DE112004001771B4 - Reciprocating compressor with a lateral displacement damping support unit - Google Patents

Abstract

Reciprocating Compressor with:
- A housing (100) comprising a suction line through which a fluid is supplied from the outside, and a drain line (DP), through which the fluid is discharged to the outside, and which forms a predetermined interior space;
A compressor main body (700) disposed in the housing (100) that compresses fluid supplied through the suction pipe (SP) by linear reciprocation of a piston (420) and discharges the compressed fluid through the exhaust pipe (DP) ; and
- A carrier unit (600) having a plurality of coil springs (610, 620) connecting the compressor main body (700) to the housing (100), wherein the plurality of coil springs (610, 620) respectively Endwicklungen (590), the tightly wound are to be attached to a surface of the compressor main body (700) or to a surface of the housing (100), and an inner winding (580) having at least one portion tightly wound without clearance and between the end windings ( 590) arranged ...

Description

Technical area

The The present invention relates to a reciprocating compressor, in particular a reciprocating compressor, with its lateral displacement absorbing support unit and in particular a reciprocating compressor with a lateral one Displacement damping Support unit which is capable of lateral vibration of a compressor minimize, which is generated in a direction in which a reciprocating engine is operated during operation of the reciprocating compressor.

State of the art

in the Generally, a reciprocating compressor forms an air conditioning device, sucks a cooling gas and discharges the compressed refrigerant gas outside the compressor, when a piston reciprocates linearly in a cylinder.

As in 1 1, a conventional reciprocating compressor includes an exterior forming housing 10 having a certain space therein and comprising a suction pipe (SP) through which a cooling gas is supplied, and a drain pipe (DP) through which the refrigerant gas compressed in the compressor is discharged to the outside, one in the casing 10 arranged compressor main body 70 for compressing the sucked-in cooling gas and a carrier unit 60 with a plurality of coil springs constituting the compressor main body 70 elastic with a surface of the housing 10 connect, leaving the main body 70 on the housing 10 is attached.

The main body 70 the compressor comprises a frame unit 20 that is elastic with the carrier unit 60 connected and the whole frame of the main body 70 forms, a reciprocating engine 30 That stuck to the frame unit 20 is mounted and generates a linear reciprocating driving force, and a compression unit 40 attached to the frame unit 20 supported and the sucked cooling gas by a driving force of the reciprocating engine 30 compressed.

The frame unit 20 includes a front frame 21 , one by the carrier unit 60 having supported surface and a surface of the reciprocating engine 30 attached, a middle frame 22 attached to the other surface of the front frame 21 attached reciprocating engine 30 is attached, and a rear frame 23 , one by the carrier unit 60 has elastically attached surface and with the middle frame 22 connected is.

The reciprocating engine 30 includes an outer stator 31 that is stuck between the front frame 21 and the middle frame 22 attached and a coil 34 therein comprises an inner stator 32 , the outer stator 31 at a certain distance and fixed to one side of the front frame 21 attached, and a rotor 33 which is linear between the outer stator 31 and the inner stator 32 emotional.

The compression unit 40 includes a cylinder 41 Being attached to this in the front frame 21 is introduced a piston 42 having a path (F) for a refrigerant gas therein and having one end with the rotor 33 is connected to thereby in the cylinder 41 to move back and forth, a suction valve 43 attached to a front end of the piston 42 is mounted to open and close the cooling gas path (F), and a drain valve assembly 44 at one end of the cylinder 41 is attached to control the discharge of the compressed refrigerant gas. A compression space (P) is between the suction valve 43 and the drain valve assembly 44 educated.

Here are a front resonance spring 51 and a rear resonance spring 52 that produces a resonant motion of the piston 42 cause between one end of the rotor 33 connected piston 42 and one end of the front frame 21 or between the one end of the piston 42 and one end of the rear frame 23 appropriate.

A plurality of the carrier unit 60 forming coil springs includes a front coil spring 61 that the front frame 21 with a surface of the housing 10 connects, and a rear coil spring 62 that the rear frame 23 with a surface of the housing 10 connects, leaving the main body 70 elastic on the inside of the housing 10 is attached.

As in the 1 and 2 is shown is the plurality of coil springs 61 and 62 formed by a plurality of helical windings with equal distances and the same diameter. That is, the coil spring 61 . 62 has an internal winding wound several times 58 as well as at both ends of the inner winding 58 trained endwindings 59 on.

