DE202012100995U1 - compressor device - Google Patents

Abstract

Compressor device comprising a compressor device (6; 90; 100) in which a working medium is periodically compressed by a reciprocating compressor element (12; 92; 112) and a drive device (8) which is mechanically or magnetically connected to the compressor element (8). 12, 92, 112) is coupled.

Description

The invention relates to a compressor device and a cooling device equipped therewith and a refrigeration machine equipped therewith.

For cooling of magnetic resonance tomographs, cryopumps, etc., pulse tube coolers or Gifford-McMahon coolers are used. Gas and especially helium compressors are used in combination with rotary or rotary valves as they are used in 11 is shown. A helium compressor 130 is via a high pressure line 132 and a low pressure line 134 with a rotary valve 136 connected. On the output side, the rotary valve 136 via a gas line 138 with a cooling device 110 connected in the form of a Gifford-McMahon cooler or a pulse tube refrigerator. It is about the rotary valve 136 alternately the high and low pressure side of the gas compressor 130 connected to the pulse tube cooler or the Gifford-McMahon cooler. The rate with the compressed helium into the cooler 138 introduced and re-runs is in the range of 1 Hz. A disadvantage of such cooling or compressor systems is that the motor-driven rotary valve 136 Losses of about 50% of the input power of the compressor caused.

There are also known acoustic compressors or high-frequency compressors in which one or more pistons are caused by a magnetic field in linear resonant vibrations. These resonant frequencies are in the range of a few 10 Hz and are therefore not suitable for use with pulse tube coolers and Gifford-McMahon coolers to produce very low temperatures in the lower than 10 K range.

It is therefore an object of the invention to provide a comparison with the combination of gas compressor and rotary valve more efficient compressor device. It is another object of the invention to provide a cooling device and a refrigerator with such a compressor device.

The solution of these objects is achieved by the features of claim 1, 24 and 27, respectively.

Due to the advantageous embodiment of the invention according to claim 2 with a working fluid reservoir, it is possible that the compressor element must perform the compression work only in one direction of movement. Also can thus stabilize the working pressure range of the compressor. The reduction in volume of the working medium by cooling in the thus operated cooling device can thus be compensated.

For this purpose, the compressor device is preferably divided by the compressor element into a first and a second gas volume. The working medium expansion tank is connected via an open in the direction of the first gas volume check valve with the first gas volume - claim 3 - and directly via a gas line with the second gas volume - claim 4 -.

Alternatively to claim 4, according to claim 5, a fluid expansion tank are provided, which is connected via a fluid line directly to the second gas volume. The balancing fluid in the fluid reservoir is not the working fluid but another gas or fluid. For example, for this purpose, an oil, in particular hydraulic oil can be used.

According to an advantageous embodiment of the invention according to claim 10, the drive means may be mechanically or magnetically coupled to a plurality of compressor means. This leads to a reduction in costs, since only one drive device is necessary.

Due to the advantageous hette embodiment of the invention according to claim 11 leaks are reduced.

By combining a compressor device in which a working fluid is periodically compressed and re-expanded by a compressor element with an electro-hydrostatic drive device mechanically coupled to the compressor element according to claim 17, the compressed gas may be in the required frequency range for Gifford-McMahon coolers and pulse tube coolers are provided. The coupling between electrohydrostatic drive device and compressor element via a mechanical or a magnetic coupling. The use of high loss rotary valves is therefore unnecessary. By combining the ease of actuation of an electric motor and the power of hydraulics, it is possible to build an extremely efficient compressor which, due to the lack of a rotary valve when used with Gifford-McMahon coolers or pulse tube coolers, results in a significant reduction in losses. Therefore, a very efficient compressor device is provided.

A particularly suitable electrohydrostatic drive device according to claim 18 comprises a hydraulic cylinder in which a hydraulic piston is arranged linearly movable. The hydraulic cylinder is acted upon by hydraulic fluid, which is supplied or removed via an electrically driven hydraulic pump. The hydraulic piston of the hydraulic cylinder is mechanically, for. B. via a rigid rod, or magnetically coupled to the compressor element of the compressor device.

