EP3167189A1 - Compressor - Google Patents

Abstract

The invention relates to a compressor (10), in particular a compressor for compressing a coolant, comprising one or more pistons (12), a cylinder block (16), and a compressor housing which at least partially houses the compressor (10), the piston(s) (12) being arranged in corresponding cylinder bores or cylinders (14) arranged at least partially in the cylinder block (16) and/or in the compressor housing so that they can move back and forth. The compressor (10) also comprises an impedance tube (36) and an outlet (30) for releasing the coolant from the compressor, (10) in particular an outlet flange (32). Said compressor (10) has an associated high pressure volume (24), for one or more, in particular, for respectively two cylinders (14), and a common high pressure volume (26), in which the individual high pressure volumes (24) join, the common high pressure volume (26) being connected to the outlet (30) and the impedance tube (36) being arranged in the connection between the common high pressure volume (26) and the outlet (30) or the connection is created between the common high pressure volume (26) and the outlet (30). The invention also relates to a corresponding coolant circuit and to a corresponding air-conditioning system.

Description

 compressor

The invention relates to a compressor according to the preamble of patent claim 1, and a refrigeration system according to claim 11, and an air conditioner according to

Claim 12.

Such compressors are widely used in today's life, for example in the field of air conditioning of motor vehicles, such as passenger cars or buses, in the air conditioning of railway cars, in the field of transport refrigeration or stationary applications such as supermarket refrigeration or industrial heat pump use or the like Such compressors, which are generally subject to the principle of reciprocating piston, available in many embodiments, for example as a reciprocating compressor, in which a piston movement usually in a (to a crankshaft axis extending direction, which simultaneously defines the axial direction) radial direction takes place, wherein the pistons are further arranged, as a rule, at least partially spaced apart in the axial direction, as a radial piston compressor, in which the piston movement, ie a suction and a counter-rotating to this compression movement, takes place substantially in the radial direction, the pistons are not spaced apart in the axial direction usually (radial engine geometry) or as axial piston compressor, in which the suction and compression movement in the essential in an axial direction

1

CONFIRMATION COPY he follows.

Due to the cyclical compression of the refrigerant, there are pulsations and noise, especially in the discharge of compressed refrigerant from a cylinder in which the corresponding piston reciprocates.

For damping the pulsations, DE 197 57 829 A1 discloses a damper channel

proposed, via which compacted refrigerant from a cylinder chamber downstream of the pressure chamber into a common high pressure volume all cylinders. The damper channel is usually equipped with a 90 ° bend, but in particular with a 180 ° bend, wherein a part or the entire channel may be formed by a pipe, the so-called impedance tube. The construction of DE 197 57 829 AI is therefore relatively complicated and thus expensive to manufacture.

Based on the above-discussed prior art, it is therefore an object of the present invention to provide a compressor having a pulsation damping at the same time simple construction, and to provide a corresponding refrigeration system and a corresponding air conditioning.

This object is achieved by a compressor according to claim 1 and a refrigeration system according to claim 11, and an air conditioner according to claim 12.

Accordingly, a compressor, in particular a compressor for compressing a refrigerant, has one or more pistons and a cylinder block and / or a compressor housing. The pistons are in corresponding, usually at least partially in

Compressor housing and / or arranged in the cylinder block recesses (cylinder or cylinder bores) back and forth arranged. The compressor further comprises an impedance tube and an outlet for discharging the refrigerant from the compressor, in particular an outlet flange. For one or more, in particular for two cylinders, a high-pressure volume assigned to this or these is arranged in the compressor, into which it discharges compressed refrigerant. The compressor also has a common high-pressure volume into which the individual

High-pressure volumes open, with the common high-pressure volume with the outlet communicates. The impedance tube is arranged in the connection between the common high-pressure volume and the outlet. In one possible embodiment, the connection between the common high-pressure volume and the outlet is formed by the impedance tube.

This represents a simple and inexpensive to implement construction.

Inventive refrigeration systems and / or air conditioning systems have a correspondingly designed compressor.

Further features of the invention are specified in the subclaims.

The invention will now be described by way of example with reference to the accompanying drawings with reference to an embodiment. It shows:

Fig. 1 is a partial view of a possible embodiment of a compressor according to the invention in a sectional view.