The inner winding 58 is wrapped with regular gradients (t) and each of the endwindings 59 is tightly wound, leaving the coil spring 61 . 62 on a surface of the compressor main body 70 - the front frame 21 and the rear frame 23 - And a surface of the housing 10 can be attached.

Of the The conventional reciprocating compressor described above becomes as follows operated.

When a current goes to a coil 34 an outer stator 31 a reciprocating engine 30 is applied, becomes a magnetic induction field having a direction of a current changing direction on the outer stator 31 and an electromagnetic force having a direction changing according to a direction of the magnetic induction field is formed by the interaction between the magnetic induction field and a magnetic field of the inner stator 32 between the outer stator 31 and the inner stator 32 generated. Here will be a rotor 33 and a piston 42 moved together in one direction of the electromagnetic force and simultaneously generates the piston 42 a pressure difference in a compression space (P) of the cylinder 41 while moving through the front and rear resonant springs 51 and 52 is linearly reciprocated in the cylinder, thereby repeatedly performing a series of steps of sucking a cooling gas and compressing the sucked cooling gas until the pressure reaches a certain level and the compressed refrigerant gas is discharged.

If the compressor includes the steps of sucking and discharging a cooling gas goes through an operation of the reciprocating engine, is on the main body a Vibration generated. Such vibration of the compressor main body is performed by a carrier unit reduced, which comprises a plurality of coil springs with regular gradients, and so will the noise and the on the case of the compressor transmitted Reduced vibration.

However, the above-described conventional reciprocating compressor naturally vibrates mainly in the lateral direction, that is, in a direction in which the piston of the reciprocating motor moves. Nevertheless, the lateral stiffness of the coil spring is small, since an inner coil of each coil spring for supporting the main body of the reciprocating compressor is formed with regular pitches. As in 3 is shown, for this reason, a lateral displacement (L) of the compressor becomes large and thus the compressor main body is excessively inclined, whereby the vibration of the compressor becomes very strong.

A reciprocating compressor, similar to the above with respect to the 1 to 3 described reciprocating compressor, is in document EP 1 580 428 A1 disclosed. The reciprocating compressor has a housing in which a stored on coil springs electric compression element is added. The coil springs are arranged to reduce the noise and vibration of the electric compressor. The coil springs according to this document have between the upper and lower end winding areas with different distances between the individual windings. The distances between the individual windings in the middle region of the helical spring are less than the spacings of the windings, which run towards the upper or lower end region of the helical spring. By reducing the distances of the windings in the central region of the coil spring, the vibrations and lateral displacements of the compressor can be reduced only to a very small extent.

The document WO 01/98658 A2 discloses a suspension system for a reciprocating engine. A spring, for example a compression spring, this suspension motor has constant distances and slopes of the individual windings to each other. The respective last upper and lower winding of the spring has a larger diameter than the windings in the region between the two end windings.

Disclosure of the invention

It is therefore an object of the present invention, a reciprocating compressor with a lateral displacement damping carrier unit, which is capable of a lateral vibration of a compressor to a greater extent to minimize as the prior art, which generates in one direction in which a reciprocating engine during operation of the reciprocating compressor is operated.

to solution the above object provides a reciprocating compressor, which comprises: a housing, a suction pipe through which a fluid is supplied from the outside, and a drain pipe includes, through which the fluid is discharged to the outside, and the forms a predetermined internal space, a compressor main body disposed in the housing that fed through the suction line Fluid compressed by a linear reciprocating motion of a piston and discharging the compressed fluid through the drain line, and a carrier unit with a plurality of coil springs, the compressor main body with the housing connect, wherein the plurality of coil springs respectively end windings, which are tightly wound to on a surface of the compressor main body and on a surface of the housing to be attached, as well as an inner winding that covers between the pair of end windings is arranged and at least one without clearance has tightly wound section.