As a compressor element, both a membrane - claim 21 - or a piston - claims 15 and 16 - are used. Preferably, a linearly movable piston or a linear piston compressor is used due to the simple construction - claim 16. The advantage of a membrane as a compressor element is that no piston running surface must be sealed. Preferably, the membrane is made of metal, as a result, the helium tightness can be ensured - claim 22.

According to an advantageous embodiment of the invention, the direction of movement of the hydraulic cylinder is controlled by the direction of rotation of the electric motor - claim 19.

An electrohydrostatic drive device suitable for the present invention is known, for example, from US Pat DE 10 2008 025 045 B4 known.

By means of the electrohydrostatic drive device, any desired movement, pressure and gas exchange frequency pattern can be transmitted to the compressor device via the hydraulic cylinder. The gas exchange frequency can be adjusted independently of any resonance frequencies. In this way, the performance of a cooler to be operated with such a compressor device can be optimized and vibrations minimized. Claims 6 and 7.

Due to the electrically operated hydraulic pump, a simple electronic control device, the compression of the working fluid in the compressor device can be made according to any pattern, both in terms of time and the amount of pressure - claim. 7

The compressor device can be designed both as a conveying compressor device - claim 14, if it is used, for example, to drive a conventional chiller, or only compress a certain volume of gas and relax repeatedly. The latter is z. B. when operating the aforementioned Gifford McMahon coolers and pulse tube coolers needed.

The advantageous embodiment of the invention according to claim 20 provides a cost-effective compressor device, since the coupling rod between the drive device and compressor device itself is designed as a compressor or displacer; a specially designed compressor element, which is connected to the coupling rod, is therefore unnecessary. Here, the compressor cylinder is designed so that its cross-section is only slightly larger than the cross section of the coupling rod. The distance between the coupling rod and the inside of the compressor cylinder is as small as possible, but no sealing between the coupling rod and the inside of the compression cylinder must be done. The sealing and the inclusion of the working medium takes place through the O-ring or the implementation of the coupling rod in the compressor cylinder. The smaller the distance between the coupling rod and the inside of the compressor cylinder and the greater the stroke of the coupling rod in the compressor cylinder, the lower the dead volume in the compressor device and the more efficient the compressor device.

The remaining subclaims relate to further advantageous embodiments of the invention. Further details, features and advantages of the invention will become apparent from the following description of various embodiments.

It shows:

1 a schematic representation of the invention in a first embodiment in combination with a cooling device,

2 A second embodiment of the invention in combination with a conventional refrigerator,

3 A third embodiment of the compressor device according to the invention,

4 A fourth embodiment of the compressor device according to the invention,

5 A fifth embodiment of the compressor device,

6 A sixth embodiment of the compressor device,

7 A seventh embodiment of the compressor device,

8th an eighth embodiment of the compressor device,

9 a ninth embodiment of the compressor device,

10 a tenth embodiment of the compressor device, and

11 a schematic representation of a helium compressor device with rotary valve and a cooling device according to the prior art.

In the explanation of the various embodiments, the same or corresponding components are given the same reference numerals.

1 shows a first embodiment of the present invention with a compressor device 2 that with a cooling device 4 is coupled. The compressor device 2 in turn comprises a compressor device 6 produced by an electro-hydrostatic drive device 8th is driven. The compressor device 6 includes a gas-tight compressor cylinder 10 in which a compressor element 12 In the form of a piston is arranged linearly movable. The piston 12 divides the compressor cylinder into a first and a second gas volume 14 . 16 , By the movement of the piston 12 becomes the first gas volume 14 with a working gas, z. B. helium, periodically compressed and relaxed again. A coupling rod 18 with a first and a second end 20 . 22 is through her first end with the piston 12 connected. The coupling rod 18 is through a sealed implementation 24 from the second gas volume 16 of the compressor cylinder 10 led out, leaving the second end 22 the coupling rod 18 outside the second gas volume 16 lies. A working fluid expansion tank 25 is via a first gas line 26 directly with the second gas volume 16 and a second gas line 27 with a check valve 28 with the first gas volume 14 connected. The check valve 28 is in the direction of the first gas volume 14 open. Through the working medium expansion tank 25 can that be in the second gas volume 16 located working fluid during the return movement of the piston 12 in the working medium expansion tank 25 stream. Compressor work must therefore only during the forward movement of the piston 12 and in the compression of the in the first gas volume 14 be made working medium.

