DE10052895A1 - compressor - Google Patents

Abstract

A head (15), which is provided with an ejection chamber (14) and a suction chamber (13), is formed in a compressor by a combination of different materials with different mechanical strength. More specifically, the head has an outer partition (44) which separates the suction chamber and the ambient air, and an inner partition (45) which forms the discharge chamber. The outer partition wall is made of an aluminum casting material, while the inner partition wall is made of a steel casting material, the mechanical strength of which is higher than that of the aluminum casting material.

Description

This invention relates to a compressor that is adapted for a cooling circuit that uses CO ₂ as a refrigerant, and a cooling circuit that uses the compressor.

In a cooling circuit there is a wide variety of compresses sensors with different constructions. In each Case, each of these compressors has a head that is connected to an ejection chamber for ejecting a coolant and with a suction chamber for sucking the coolant is provided. The head has a structure in which the discharge chamber and the Suction chamber are separated from each other by a partition. To reduce weight, the head is generally called one-piece molded product by molding from an aluminum made of nium material.

Recently, a proposal has been made to use a cooling circuit that uses CO ₂ as a coolant. The cooling circuit of this type is generally referred to as a supercritical cooling circuit. Since the supercritical refrigeration cycle is expected to achieve high cooling performance, the size of the compressor can be reduced. For example, if a piston type compressor is used, the size of the compressor by reducing the diameter of a cylinder bore may by _^1/2 can be reduced.

In the supercritical cooling circuit, this is due to the compressor compressed coolant a higher temperature (+ approx 50 ° C) and a higher pressure (+ about 10 MPa) in comparison to a conventional cooling circuit, the fluorocarbon (flon) used as a coolant. It is therefore necessary the mechanical strength of the partition between the ejection chamber and the suction chamber to increase. However, if the size of the compressor is reduced, it is difficult to control the mecha niche strength of the partition due to a reduced Increase the thickness of the partition. Piston construction for the compressor art is the partition between the discharge chamber and the on Suction chamber formed for example at a point where an opening of the cylinder bore is divided in half. Des half the partition can due to the relationship to one Intake opening and an exhaust opening are not sufficient be thick if the diameter of the cylinder bore is reduced becomes.

It is therefore an object of this invention to provide a compressor to create a head with a discharge chamber and egg ner suction chamber through a combination of several types of material whose mechanical strength is different, thereby reducing the size and weight of the compressor adorn.  

It is another object of this invention to provide a compressor that is adapted to a refrigeration cycle that uses CO ₂ as a refrigerant.

Another object of this invention is to improve a cooling circuit using CO ₂ as a coolant.

This invention is characterized by the features of the independent An sayings solved. Further advantageous embodiments of the Er invention are the subject of the subclaims.

According to the invention, a compressor is provided which has a head has that with an ejection chamber and a suction chamber is provided, characterized in that the head has an up has a partition that separates the suction chamber from the separates the ambient air from a cast aluminum material is posed while another partition that is the ejection separates the chamber from the suction chamber, from a high-strength mate rial is manufactured, whose mechanical strength is higher than is that of the cast aluminum material.

According to this invention, a compressor is also provided, which has a head with an ejection chamber and a Suction chamber is provided, characterized in that the Head has a structure in which a partition wall, which the An Separates suction chamber from the ambient air, made of an aluminum cast material is made, while another partition, that separates the discharge chamber from the ambient air, from one high-strength material is made, the mechanical Fe strength is higher than that of the cast aluminum material.

According to this invention, a compressor is also provided, which has a head with an ejection chamber and a Suction chamber is provided, characterized in that the  Head has a structure in which a partition wall, which the An Separates suction chamber from the ambient air, made of an aluminum cast material is made, while another partition, which forms the discharge chamber, made of a high-strength material is manufactured, whose mechanical strength is higher than that of the cast aluminum material.

According to the invention, a supercritical cooling circuit is also provided, which is characterized in that one of the compressors mentioned above is included and that it uses CO ₂ as the coolant.

Brief description of the drawings

Fig. 1 is a vertical sectional view of a compressor according to a first embodiment of the invention.