Description of the drawings

1 is a longitudinal sectional view of a conventional reciprocating compressor;

2 Fig. 10 is a side view showing a coil spring of a conventional reciprocating compressor;

3 Fig. 12 is a view showing a lateral displacement of a coil spring of a conventional reciprocating compressor;

4 Fig. 15 is a longitudinal sectional view showing an example of a reciprocating compressor according to the present invention;

5 Fig. 15 is a longitudinal sectional view of a reciprocating compressor for illustrating a coil spring according to a first embodiment of the present invention;

6 Fig. 10 is a side view showing a coil spring according to a first embodiment of the present invention;

7 Fig. 16 is a view showing a lateral displacement of a coil spring according to a first embodiment of the present invention;

8th Fig. 15 is a longitudinal sectional view of a reciprocating compressor for illustrating a coil spring according to a second embodiment of the present invention;

9 Fig. 10 is a side view showing a coil spring according to a second embodiment of the present invention;

10 Fig. 12 is a view showing a lateral displacement of a coil spring according to a second embodiment of the present invention;

11 Fig. 15 is a longitudinal sectional view of a reciprocating compressor for illustrating a coil spring according to a third embodiment of the present invention;

12 Fig. 10 is a side view showing a coil spring according to a third embodiment of the present invention; and

13 FIG. 16 is a view showing a lateral displacement of a coil spring according to a third embodiment of the present invention. FIG.

Type of invention

It will now be described in detail on the preferred embodiments of the present Invention, for the examples in the accompanying drawings are shown.

4 is a longitudinal sectional view showing a reciprocating compressor according to the invention.

As shown therein, the reciprocating compressor of the present invention comprises: a housing 100 that forms an outside of a compressor, has a certain space therein, and includes a suction pipe (SP) through which a cooling gas is supplied and a discharge pipe through which the refrigerant gas compressed in the compressor is discharged to the outside, becomes one in the casing 100 arranged compressor main body 700 for compressing and discharging the sucked-in cooling gas, and a carrier unit 600 with a plurality of coil springs constituting the compressor main body 700 elastic with a surface of the housing 100 connect, leaving the main body 700 on the housing 100 is attached.

The compressor main body 700 includes a frame unit 200 that is elastic with the carrier unit 600 is connected and the entire frame of the main body 700 forms, a reciprocating engine 300 That stuck to the frame unit 200 is mounted to produce a linear reciprocating driving force, and one through the frame unit 200 supported compression unit 400 to the sucked cooling gas by a driving force of the reciprocating motor 300 to compress.

The frame unit 200 includes a front frame 210 , one of the carrier unit 600 having supported surface and a surface of the reciprocating engine 300 attached, a middle frame 220 attached to the other surface of the front frame 210 attached reciprocating engine 300 is attached, and a rear frame 230 , which is elastic on the carrier unit 600 has attached surface and with the middle frame 220 connected is.

The reciprocating engine 300 includes an outer stator 310 that is stuck between the front frame 210 and the middle frame 220 attached and a coil 340 having an inner stator 320 , the outer stator 310 at a certain distance and fixed to one side of the front frame 210 attached, and a rotor 330 which is linear between the outer stator 310 and the inner stator 320 emotional.

The compression unit 400 includes one cylinder 410 which attach to it in the front frame 210 is introduced a piston 420 having a path (F) for a refrigerant gas therein and an end connected to the rotor 330 is connected to thereby in the cylinder 410 to be moved back and forth, a suction valve 430 attached to a front end of the piston 420 is mounted to open and close the cooling gas path (F), and a drain valve assembly 440 at one end of the cylinder 410 is attached to control the discharge of the compressor cooling gas. Accordingly, a compression space (P) between the suction valve 430 and the drain valve assembly 440 educated.

Here are a front resonance spring 510 and a rear resonance spring 520 that produces a resonant motion of the piston 420 cause between one end of the rotor 330 connected piston 420 and one end of the front frame 210 or the one end of the piston 420 and one end of the rear frame 230 appropriate.

A plurality of coil springs that support the carrier 600 form, each includes a front coil spring 610 that the front frame 210 with a surface of the housing 100 connects, and a rear coil spring 620 that the rear frame 230 with a surface of the housing 100 connects, leaving the main body 700 elastic on the inside of the housing 100 is attached.

As in 4 is shown is the plurality of coil springs 610 and 620 formed by a plurality of helical windings of the same diameter. That is, the coil spring 610 . 620 has a multiple wound inner winding 580 as well as endwindings 590 on that at both ends of the inner winding 580 are formed.

The inner winding 580 has at least a portion that is tightly wound around the vibration of the compressor main body 700 diminished, which is generated in a direction in which the piston 420 emotional. In addition, the final winding 590 tightly wound, leaving the coil spring 610 . 620 on a surface of the compressor main body 700 - the front frame 210 and the rear frame 230 - And on a surface of the housing 100 can be attached.

