mounting error between the end plate (12, 13) and the accumulator mounting plate (2) is absorbed, and the support member (2) is passed from the excitation source. Thus, vibration propagating to the accumulator (50) can be suppressed to a low level.

-Modification 2 of embodiment-
In the compressor (90) of the second modification of the embodiment, the structure is changed as shown in FIG. 3 with respect to the casing (14) and the compression mechanism (21) of the above embodiment. The casing of Modification 2 has a two-part structure of an upper casing (93) and a lower casing (94). The compression mechanism (93) of the second modification is a so-called two-cylinder type rotary compression mechanism, and has two suction pipes (95). The two suction pipes (95) serve as a suction path for the compressor body in the compressor (90). Even in such a configuration, the compressor motor and the compression mechanism (96) as the vibration source are fixed to the lower casing (94), and the accumulator is fixed to the upper casing (93) to which the vibration source is not fixed. By fixing the plate (92), vibration propagating from the excitation source to the accumulator (91) via the accumulator fixing plate (92) can be suppressed to a low level. Here, in the second modification of the embodiment, the structure of both the casing (14) and the compression mechanism (21) in the above embodiment is changed, but it is not necessary to limit to this, and either The structure which changed only the structure may be sufficient. Further, the casing need not be limited to two divisions, and may be four or more divisions. However, the accumulator mounting plate (2) needs to be mounted on a casing member to which no vibration source is mounted.

<< Other Embodiments >>
About the said embodiment, it is good also as the following structures.

  In the said embodiment, although the said compressor main body (10) was a rotary type compressor which has a rotary piston (25), it is not necessary to limit to a rotary type, For example, a scroll type compressor may be sufficient. .

  In the said embodiment, although the said compressor main body (10) was comprised with the vertical compressor, it is not necessary to limit to a vertical compressor, For example, you may be comprised with the horizontal compressor.

  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 damping technology of the accumulator against the vibration of the compressor body in the compressor with the external accumulator.

It is a longitudinal section of a compressor with an accumulator concerning an embodiment of the present invention. It is a longitudinal cross-sectional view of the compressor with an accumulator which concerns on the modification 1 of embodiment of this invention. It is a longitudinal cross-sectional view of the compressor with an accumulator which concerns on the modification 2 of embodiment of this invention. It is a longitudinal cross-sectional view of the compressor with an accumulator which concerns on a prior art.

1 Compressor with accumulator (compressor)
2 Accumulator mounting plate (support member)
10 Compressor body
11 trunk (first casing member)
12 End plate (second casing member)
15 Suction tube
20 Compression mechanism
30 Compressor motor (electric motor)
50 Accumulator

Claims (3)

A compressor main body (10) and an accumulator (50) attached to the compressor main body (10) via a support member (2). The compressor main body (10) includes a casing (14) and an inner portion thereof. A compression mechanism (20) fixed to the wall and an electric motor (30) for driving the compression mechanism (20),
The casing (14) includes a first casing member (11) to which the compression mechanism (20) and the electric motor (30) are attached and open at both ends or one end, and openings at both ends or one end of the first casing member (11). A compressor comprising a second casing member (12, 13) fixed to an end,
The compression mechanism (20) and the outer surface of the electric motor (30) are fixed to the inner wall of the first casing member (11),
The compressor, wherein the support member (2) is fixed to the second casing member (12, 13). A compressor body (10) and an accumulator (50) attached to the compressor body (10) via a support member (2). The compressor body (10) comprises a casing (14) and an inner wall thereof. A compression mechanism (20) fixed to the motor and an electric motor (30) for driving the compression mechanism (20),
The casing (14) includes a first casing member (11) to which the compression mechanism (20) and the electric motor (30) are attached and open at both ends or one end, and openings at both ends or one end of the first casing member (11). A compressor comprising a second casing member (12, 13) fixed to an end,
A compression mechanism (20) and an electric motor (30) are fixed to the first casing member (11),
The support member (2) is fixed to the second casing member (12, 13),
The second casing member (12, 13) has a spherical or substantially spherical curved surface;
The compressor, wherein the support member (2) is attached to the spherical or substantially spherical curved surface. In claim 1 or 2,
The compressor characterized in that an attachment band (2a) for holding the accumulator (50) is provided at the other end of the support member (2).

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