Fig. 2 is a vertical sectional view of a compressor GE according to a second embodiment of the invention.

With reference to FIG. 1, a description is given about a compressor according to a first exemplary embodiment according to the invention. The compressor shown is a compressor of the piston type, which is referred to as a variable piston compressor of the swash plate type and is suitable for use in a vehicle air conditioning system.

The compressor shown in Fig. 1 has a cylinder block 12 which has a plurality of cylinder bores 11 (only one is shown in the figure) which are arranged parallel to one another, a cylinder head 15 which is connected to one end of the cylinder block 12 and with an intake chamber 13 and an ejection chamber 14 , a valve plate 16 which is arranged between the cylinder block 12 and the cylinder head 15 , and a plurality of pistons 17 which are inserted in the cylinder bores 11 in a one-to-one correspondence in order to and carry out outgoing movement. The discharge chamber 14 is formed in the center of the cylinder head 15 , while the suction chamber 13 is formed around the discharge chamber 14 . The valve plate 16 has a pair consisting of a suction opening 18 and an exhaust opening 19 for each of the cylinder bores 11th The suction opening 18 is connected to the suction chamber 13 , while the discharge opening 19 is connected to the discharge chamber 14 .

The piston-type compressor also has a front housing 31 which is fixed to the cylinder block 12 at the other end from the one end connected to the cylinder head 15 , a drive shaft 34 which is rotatable in the front housing 31 and the cylinder block 12 is supported by respective radial bearings 32 and 33 in order to carry out a rotary movement, a rotor 36 which is fastened to the drive shaft 34 and faces the front housing 31 by means of a thrust bearing 35 , an inclination-variable swash plate 38 which is provided by a joint mechanism 37 is coupled to the rotor 36 , and a swash plate 41 which is rotatably supported on the swash plate 38 by a bearing 39 . The swash plate 38 is rotated via the joint mechanism 37 with the rotor 36 and the inclination angle with respect to the drive shaft 34 is variable. The swash plate 41 has a peripheral part which is coupled to the piston 17 by a piston rod 42 . A guide 43 is provided to prevent the rotation of the swash plate 41 .

The cylinder head 15 has an outer partition wall 44 with an annular shape, which separates the suction chamber 13 from the ambient air, and an inner partition wall 45 with a cup-shaped shape, which is arranged inside the outer partition wall 44 to form the discharge chamber 14 . The outer uter partition 44 is made of a cast aluminum material. On the other hand, the inner partition wall 45 is made of a high-strength material whose mechanical strength is higher than that of the aluminum casting material, for example, a steel casting material. The outer and inner partitions 44 and 45 are securely attached by a suitable device or measure, such as by thermal expansion, to obtain an integrated structure.

The inner partition 45 has a first wall portion 46 which separates the suction chamber 13 from the discharge chamber 14 , a second wall portion 47 which separates the discharge chamber 14 from the ambient air and a third wall portion 48 which is connected to the outer partition 44 . The first Wandab section 46 is located at a location between the suction opening 18 and the discharge opening 19 , that is, at a location where an opening of the cylinder bore 11 is divided into two halves.

The function of the compressor of the piston type is briefly described below. For example, when the drive shaft 34 is driven by an internal combustion engine of a vehicle to perform a rotary motion, the rotor 36 and the swash plate 38 are rotated. Since the swash plate 41 is prevented from rotating by the guide 43 , the swash plate 41 is not rotated, but in accordance with the inclination of the swash plate 38 for wobbling. As a result, the piston 17 makes a reciprocating movement in the cylinder bore 11 through the piston 42 . Since the stroke or the displacement of the piston 17 is changed accordingly to the change in the angle of inclination of the swash plate 38 , the compression volume is variable.

Following the reciprocating movement of the piston 17 , a coolant is sucked out of the suction chamber 13 through the suction opening 18 into the cylinder bore 11 and is expelled through the discharge opening 19 to the discharge chamber 14 . As a result, the discharge chamber 14 is subjected to a high pressure. However, the inner partition wall 45 , which forms the discharge chamber 14 , is made of a high-strength material and therefore has a high mechanical strength. Therefore, the piston type compressor described above can be used even when the compressed refrigerant has a high temperature and a high pressure, for example, in a supercritical refrigeration cycle that uses CO ₂ as a refrigerant. In addition, the size of the compressor can be reduced by reducing the diameter of the cylinder bore 11 , since the first wall section 46 can be reduced in thickness. As a result, the weight of the compressor can also be reduced.