In the case of the compressor 10 shown in FIG. 1, the described embodiment is a compressor suitable for compressing a refrigerant,

in particular C0 ₂ , is provided. The compressor 10 has a plurality of pistons 12 (in the figure, only one piston 12 is shown), which in recesses (cylinder bores) 14, which are arranged in a cylinder block 16, arranged back and forth are (indicated by double arrow 18). Described in the present

Embodiment is designed as a reciprocating compressor

Compressor 10, i. a compressor 10, in which a suction and a

Compression movement (reciprocation, as mentioned above by

Double arrow 18) in a radial direction, i. perpendicular to one

Crankshaft axis of the same takes place. Alternatively, for example, an embodiment as an axial piston compressor in which a lifting movement in the axial direction, i.

parallel to the crankshaft axis, conceivable.

By the respective pistons 12, the recesses (cylinder bores) or cylinder 14 and arranged on the cylinder block 16 cover or valve plate 20 is in each case one Cylinder space or compression volume defined. In a suction movement of the piston 12, in which they are moved away from the valve plate 20, sucked via inlet valves 21 to be compressed refrigerant, which then in a counter-aligned compression movement (directed toward the valve plate 20 toward) and compressed by exhaust valves 22 in a the respective cylinder 14 associated high-pressure volume 24 is ejected. In the presently described embodiment, two cylinders 14 each share an associated high pressure volume 24. In the presently described embodiment, the intake valves and the exhaust valves are each configured as a louvered valve, and in alternative embodiments, any suitable valves, such as, for example, ring valves or louvered valves, may be used.

The compressor 10 also has a common high-pressure volume 26, into which the individual high-pressure volumes 24 assigned to the respective cylinder 14 or the respective cylinders 14 open via a channel 28, which in alternative embodiments can also be designed as a simple bore. The common high-pressure volume 26 accommodates the pressurized (compressed) refrigerant, which in the embodiment described here is CO ₂ , of all cylinders 14 or of all individual high-pressure volumes 24 assigned to the respective cylinders 14.

The compressor 10 further includes an outlet 30 for discharging the refrigerant from the compressor having an outlet flange 32. When viewed in a flow direction of the refrigerant during normal operation of the compressor 10, a shut-off valve 34 is arranged upstream of the outlet 30 in order to be able to close the outlet accordingly.

For damping during operation of the compressor 10, in particular during the discharge of compressed refrigerant from the respective cylinder 14, resulting pulsations and also for damping noise caused by the pulsations, the compressor 10 has an impedance tube 36. The impedance tube 36 is in communication between the common high pressure volume 26 and the check valve 34

arranged. In the embodiment described here, the connection between the common high pressure volume 26 and the check valve 34 is even formed by the impedance tube 36. In alternative embodiments, the Impedance tube 36 also extend over only part of the connection between the common high-pressure volume 26 and the check valve 34 and form part of it.

The impedance tube 36 acts by reflection of pulsations or vibrations at the respective pipe ends targeted as a vibration absorber. For this purpose, the impedance tube on a pre and a downstream volume in order to achieve freedom from reaction. The upstream volume is formed by the common high-pressure volume 26. The downstream volume is formed by a volume of the applications of the compressor, ie, for example, a refrigeration system or an air conditioning system (for example, by its input volume). For connection to the downstream volume, the outlet flange 32 is provided on the compressor. In other words, the compressor is designed for connection to a downstream of the impedance tube 36 volume.

In the idea of the present invention are also a refrigeration system and a

Contain air conditioning, which have a compressor according to the invention. The compressor downstream volume is formed in the corresponding refrigeration system or air conditioning. In other words, the present disclosure also includes a refrigeration system, in particular transport refrigeration system or stationary refrigeration system, which has a compressor 10 and a volume which is connected to the outlet 30 of the compressor. Further included in the spirit of the present disclosure is an air conditioner, particularly stationary air conditioner or mobile air conditioner, comprising a compressor 10 and a volume connected to the outlet 30 of the compressor.

The impedance tube 36 has a constant cross-section, wherein in alternative embodiments, variations in the cross section, in particular gradations or

step-like extensions and / or constrictions are conceivable. The concrete one

Design depends in particular on those prevailing in the compressor 10

Flow conditions.

The compressor 10 has a compressor housing 38. The impedance tube 36 is on

Compressor housing 38 is fixed, wherein it is for attachment to the same a thread for Screw connection with the compressor housing 38 has. The impedance tube 36 is completely hermetized in the presently described embodiment

Integrated refrigerant circuit of the compressor 10, whereby a use of seals can be omitted. It is therefore a sealless integration of the impedance tube 36 in the compressor 10. In alternative embodiments, it is also conceivable to arrange the impedance tube with a seal in the compressor, in other words, in addition, a sealed variant is also conceivable, which also possibly in a compressor can be retrofitted.