The drive of the compressor device 6 takes place by the electro-hydrostatic drive device 8th , The electrohydrostatic drive device 8th includes an electric motor 30 that is a hydraulic pump 32 drives. The hydraulic pump 32 pumps hydraulic fluid via a first hydraulic line 34 in a hydraulic cylinder 36 in which a hydraulic piston 38 is arranged linearly movable. The hydraulic piston 38 divides the hydraulic cylinder 36 into a first and a second partial volume 40 . 42 , The first hydraulic line 34 flows into the first partial volume 40 and from the second subvolume 42 branches a second hydraulic line 44 off, back to the hydraulic pump 32 leads. By appropriate control of the electric motor 30 and thus the hydraulic pump 32 becomes the hydraulic piston 38 in the hydraulic cylinder 36 moved back and forth. The hydraulic piston 38 is with the second end 22 the coupling rod 18 connected via a liquid-tight passage 46 in the second subvolume 42 protrudes. This is the movement of the hydraulic piston 38 on the piston 12 transferred, so that the gaseous working fluid in the first gas volume 14 of the compressor cylinder 10 by the movement of the hydraulic piston 38 and the coupled therewith movement of the compressor piston 12 is compressed periodically. Also can thus be the working pressure range of the compressor device 6 stabilize. The volume reduction of the working medium by cooling in the cooling device operated therewith 4 can be compensated.

The first gas volume 14 the compressor device 6 is over a gas pipe 48 with the cooling device 4 connected. The cooling device 4 Here is a cooling device that uses periodically compressed gas for their operation. In particular, the cooling device is for a Gifford-McMahon cooler or a pulse tube refrigerator. In the embodiment of the invention according to 1 Therefore, a fixed amount of gas is periodically in the first gas volume 14 compacted and relaxed again.

2 shows a second embodiment of the invention in which the compressor device 2 as a working medium promoting compressor device is formed and thus a thermodynamic cycle 50 a heat pump or chiller drives. The first gas volume 14 in the compressor cylinder 10 is over the gas line 48 with a capacitor 52 connected. In the condenser 52 the gaseous working medium is condensed with the release of heat. The liquid working medium is via a throttle 54 an evaporator 56 fed. The liquid working medium is in the evaporator 56 is vaporized by absorbing heat and the gaseous working medium is via a gas line 58 again the first gas volume 14 in the compressor cylinder 10 fed. The gas exchange into and out of the first gas volume is via a valve control device 60 controlled.

The following are based on the 3 to 7 various embodiments and variants of the compressor device 2 explained.

3 shows a third embodiment of the invention with a compressor device 70 that differ from the compressor device 2 according to the first embodiment only differs in that the hydraulic cylinder 36 as well as the coupling rod 18 between the hydraulic piston 38 and the compressor element 12 in a common gastight envelope 72 are arranged. Here is the implementation 24 the coupling rod 18 from the second gas volume 16 and the implementation 46 in the first partial volume 40 of the hydraulic cylinder 36 within the gastight envelope 72 arranged. This will prevent that gaseous working medium from the first gas volume 14 over the second gas volume 16 and the implementation 24 can escape. This is particularly important when helium is used as the working medium since helium is very expensive. The gas-tight envelope 72 also defines the working fluid expansion tank 25 ,

4 shows a fourth embodiment of the invention - compressor device 75 - which also reduces the problem of helium leakage. The embodiment according to 4 differs from the embodiment according to 3 in that the gas-tight envelope 72 on the area between the drive device 8th and compressor device 6 is restricted. The coupling rod 18 , the liquid-tight implementation 46 and the gas-tight execution 24 are inside the gas tight envelope 72 arranged. Because of the gas-tight envelope 72 enclosed gas volume is comparatively small, is in the embodiment according to 4 a separate working fluid expansion tank 25 intended.