There are several embodiments of a reciprocating compressor with a carrier unit 600 possible that the majority of coil springs 610 and 620 includes. In the following, the particularly preferred embodiments will be described, and descriptions overlapping with the above description will be omitted.

5 shows one of a plurality of coil springs, which form a support unit of a reciprocating compressor according to a first embodiment of the present invention.

Although only a front coil spring in 5 is shown, the remaining coil springs of the reciprocating compressor on the same structure as that shown in the drawing. A structure shown in another drawing for a further embodiment to be described below is also present in the other coil springs of the corresponding compressor.

The coil spring 610 . 620 according to the first embodiment of the present invention comprises end windings 590 , which are tightly wound, so that they are each attached to a surface of the housing 100 and a surface of the main body, in particular, a surface of the frame unit 200 are attached, and an inner winding 580 that wound and with the final winding 590 connected is.

The inner winding 580 includes a pair of elastic sections 631 , the predetermined slopes (t) from the end winding 590 in the direction of the central portion of the coil spring, and a mass portion 632 attached to the middle section of the coil spring between the pair of elastic sections 631 trained and tightly wound without a gap.

The winding number of the mass section 632 is two to four times the size of the final winding 590 so that the coil spring 610 . 620 has a rigidity, the lateral vibration of a reciprocating engine 300 and a compression unit 400 can withstand.

The pair of elastic sections 631 is wrapped with regular gradients.

In addition, each of the elastic sections 631 to be wound with gradients (T) coming from the end winding 590 in the direction of the mass section 632 or can be wound with gradients (T) coming from the end winding 590 in the direction of the mass section 632 increase.

In addition, each of the elastic sections 631 be wound with slopes between the end section 590 and the mass section 632 alternately increase and decrease.

The coil spring has a longitudinal stiffness and at the same time a lateral rigidity, by the pair of elastic sections 631 and the mass section 632 between the pair of elastic sections 631 includes.

As in the 6 and 7 is shown, the lateral stiffness of the coil spring is increased because the mass portion 632 which is tightly wound, between the pair of elastic sections 632 is formed, whereby a lateral displacement (L1) of the compressor main body 700 damped, and thus the vibration of the compressor main body is effectively reduced.

The 8th and 9 show a coil spring forming a support unit of a reciprocating compressor according to a second embodiment of the present invention.

As in 8th is shown comprises a coil spring 610 . 620 according to the second embodiment, a final winding 590 and an inner winding 580 that a couple of mass sections 641 includes, immediately adjacent to the end winding 590 are tightly wound, and an elastic section 642 which is wound with predetermined pitches (t) between the pair of mass portions.

The winding number of the mass section 641 is preferably two to four times as large as that of the final winding 590 ,

The elastic section 642 is preferably wound with regular gradients (t).

In addition, the elastic section 642 be wound with gradients facing towards the middle section of the coil spring 610 . 620 decrease or, in contrast, with gradients (T) increasing towards their middle section.

In addition, the elastic section 642 be wound with gradients between the pair of mass sections 641 alternately increase and decrease.

As in the 9 and 10 is shown, in this case, the lateral stiffness of the coil spring 610 . 620 through the mass sections 641 , which are tightly wound, increased, whereby one by the vibration of the compressor main body 700 caused lateral shift (L2) is effectively attenuated.

11 shows a coil spring, which forms a support unit of a reciprocating compressor according to a third embodiment of the present invention.

As shown here, includes a coil spring 610 . 620 according to the third embodiment, a final winding 592 and an inner coil having a first elastic portion 652 that of a on a surface of the compressor main body 700 attached end winding 590 is wound with predetermined pitches (t1), a second elastic portion 653 which is one of a surface of the housing 100 attached end winding 590 is wound with predetermined slopes (t2) different from those (t1) of the first elastic portion 652 differ, and a mass section 651 that is between the first and second elastic sections 652 and 653 is tightly wound.

The slopes (t1) of the first elastic section 652 or the slopes (t2) of the second elastic section are regular, but the two slopes (t1 and t2) are different.

In addition, the first elastic section 652 and the second elastic portion 653 be wound with gradients (t1, t2) coming from both end windings 592 and the mass section 651 and the ratios of decreasing the slope (t1) and the slope (t2) may be different.

In contrast, the first elastic section 652 and the second elastic portion 653 to be wound with gradients (t1 and t2) from both end windings 592 in the direction of the mass section 651 and the ratios of increase in slope (t1) and slope (t2) may be different.