Referring to FIG. 2, a description of a compressor in accordance with a second example of execution of the invention. The compressor of this embodiment is a piston type compressor, which is often referred to as a variable displacement compressor of the swash plate type or swash plate type compressor and is suitable for use in a vehicle air conditioner. Similar parts are designated by the same reference numerals and will not be described further.

The piston type compressor shown in FIG. 2 has a modified construction of the cylinder head 15 . In the cylinder head 15 , each of the outer and inner partitions 44 and 45 has a cup shape. The inner partition wall 45 is essentially completely encased by the outer partition wall 44 . In other words, the inner partition wall 45 with a cup-shaped shape is arranged in the suction chamber 13 , which is formed by the outer partition wall 45 with a cup-shaped shape. Consequently, most of the inner partition 45 serves to separate the suction chamber 13 and the shock chamber 14 .

Also in the compressor of the piston type of this embodiment, the outer partition 44 is made of an aluminum casting material. On the other hand, the inner partition wall 45 is made of a high-strength material, the mechanical strength of which is higher than that of the aluminum casting material, for example of a steel casting material. In this way, the piston type compressor shown in FIG. 2 has an effect similar to that of the first embodiment shown in FIG. 1.

The weight and size of the compressor can be reduced because the head, which is provided with the discharge chamber and the suction chamber, is made by a combination of different materials with different mechanical strengths. The compressor is adapted to a supercritical cooling circuit that uses CO ₂ as a coolant. Therefore, the supercritical refrigeration cycle can be improved by using the compressor.

While the present invention has been in connection with a few examples has been described it is of course possible for the person skilled in the art to invent this implementation in practice in different ways. At for example, from other different materials like for example stainless steel, titanium and ceramics be made, although the cast steel material as the high strength Material was mentioned. In addition, the present invention  also on different compressors of different construction Types applicable, although the compressor of a certain type has been described above.

In a compressor, a head 15 , which is provided with a discharge chamber 14 and a suction chamber 13 , is formed by a combination of different materials with different mechanical strength. More specifically, the head has an outer partition 44 which separates the suction chamber and the ambient air, and an inner partition 45 which forms the discharge chamber. The outer partition is made of an aluminum casting material, while the inner partition is made of a steel casting material, the mechanical strength is higher than that of the aluminum casting material.

Claims (5)

1. A compressor having a head ( 15 ) which is provided with an exhaust chamber ( 14 ) and a suction chamber ( 13 ), characterized in that the head has a structure in which a partition ( 44 ) which the suction chamber of separating the ambient air is made of an aluminum casting material, while another partition wall ( 46 ) separating the discharge chamber from the suction chamber is made of a high-strength material whose mechanical strength is higher than that of the aluminum casting material. 2. Compressor having a head ( 15 ) which is provided with a discharge chamber ( 14 ) and a suction chamber ( 13 ), characterized in that the head has a structure in which a partition ( 44 ) which the suction chamber of the ambient air separates, is made of an aluminum casting material, while another partition ( 47 ), which separates the discharge chamber from the ambient air, is made of a high-strength material whose mechanical strength is higher than that of the aluminum casting material. 3. Compressor having a head ( 15 ) which is provided with a discharge chamber ( 14 ) and a suction chamber ( 13 ), characterized in that the head has a structure in which a partition ( 44 ) which the suction chamber of the ambient air separates, is made of an aluminum casting material, while another partition ( 45 ), which forms the discharge chamber, is made of a high-strength material whose mechanical strength is higher than that of the aluminum casting material. 4. Compressor according to one of claims 1 to 3, characterized ge indicates that the high-strength material is a cast steel material al is. 5. supercritical cooling circuit, characterized in that a compressor according to one of claims 1 to 4 is included and CO _{2 is used} as the coolant.