5 shows a fifth embodiment of the invention, which also reduces the problem of helium leakage. 5 shows a compressor device 80 in which the hydraulic cylinder 36 directly with the compressor cylinder 10 the compressor device 6 connected is. The junction of hydraulic cylinders 36 and compressor cylinder 10 is with an O-ring 82 designed gas-tight. In this way, the rigid mechanical connection between hydraulic piston 38 and compressor element 12 - coupling rod 18 - Also enclosed within a gas-tight envelope.

6 shows a sixth embodiment of the invention. Also with compressor device 84 According to the sixth embodiment of the invention, the hydraulic cylinder 36 directly with the compressor cylinder 10 connected and the junction of hydraulic cylinders 36 and compressor cylinder 10 is with an O-ring 82 designed gas-tight. In contrast to the fifth embodiment of the invention according to 5 in the sixth embodiment, that is in the compressor cylinder 10 protruding end of the coupling rod 18 designed as a compressor element; a separate compressor element is therefore unnecessary. The compressor cylinders 10 defines only a first gas volume 14 , which is periodically reduced and enlarged again. The working medium expansion tank 25 is over the gas line 27 with check valve 28 with this gas volume 14 connected. The cross section or the inner diameter of the compressor cylinder 10 is only slightly larger than the cross-section or outer diameter of the coupling rod 18 , The distance between coupling rod 18 and inside of the compressor cylinder 10 is as small as possible, but no seal between the coupling rod 18 and the inside of the compression cylinder 10 respectively. The sealing and the inclusion of the working medium takes place through the O-ring 82 in the implementation of the coupling rod 18 in the compressor cylinder 10 , The smaller the distance between the coupling rod 18 and inside of the compressor cylinder 10 and the larger the stroke of the coupling rod 18 in the compressor cylinder 10 the lower the dead volume in the compressor device 6 and the more efficient the compressor device 6 ,

7 shows a compressor device 90 a seventh embodiment of the invention, wherein the compressor device 90 is arranged separately from the drive device. That in the compressor cylinder 10 protruding end of the coupling rod 18 is of a gas-tight bellows 92 surrounded, which together with the in the compressor cylinder 10 protruding end of the coupling rod 18 the compressor element of the compressor device 90 forms. The bellows 92 is gas-tight with the inside of the compressor cylinder 10 connected. In this way, the implementation must be 24 for the coupling rod 18 in the compressor cylinder 10 not gas-tight. The sealing of the gas volume to be compressed 14 takes place through the bellows 92 , If, however, the implementation 24 gas-tight, the volume must be 96 inside the bellows 92 via a gas line 94 directly with another fluid expansion tank 98 get connected. That in the fluid reservoir 98 Balancing fluid is not the working fluid, but another gas or liquid. For example, for this purpose, an oil, in particular hydraulic oil can be used.

8th shows a compressor device 100 an eighth embodiment of the invention. The compressor device 100 differs from the compressor device 90 only by the fact that at the end of the coupling rod 10 again a compressor element in the form of a piston 12 is arranged and the bellows 92 with the compressor element 12 connected is. The piston 12 divides the compressor cylinder 10 in the first and second gas volumes 14 . 16 and the working fluid balance box 25 is over a gas pipe 26 directly with the second gas volume 16 and over the gas line 27 with check valve 28 with the first gas volume 14 connected. Again this has to be done through the bellows 92 enclosed gas volume 96 with a surge tank 98 be connected when performing 24 is designed gas-tight.