The impedance tube 36 extends in the present embodiment of the common high pressure volume 26 up to the outlet 30 upstream

Shut-off device (shut-off valve 34). In embodiments in which a

Shut-off can be dispensed with, the in the pedestrian tube may extend to the outlet 30. The impedance tube 36 has no bending or bending in the present embodiment, in other words, the impedance tube 36 is arranged as a straight tube at a corresponding location.

Optionally, the length of the impedance tube 36 is tuned so that the incoming vibration waves are selectively freed from their Oberwel len (in the pedestal length I = λ / 4 or parts thereof), is repaid I (= the wavelength Wel the incoming Wel le and thus the incoming wave) or multiples of it (harmonics). With this arrangement, pulsations can be reduced to 10-20% with low loss. The following relation applies here: c / f (= wavelength, f = frequency and c = speed of sound).

However, while the invention will be described in terms of embodiments having fixed feature combinations, it also encompasses the other conceivable advantageous ones

Combinations as specified in particular, but not exhaustive, by the subclaims. All disclosed in the application documents features are claimed as essential to the invention, as far as they are new individually or in combination over the prior art.

LIST OF REFERENCE NUMBERS

 10 compressors

12 pistons 14 cylinder bore or cylinder

16 cylinder block

 18 double-headed arrow

 20 valve plate

 21 inlet valve

 22 exhaust valve

 24 high pressure volumes

 26 common high-pressure volume

28 channel

 30 outlet

 32 outlet flange

 34 shut-off valve

 36 impedance tube

 38 compressor housing

Claims

claims

Compressor (10), in particular compressor for compressing a refrigerant, with one or more pistons (12), and a cylinder block (16), and a compressor housing (10) at least partially einhausenden compressor housing, the / the piston (12) in corresponding At least partially in the cylinder block (16) and / or in the compressor housing arranged cylinder bores or cylinders (14) is arranged reciprocating / is, wherein the compressor (10) further comprises an impedance tube (36) and an outlet (30) for discharging the Refrigerant from the compressor, (10) in particular an outlet flange (32),

characterized in that

the compressor (10) for one or more, in particular for each two cylinders (14) an associated high pressure volume (24), and a common high pressure volume (26) into which the individual high pressure volumes (24) open, wherein the common high pressure volume ( 26) communicates with the outlet (30) and that the

Impedance tube (36) in the connection between the common high-pressure volume (26) and the outlet (30) is arranged or forms the connection between the common high-pressure volume (26) and the outlet (30).

Compressor (10) according to claim 1,

characterized in that

the impedance tube (36) extends directly to the outlet (30) or to a shut-off device upstream of the outlet (30), in particular valve (34).

3. compressor (10) according to any one of the preceding claims,

 characterized in that

 the compressor (10) has a compressor housing (38), wherein the impedance tube (36) has a thread for screwing to the compressor housing (38).

4. compressor (10) according to any one of the preceding claims,

 characterized in that

 the individual high-pressure volumes (24) assigned to the respective cylinder are each connected via a channel (28) or a bore to the common high-pressure volume (26).

5. compressor (10) according to any one of the preceding claims,

 characterized in that

the compressor (10) is provided for compressing C0 ₂ as refrigerant or that the refrigerant to be compressed C0 is ₂

6. compressor (10) according to any one of the preceding claims,

 characterized in that

 the impedance tube (36) has a constant cross-section.

7. compressor (10) according to claim 5 or 6,

 characterized in that

 the individual high pressure volumes (24) are merged into the common high pressure volume (26).

8. compressor (10) according to any one of the preceding claims,

 characterized in that

 the compressor (10) has a volume upstream of the impedance tube (36).

9. compressor (10) according to any one of the preceding claims,

 characterized in that

the compressor (10) is designed for connection or connection to a volume connected downstream of the impedance pipe (36), in particular through an outlet flange (32).

10. compressor (10) according to any one of the preceding claims,

 characterized in that

 the impedance tube (36) has a length (I) which corresponds to a quarter of the wavelength (λ) of the pulsation or harmonic to be reduced or which corresponds to a part of the aforementioned dimensions (I = λ / 4η, where n is a positive integer, in other words a number from the set of natural numbers).

11. refrigeration system, in particular transport refrigeration system or stationary refrigeration system, comprising a compressor (10) according to one of the preceding claims and a volume which is connected to the outlet (30) of the compressor.

An air conditioning system, in particular a stationary air conditioning system or a mobile air conditioning system, comprising a compressor (10) according to any one of the preceding claims and a volume connected to the outlet (30) of the compressor.