In addition, the first elastic portion and the second elastic portion 653 to be wound with gradients (t1 and t2) from both end windings 592 in the direction of the mass section 651 alternately increase and decrease and the ratios of the increase of the slope (t1) and the slope (t2) may be different.

In addition, as another modification, one of the first and second elastic portions 652 and 653 however, the other elastic portion may be wound with gradients which are in the direction of the mass portion 651 increase. In contrast, one of the first and second elastic sections 652 and 653 however, the other elastic portion may be wound with gradients which are in the direction of the mass portion 651 lose weight.

In addition, one of the first and second elastic sections 652 and 653 however, the other elastic portion may be wound with gradients which are in the direction of the mass portion 651 alternately increase and decrease.

As in the 12 and 13 is shown, the lateral stiffness of the coil spring 610 . 620 by such a construction of a coil spring 610 . 620 According to the third embodiment, increased by the mass portion, which is tightly wound. Since the elasticity coefficients of the first elastic section 652 and the second elastic portion 653 are different, moreover, by the vibration of the compressor main body 7 caused lateral displacement to be damped more effectively.

In dependence the construction can over it In addition, the compressor main body on the housing supported be by coil springs, a carrier unit of the reciprocating compressor according to a each embodiment form the present invention, arranged in a suitable manner become.

Of the inventive reciprocating compressor is operated as follows.

When a current goes to a coil 340 an outer stator 310 a reciprocating engine 300 is applied, becomes a magnetic induction field with a direction of a current variable direction on the outer stator 310 is formed and an electromagnetic force with a direction changeable by a direction of the magnetic induction field by the interaction between the magnetic induction field and a magnetic field of the inner stator 320 between the outer stator 310 and the inner stator 320 generated. At this time will be a rotor 330 and a piston 420 moved together in one direction of the electromagnetic force and at the same time moves the piston 420 through front and rear resonance springs 510 . 520 linear in a cylinder back and forth, creating a pressure difference in a compression space of the cylinder 410 is produced. Thus, a series of steps of sucking a cooling gas into the compression space (P) and compressing the sucked cooling gas until the pressure reaches a certain level and then discharging the compressed cooling gas are repeatedly executed. When the rotor 330 and the piston 420 reciprocating the reciprocating motor, here becomes the compressor main body 700 a vibrating body excessively shaken in a direction in which the piston reciprocates, that is, in a lateral direction of the compressor, thereby generating a vibration. However, by the present invention includes the coil spring 610 . 620 for supporting the compressor main body 7 a mass section that functions as a mass by being tightly wound. In addition, an elastic portion having predetermined slopes is formed in the vicinity of the mass portion. Accordingly, the coil spring not only provides an elastic force, which is a fundamental characteristic of a coil spring, but also a high lateral rigidity, whereby a lateral displacement of the compressor main body is damped and thus the vibration of the compressor is effectively reduced.

It goes without saying the skilled person that various modifications and variations of the present invention possible are without the spirit or scope of the invention leave. Thus, it is intended that the present invention Modifications and variations of this invention, provided they fall within the scope of the appended claims as well as their equivalents.

Industrial applicability

As discussed above, according to the present Invention a reciprocating compressor with a one lateral displacement absorbing support unit minimize a lateral vibration of the compressor, which in one Direction is generated in which a reciprocating engine during operation of the Reciprocating compressor is operated.

Claims (21)

