DE102010051265B4 - Refrigerant compressor - Google Patents

Abstract

Refrigeration compressor (1) with an electric motor (3) having a stator (5) and a rotor (4), and with a compressor unit (2) arranged on a carrier (13) having a carrier element (14) and an annular base member (15), wherein the rotor (4) is formed as an external rotor which radially surrounds the stator (5), characterized in that the base member (15) the motor (3) over most of its circumference and covers most of its axial extent.

Description

The invention relates to a hermetically sealed refrigerant compressor with an electric motor having a stator and a rotor, and having a compressor unit which is arranged on a carrier which has a carrier element and an annular base element, wherein the rotor is designed as an external rotor radially surrounding the stator.

Such a compressor is for example off DE 18 52 038 U known. The local small refrigerating machine comprises an electric motor with a stator and a rotor constructed as an external rotor. A support plate is connected to both the stator and a compressor cylinder. The compressor is operated via a common shaft of electric motor and compressor. Electric motor and compressor are suspended together by springs in a hermetically sealed capsule. In order to achieve a smooth running of the refrigerant compressor, counterweights are provided on the radial outer side of the rotor.

US 6 095 768 A shows a refrigerant compressor with an electric motor comprising a stator and a rotor. The rotor is provided as an internal rotor, which is arranged directly on a shaft. The stator is connected at its radial outside with a housing, which is preferably formed by deep drawing of a piece of sheet metal.

In US 3 465 954 A a refrigerant compressor with an electric motor and a compressor unit is disclosed. The electric motor comprises a stator and a rotor constructed as an internal rotor. The rotor is connected via a shaft to the compressor unit. Between the electric motor and the compressor unit, a disc-shaped carrier is arranged.

Another compressor is for example off DE 10 2008 024 671 A1 known. There is a compressor unit mounted on a support member which is connected to a base member which is mounted on an upper end side of the stator. The base member and the support member are formed as sheet metal parts, wherein the support member has a greater thickness than the base member.

Such a refrigerant compressor can be manufactured with a relatively small mass. However, it runs at low speeds relatively restless and causes annoying, acoustic noise by hitting the compressor unit to the capsule of the compressor.

Refrigerant compressors are used, for example, in refrigerators such as refrigerators or freezers. In addition to a low overall height of the refrigerant compressor while a low energy consumption is desired. Better insulation materials of the refrigeration units make it possible to reduce energy consumption by lowering the speed of rotation of the refrigerant compressor. At low rotational speeds, however, known refrigerant compressors frequently run restlessly.

The invention is based on the object of specifying a refrigerant compressor with a low overall height, which is smooth running even at low rotational speeds.

According to the invention this object is achieved in a refrigerant compressor of the type mentioned above in that the base member covers the motor over most of its circumference and most of its axial extent.

As a result, the engine is partially received within the carrier. As a result, a height in the axial direction can be minimized. At the same time, sufficient space is available for the base element radially outside the motor so that it can be manufactured with a relatively large amount of material and thus with a relatively large mass. Due to the large mass of the base element, vibrations of the refrigerant compressor during operation are reduced, but on the other hand, a resonance range is shifted, so that no resonance vibrations of the refrigerant compressor occur at low rotational speeds. The radially outer mass of the base element, which is arranged radially outside the motor, results in a significant increase in the mass inertia, which dampens rotational oscillations occurring when the refrigerant compressor starts and stops. A striking of the compressor unit to the capsule or the housing of the compressor is thereby reliably prevented. In addition, the rotor is designed as an external rotor. As a result, the engine can be produced with the same power with a lower height. In this case, the rotor may have circular-segment-shaped permanent magnets. Due to the external rotor, these are relatively easy to install.

It is particularly preferred that the base element is designed as a cast element and the carrier element as a sheet metal part. The sheet metal part can then be manufactured with a relatively low mass and low material thickness and still have sufficient strength. By manufacturing the base element of a cast element, the base element can be produced inexpensively, wherein a relatively free shaping is possible.

Advantageously, the carrier part is arranged substantially radially inside the base element. The annular base member encloses a space in which the motor is arranged. This free space is now covered by the carrier part arranged radially inside the base element. However, the support member may also additionally radially cover the base member, which may be advantageous, for example, for easy attachment. The compressor unit is fastened to the carrier element, wherein the base element is arranged on the motor-facing side of the carrier element.

Preferably, the carrier element is axially supported on at least one support point, preferably at three support points on the stator. Both the motor and the compressor unit are thus applied to the support element. By the support point, lateral forces occurring in particular during the compression stroke can be absorbed, so that displacements or bending loads of the carrier element or of a radial bearing arranged therein are reduced. Also increases by the contact between the stator and the carrier element, the rigidity of the refrigerant compressor, resulting in a reduction of vibration. Overall, this results in a smooth running of the refrigerant compressor. The base element, which covers the motor in the circumferential direction and in the axial direction for the most part, can be designed such that it has no points of contact with the motor. It can therefore be manufactured with relatively high tolerances.