9 shows a compressor device 110 a ninth embodiment of the invention. The compressor device 110 differs from the compressor device 6 according to 1 in that the compressor element not as a piston, but as metal diaphragm 112 is designed. The end of the coupling rod 18 is centered with the membrane 112 connected. The membrane 112 divides the compressor cylinder 10 in the first and second gas volumes 14 . 16 and the working fluid balance box 25 is over a gas pipe 26 directly with the second gas volume 16 and over the gas line 27 with check valve 28 with the first gas volume 14 connected. That through the membrane 112 separated second gas volume 16 only needs to be with a surge tank 98 be connected when performing 24 is designed gas-tight.

10 shows a tenth embodiment of the invention with a compressor device 120 , At the compressor device 120 is by a single electro-hydrostatic drive device 8th a plurality of compressor devices, here a first and a second compressor device 6-1 . 6-2 , powered. Ie. the hydraulic piston 38 is both with a first compressor element 12-1 a first compressor cylinder 10-1 as well as with a second compressor element 12-2 in a second compressor cylinder 10-2 mechanically via a fork-shaped linkage 122 coupled. In this way, with an electro-hydrostatic drive device 8th several compressor devices 6-i and thus several cooling devices are operated.

Instead of the rigid mechanical coupling via the coupling rod 18 can the hydraulic piston 38 and the compressor element 12 Magnetically coupled with each other. The advantage of a magnetic coupling is that in the compressor cylinder 10 the compressor device and the hydraulic cylinder 36 no implementation 24 . 46 for the coupling rod 18 be required, whereby the escape of helium from the compressor cylinder 10 almost impossible.

LIST OF REFERENCE NUMBERS

2

compressor device

4

cooler

6

compressor means

8th

electrohydrostatic drive device

10

compression cylinder

12

Compressor element, piston

14

first gas volume

16

second gas volume

18

coupling rod

20

first end of 18

22

second end of 18

24

gastight execution in 10

25

Working fluid expansion tank

26

first gas line

27

second gas line

28

check valve

30

electric motor

32

hydraulic pump

34

first hydraulic line

36

hydraulic cylinders

38

hydraulic pistons

40

first partial volume in 28

42

second partial volume in 28

44

second hydraulic line

46

liquid-tight implementation

48

gas pipe

50

thermodynamic cycle

52

capacitor

54

throttle

56

Evaporator

58

gas pipe

60

Valve control device

70

compressor device

72

gastight envelope

75

compressor device

80

compressor device

82

O-ring

84

compressor device

90

compressor means

92

bellow

94

gas pipe

96

Volume inside 92

98

Fluid expansion tank

100

compressor means

110

compressor means

112

membrane

120

compressor device

122

fork-shaped linkage

10-1

first compressor cylinder

10-2

second compressor cylinder

12-1

first compressor element

12-2

second compressor element

130

Helium compressor

132

High-pressure line

134

Low-pressure line

136

rotary valve

138

gas pipe

140

cooler

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102008025045 B4 [0015]

Claims (27)