Reciprocating compressor with: - a housing ( 100 ) comprising a suction line through which a fluid is supplied from the outside, and a discharge line (DP) through which the fluid is discharged to the outside, and which forms a predetermined internal space; A compressor main body ( 700 ) located in the housing ( 100 ), the fluid supplied through the suction line (SP) is arranged by a linear reciprocating movement of a piston ( 420 ) and discharges the compressed fluid through the drain line (DP); and a carrier unit ( 600 ) with a plurality of coil springs ( 610 . 620 ), the compressor main body ( 700 ) with the housing ( 100 ), wherein the plurality of coil springs ( 610 . 620 ) each end windings ( 590 ) tightly wound to seal on a surface of the compressor main body (FIG. 700 ) or on a surface of the housing ( 100 ) and an inner winding ( 580 ), which has at least one section wound tightly without clearance and between the end windings ( 590 ) is arranged. A compressor according to claim 1, wherein the inner winding ( 580 ) comprises: - a pair of elastic sections ( 631 ), each of the end windings ( 590 ) are wound with predetermined pitches (t); and - a mass section ( 632 ), which is between the pair of elastic sections ( 631 ) is. A compressor according to claim 2, wherein each of said elastic portions (16) 631 ) is wound with regular gradients (t). A compressor according to claim 2, wherein each of said elastic portions (16) 631 ) is wound with gradients (T), which from the end winding ( 590 ) in the direction of the mass section ( 632 ) increase. A compressor according to claim 2, wherein each of said elastic portions (16) 631 ) is wound with gradients (T), which from the end winding ( 590 ) in the direction of the mass section ( 632 ) lose weight. A compressor according to claim 2, wherein each of said elastic portions (16) 631 ) is wound with gradients (T) between the end winding ( 590 ) and the mass section ( 632 ) alternately increase and decrease. A compressor according to claim 2, wherein the number of turns of the mass section ( 632 ) is two to four times as large as that of the end winding ( 590 ). A compressor according to claim 1, wherein the inner winding ( 580 ) comprises: - a pair of tightly wound mass sections ( 641 ) immediately adjacent to the end windings ( 590 ); and - an elastic section ( 642 ) between the pair of mass sections ( 641 ) and wound with predetermined pitches (T). A compressor according to claim 8, wherein the number of turns of the mass portion ( 641 ) is two to four times as large as that of the final winding ( 590 ). A compressor according to claim 9, wherein the elastic portion ( 642 ) is wound with regular gradients (t). A compressor according to claim 9, wherein the elastic portion ( 642 ) is wound with gradients (T), which in the direction of a central portion of the coil spring ( 610 . 620 ) lose weight. A compressor according to claim 9, wherein the elastic portion ( 642 ) is wound with gradients (T), which in the direction of the central portion of the coil spring ( 610 . 620 ) increase. A compressor according to claim 9, wherein the elastic portion ( 642 ) is wound with gradients (T), which increase and decrease alternately. A compressor according to claim 1, wherein the inner winding ( 580 ) comprises: - a first elastic section ( 652 ) having predetermined slopes (t1) from that at a surface of the compressor main body (Fig. 700 ) attached end winding ( 590 ) is wound; A second elastic section ( 653 ) with predetermined pitches (t2) from that on a surface of the housing ( 100 ) attached end winding ( 590 ), which are different from those of the first elastic section (FIG. 652 ) distinguish; and - a mass section ( 651 ) between the first and second elastic sections ( 652 . 653 ) is tightly wound. A compressor according to claim 14, wherein said first and second elastic portions (16) 652 . 653 ) each have regular slopes (t1, t2) and the two slopes (t1, t2) are different. A compressor according to claim 14, wherein said first and second elastic portions (16) 652 . 653 ) are wound with slopes (t1, t2) which are in the direction of the mass section ( 651 ), wherein the ratios of the increase of the slopes (t1) of the first elastic section ( 652 ) and the slopes (t2) of the second elastic section ( 653 ) differ from each other. A compressor according to claim 14, wherein said first and second elastic portions (16) 652 . 653 ) are wound with slopes (t1, t2) which are in the direction of the mass section ( 651 ), wherein the ratios of the decrease of the slopes (t1) of the first elastic section ( 652 ) and the slopes (t2) of the second elastic section ( 653 ) differ from each other. A compressor according to claim 14, wherein said first and second elastic portions (16) 652 . 653 ) are wound with slopes (t1, t2) which are in the direction of the mass section ( 651 ) alternately increase and decrease, the ratios of the increase and decrease of the slopes (t1) of the first elastic section ( 652 ) and the slopes (t2) of the second elastic section ( 653 ) differ from each other. A compressor according to claim 14, wherein one of said first and second elastic portions (16) 652 . 653 ) is wound with regular gradients (t1, t2), the other elastic portion ( 652 . 653 ) but is wound with gradients (t1, t2), which are in the direction of the mass portion ( 651 ) increase. A compressor according to claim 14, wherein one of said first and second elastic portions (16) 652 . 653 ) is wound with regular gradients (t1, t2), the other elastic portion ( 652 . 653 ) but wound with gradients (t1, t2), which in the direction of the mass portion ( 651 ) lose weight. A compressor according to claim 14, wherein one of said first and second elastic portions (16) 652 . 653 ) is wound with regular gradients (t1, t2), the other elastic portion ( 652 . 653 ) but is wound with gradients (t1, t2), which are in the direction of the mass portion ( 651 ) alternately increase and decrease.