The base element preferably has receptacles for support elements on its side facing away from the compressor unit. Such support elements are for example spring elements which are arranged on a bottom of the compressor capsule or the housing of the refrigerant compressor. The recordings may be formed, for example, as depressions and receive end portions of the support elements. As a result, the compressor unit with the engine can be stored elastically in the capsule.

Preferably, a radial bearing for a shaft connected to the rotor is connected to the carrier element, in particular pressed into an opening of the carrier element. This radial bearing, which for example has a bearing bush, is arranged within an opening in the stator, which is also fastened to the radial bearing. About the radial bearing then the controller is attached to the support element. In this case, an additional thrust bearing may be provided for the rotor, which defines an axial position of the rotor relative to the stator. By compressing the radial bearing or the bearing bush with the carrier element results in a cost-effective production.

Preferably, the compressor unit has a cylinder and a piston guided therein, a valve system and a pressure silencer and can be fastened in particular as a structural unit on the carrier. This results in a relatively simple installation of the refrigerant compressor.

It is particularly preferred that the shaft has an eccentric crank pin at one end, which is connected via a connecting rod with the piston. Such a configuration allows a relatively simple implementation of the rotational movement of the shaft in a linear movement of the piston.

Preferably, the carrier element and the base element are connected to each other via a three-point connection. Between the support member and the base member so three connection points or contact points are formed. The base member can thus be kept stable and stress-free on the support element.

• 1 einen Querschnitt durch einen Kältemittelverdichter und
• 2 einen Träger in räumlicher Darstellung.

The invention will be described below with reference to a preferred embodiment in conjunction with the drawings. Herein show:

• 1 a cross section through a refrigerant compressor and
• 2 a carrier in spatial representation.

In 1 is a refrigerant compressor 1 shown in a sectional view. The refrigerant compressor 1 has a compressor unit 2 and an electric motor 3 on. The compressor unit 2 and the engine 3 are housed in a hermetically sealed housing, which is not shown.

The motor 3 has a rotor 4 and a stator 5 on. The rotor 4 is designed as an external rotor, which is the stator 5 radially surrounds. The rotor 4 has permanent magnets 6 on, radially from a shorting ring 7 are surrounded. About a bottom part 8th is the rotor 4 with a wave 9 rotatably connected, extending through a central opening in the stator 5 extends. Here is the wave 9 in a bushing 10 held a radial bearing. The stator 5 is on the bearing bush 10 established.

Inside the wave 9 is a displacement element 11 arranged, between the displacement element 11 and the hollow shaft 9 an oil transport path is formed. Inside the wave 9 is a thrust bearing 12 formed, with which the axial position of the rotor 4 is determined.

The compressor unit 2 and the engine 3 are about a carrier 13 connected to each other, which is a carrier element 14 and an annular base member 15 having. The basic element 15 surrounds the engine 3 over most of its scope. In addition, the base element covers 15 the motor over most of its axial extent, ie in the direction of the axis of rotation of the shaft 9 or the rotor 4 , The motor 3 is thus largely within the carrier, so to speak 13 or the base element 15 added.

The carrier element 14 covers a free space from the base element 15 is enclosed and in which the engine 3 is arranged. The carrier element 14 is thus arranged substantially radially within the base member and preferably at three contact points fixed to the base member 15 connected. One of the points 31 that is in the range of a cylinder unit 2 is located in 1 shown. The basic element 15 stiffens the carrier element 14 and prevents its deformation by forces occurring during operation. The bearing bush 10 and thus the corresponding radial bearing is via a press fit on the support element 14 connected. This represents a relatively simple connection option. It is also possible, the bushing 10 with the carrier element 14 to glue or to weld.

About a base 17 is the carrier element 14 in the area of the piston-cylinder unit 18 at the stator 5 supported. Both the engine 3 as well as the compressor unit 2 So lie on the support element 14 on while the base element 15 only with the carrier element 14 is connected and otherwise arranged freely.

The piston-cylinder unit 18 has a cylinder 19 and a linearly displaceable piston therein 20 on. The piston 20 is via a connecting rod 21 and a crankpin 22 driven, eccentric with the shaft 9 connected is.