Compressor device, with a compressor device ( 6 ; 90 ; 100 ) in which a working medium by a reciprocating compressor element ( 12 ; 92 ; 112 ) is periodically compressed, and a drive device ( 8th ) mechanically or magnetically with the compressor element ( 12 ; 92 ; 112 ) is coupled. Compressor device according to claim 1, characterized in that the compressor device ( 6 ; 90 : 100 ) with a working medium expansion tank ( 25 ) connected is. Compressor device according to claim 2, characterized in that the compressor element ( 12 ; 92 ; 112 ) the compressor device ( 6 ; 90 ; 100 ) into a first and a second gas volume ( 14 . 16 ) and that the working medium expansion tank ( 25 ) via a first gas volume ( 14 ) open check valve ( 28 ) with the first gas volume ( 14 ) connected is. Compressor device according to claim 3, characterized in that the working medium expansion tank ( 25 ) directly with the second gas volume ( 16 ) connected is. Compressor device according to claim 3, characterized in that the second gas volume ( 16 ; 96 ; 16 . 96 ) via a line ( 94 ) with a fluid expansion tank ( 98 ) connected is. Compressor device according to one of the preceding claims, characterized in that the drive device ( 8th ) has a control device by means of which the compression of the working medium takes place according to a predetermined pattern. Compressor device according to claim 6, characterized in that the predetermined pattern changes over time. Compressor device according to one of the preceding claims, characterized in that the compressor device ( 6 ; 90 ; 100 ) a filter is connected downstream. Compressor device according to one of the preceding claims, characterized in that the working medium is helium. Compressor device according to one of the preceding claims, characterized in that the drive device ( 8th ) a plurality of compressor devices ( 6-1 . 6-2 ) drives. Compressor device according to one of the preceding claims, characterized in that the drive device ( 8th ) and the compressor device ( 6 ) each a gas-tight housing ( 36 . 10 ; 72 . 10 ) and that the two housings ( 36 . 10 ; 72 . 10 ) Are connected to each other gas-tight. Compressor device according to one of the preceding claims, characterized in that the compressor device ( 6 ; 90 ; 100 ) is designed for a working frequency range between 0.1 and 10 Hz and in particular for a working frequency range between 0.5 and 5 Hz. Compressor device according to one of the preceding claims, characterized in that the mechanical coupling between the drive device ( 8th ) and compressor element ( 6 ; 90 ; 100 ) via a rigid piston rod ( 18 ) he follows. Compressor device according to one of the preceding claims, characterized in that the compressor device ( 6 ; 90 ; 100 ) is designed as a promotional compressor device. Compressor device according to one of the preceding claims, characterized in that the compressor element comprises a piston device ( 12 ). Compressor device according to claim 15, characterized in that the compressor device ( 6 ; 90 ) is a linear piston compressor. Compressor device according to one of the preceding claims, characterized in that the drive device ( 8th ) is an electro-hydrostatic drive device. Compressor device according to claim 17, characterized in that the electro-hydrostatic drive device ( 8th ) an electric motor ( 30 ), a hydraulic pump driven by the electric motor ( 32 ) with a hydraulic cylinder ( 36 ), in which a hydraulic piston ( 38 ) is arranged linearly movable, wherein the hydraulic piston ( 38 ) mechanically or magnetically with the compressor element ( 12 ) of the compressor device ( 6 ) is coupled. Compressor device according to claim 18, characterized in that the direction of movement of the hydraulic cylinder ( 36 ) by the direction of rotation of the electric motor ( 30 ) is controlled. Compressor device according to one of the preceding claims, characterized in that the drive device ( 8th ) via a coupling rod ( 18 ) mechanically with the compressor device ( 6 ; 90 ), and that of the Drive device ( 8th ) facing away from the coupling rod ( 18 ) is designed as a compressor element. Compressor device according to one of the preceding claims, characterized in that the compressor element ( 12 ) a membrane ( 112 ). Compressor device according to claim 21, characterized in that the membrane ( 112 ) consists of metal. Compressor device according to one of the preceding claims, characterized in that the compressor element comprises a bellows ( 92 ). Cooling device with a compressor device according to one of the preceding claims and a Gifford-McMahon cooler or a pulse tube cooler, wherein the compressor device ( 6 ; 90 ; 100 ) is coupled to the Gifford-McMahon cooler or the pulse tube refrigerator. Cooling device according to claim 24, characterized in that the compressor device ( 6 ) a high-pressure connection ( 102 ) and that the Gifford-McMahon cooler or the pulse tube cooler with the high pressure port ( 102 ) of the compressor device ( 6 ; 90 ; 100 ) connected is. Cooling device according to claim 24, characterized in that the compressor device ( 6 ; 90 ; 100 ) a low pressure port ( 104 ) and that the Gifford-McMahon cooler or the pulse tube cooler with the low pressure connection ( 104 ) of the compressor device ( 6 ) connected is. Compressor chiller, in particular for conventional refrigerators, with a compressor device ( 2 ; 70 ; 75 ; 80 ; 84 ; 90 ; 120 ) according to one of the preceding claims 1 to 22, an evaporator ( 56 ) and a capacitor ( 52 ).

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