The basic element 15 is designed as a casting, so it can be made relatively inexpensive in the desired shape. The carrier element 14 is designed as a sheet metal part. The basic element 15 thus has a much larger mass than the carrier element 14 on. As a result, a relatively large mass and thus a large mass inertia are formed radially outward. The central part of the refrigerant compressor 1 with the carrier element 14 on the other hand is relatively easily formed and allows a low overall height, with the formation of the support element 14 as a sheet metal part and by a three-point connection 31 with the base element 15 the carrier element 14 even with low material thickness can be mechanically stable enough to accommodate the forces occurring during operation can. The mass inertia is essentially by the base element 15 certainly.

In 2 is the carrier 13 with the carrier element 14 and the base element 15 shown in a spatial representation. The bearing bush 10 the radial bearing is in a central opening of the support element 14 pressed in and extends in the axial direction. The basic element 15 is annular and surrounds a free space, which passes through the support element 14 is covered. In this case, the support element 14 substantially radially within the base member 15 arranged. The carrier element 14 lies on an upper side of the base element 15 on that in 2 not visible and that of the compressor unit 2 is facing. In the fully assembled state of the refrigerant compressor 1 is the basic element 15 So below the support element 14 arranged.

At a bottom 23 of the base element 15 coming from the compressor unit 2 facing away, has the base element 15 Recordings 24 . 25 . 26 . 27 on, which serve to receive support elements, with which the base element 15 axially in a capsule or a housing of the refrigerant compressor 1 can be arranged. The support elements may be formed as coil springs. About the carrier 13 or the base element 15 is then also the compressor unit 2 and the engine 3 spring-mounted. The basic element 15 , the motor 3 and the compressor unit 2 are each on the support element 14 attached.

The carrier element 14 has three projections on its underside 28 . 29 . 30 on, which serve to form support points, with which the support element 14 axially on the stator 5 of the motor 3 is supported. About these bases lateral forces can be transmitted, in particular during the compression stroke of the piston-cylinder unit 18 occur and the bearing bush 10 would claim on bending. By the bases so a load of the radial bearing is reduced.

The formation of exactly three projections or support points results in a defined contact of the support element 14 at the stator 5 , The support points should be arranged in the radial direction as possible at the edge of the stator and are in the range of a laminated core of the stator.

At least one base 17 should be below the piston-cylinder unit 18 be arranged. This results in a good stiffening, so that tilting of the crank pin of the shaft 9 by tilting the bearing bush 10 is prevented.

The arrangement of the base member around the engine, wherein the engine is arranged, so to speak, within a free space of the base member, results in a reduced overall height of the refrigerant compressor, wherein at the same time results in a high mass inertia by the radially relatively far outward mass of the base member. The carrier element which connects the compressor unit to the motor can be made relatively thin, since it does not have to contribute to the mass inertia. Accordingly, the overall height of the carrier element and thus of the entire refrigerant compressor is minimized. Due to the external inertia at the same time ensures that even at low rotational speeds and when switching on and off a smooth running of the refrigerant compressor is achieved.

Claims (9)

Refrigeration compressor (1) with an electric motor (3) having a stator (5) and a rotor (4), and with a compressor unit (2) arranged on a carrier (13) having a carrier element (14) and an annular base member (15), wherein the rotor (4) is formed as an external rotor which radially surrounds the stator (5), characterized in that the base member (15) the motor (3) over most of its circumference and covers most of its axial extent. Refrigerant compressor (1) after Claim 1 , characterized in that the base element (15) is designed as a cast element and the carrier element (14) as a sheet metal part. Refrigerant compressor (1) after Claim 1 or 2 , characterized in that the carrier element (14) is arranged substantially radially inside the base element (15). Refrigerant compressor (1) according to one of Claims 1 to 3 , characterized in that the carrier element (14) is supported axially on at least one support point (17), preferably on three support points, on the stator (5). Refrigerant compressor (1) according to one of Claims 1 to 4 , characterized in that the base element (15) on a side facing away from the compressor unit (2) side (23) receiving (24, 25, 26, 27) for supporting elements. Refrigerant compressor (1) according to one of Claims 1 to 5 , characterized in that a radial bearing (10) for a shaft (9) connected to the rotor (4) is connected to the carrier element (14), in particular in an opening of the carrier element (14) is pressed. Refrigerant compressor (1) according to one of Claims 1 to 6 , characterized in that the compressor unit (2) has a cylinder (19) and a piston guided therein (20), a valve system and a pressure silencer and in particular as a structural unit on the carrier (13) can be fastened. Refrigerant compressor (1) according to one of Claims 1 to 7 , characterized in that the shaft (9) at one end an eccentric crank pin (22) which is connected via a connecting rod (21) with the piston (20). Refrigerant compressor (1) according to one of Claims 1 to 8th , characterized in that the carrier element (14) and the base element (15) via a three-point connection (31) are interconnected.

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