EP2212556A1

EP2212556A1 - Linear compressor and drive unit therefor

Info

Publication number: EP2212556A1
Application number: EP08852620A
Authority: EP
Inventors: Jan-Grigor Schubert
Original assignee: BSH Bosch und Siemens Hausgeraete GmbH
Current assignee: BSH Hausgeraete GmbH
Priority date: 2007-11-19
Filing date: 2008-10-21
Publication date: 2010-08-04
Anticipated expiration: 2028-10-21
Also published as: DE102007055166A1; ATE547628T1; ES2380647T3; EP2212556B1; WO2009065684A1

Abstract

The invention relates to a drive unit for a linear compressor, comprising a rack (1, 9), an oscillating body (5), and a membrane spring (6, 7), which is attached to a first attachment point on the rack (1) and to a second attachment point on the oscillating body (5) in order to guide the oscillating body (5) on the rack (1, 9) back and forth in a movable manner. The membrane spring (6, 7) has a smaller cross-section in the center region (25) between the two attachment points, than at the attachment points.

Description

Linear compressor and drive unit for it

The present invention relates to a linear compressor, in particular for use for compressing refrigerant in a refrigerator, and a drive unit for driving an oscillating piston movement for such a linear compressor.

DE 10 2004 062 301 A1 discloses a drive unit for a linear compressor with a frame, a vibrating body that is movable in the frame via at least one diaphragm spring and at least one auxiliary spring acting parallel to the movement. The diaphragm spring of this known drive unit comprises four arms which are integrally connected to one another on the oscillating body and extend in each case zigzag outwards from the oscillating body to attachment points on the frame. Since the arms of the diaphragm spring are easier to deform in the direction of movement of the oscillating body than transversely thereto, they ensure a precise guidance of the oscillating body, without requiring additional guide parts. In each case, the pairwise opposite spring arms force the oscillating body to a straight-line oscillating movement, in which the distance of a fastening point of the oscillating body to the spring at the reversal points of the oscillating motion is greater than in the equilibrium position. Since the material of the diaphragm spring is not stretched to any significant extent, the diaphragm spring can only yield to the forces acting at the reversal points between the attachment points by the middle portion of each spring arm is compressed in its longitudinal direction. The occurring deformation of the diaphragm spring is unevenly distributed, in particular stress peaks occur at the break points at which the arms change direction. When the linear compressor is in operation, the diaphragm spring 50 experiences load changes per second, corresponding to the frequency of the AC voltage with which the compressor is operated. In order to achieve a life of the linear compressor of many years, corresponding to the life expectancy of the rotary-driven compressors introduced on the market, the material of the leaf spring has to withstand many millions of load changes without significant damage or fatigue. This goal is difficult to achieve with the currently known forms of diaphragm springs. Object of the present invention is therefore to provide a drive unit for a linear compressor, which works reliably for a long time with high probability.

The object is achieved by a drive unit for a linear compressor with a frame, a vibrating body and a diaphragm spring at a first attachment point on the frame and at a second attachment point on

Oscillating body is mounted to guide the oscillating body to the frame to and fro, the diaphragm spring in a region between the two attachment points, preferably a central region, a smaller cross-sectional area than at the attachment points. The occurring in the leaf spring in the deflected state

Bending moments are unevenly distributed over the length of the leaf spring: they are greatest at the attachment sites, i. where the lever arm of each other

Attachment point is the largest, and minimal in the middle, where opposite

Compensate torques of the two attachment points each other. By reducing the cross-section of the diaphragm spring in the central region, a more uniform distribution of the bending load over the material of the diaphragm spring can be achieved and the fatigue tendency of the spring material is reduced.

The attachment points are conveniently located at two opposite ends of the elongated diaphragm spring.

The diaphragm spring preferably has a constant thickness and in the middle region a smaller width than at the fastening points. Thus, the membrane can be made in a simple manner from flat material of constant thickness, in particular punched out of spring plate.

The diaphragm spring should be free of openings.

In order to avoid that the deformation stress concentrates at individual points of the diaphragm spring, the cross section of the diaphragm spring expediently varies continuously in the longitudinal direction of the diaphragm spring. It is particularly advantageous if the change in cross section beyond that in the longitudinal direction is continuously differentiable. The diaphragm spring should be free of openings. Namely, if an opening tapers toward one of the attachment points, the forces acting in the spring tend to concentrate at the tip, so that in the course of operation material damage preferably occurs in the vicinity of such a tip. If, on the other hand, a wall of the opening facing the attachment point is rounded off, the change in the cross-sectional area of the diaphragm spring is inevitably discontinuous, and a uniform distribution of the deformation stress via the spring can not be achieved.

In a diaphragm spring of constant thickness free from the need for a constant change in the Ouerschnitts in the longitudinal direction of the spring is equivalent to a continuous or stepless course of the longitudinal edges of the spring, and a continuously differentiable Ouerschnitt corresponds to a free of wrinkles course of the longitudinal edges.

In particular, the above requirements are easy to fulfill because the diaphragm spring has at least one concave edge.

The curvature of the deflected diaphragm spring should change its sign across its middle section. In the middle section then necessarily exists an undeformed site.

A shape of the deformable region of the diaphragm spring has proven to be particularly resistant, comprising in longitudinal section two mutually inversion-symmetrical arcs, in particular parabolic arcs. Although a curve function that describes the edge course of such a diaphragm spring can not be specified in analytical form, but a specialist can make a prototype of such a diaphragm spring without inventive effort by starting from a diaphragm spring of any shape whose longitudinal section detected in the deflected state and Places whose curvature is smaller than desired, abrading material. In the same way, an arc shape can be realized whose curvature increases linearly from a clamped edge region up to a local maximum, from there it decreases linearly to a local minimum while the sign changes, and from there rises again to zero. It is also advantageous to provide at least a second diaphragm spring, the arms of which act on a region of the oscillating body which is spaced from the engagement region of the first diaphragm spring in the direction of the oscillating movement. By two diaphragm springs of the vibrating body is reliably guided to the linear device of the desired oscillating motion, and a lateral rolling movement of the vibrating body can be avoided.

In order to achieve a high long-term stability of the diaphragm spring, the material of the diaphragm spring should be as thin as possible and thus easily flexible. However, a slightly flexible diaphragm spring has a low resonance frequency. The resonant frequency is in turn proportional to the capacity of a linear compressor in which the drive unit is used. Therefore, a high resonance frequency is desired from the viewpoint of the capacity. In order to meet these contradictory requirements, preferably at least one parallel to the movement of the oscillating body acting auxiliary spring is provided.

The stiffness of the diaphragm spring parallel to the movement is preferably smaller than that of the auxiliary spring. Thus, the time sequence and in particular the period of the oscillatory movement is essentially determined by the auxiliary spring, while the diaphragm spring essentially determines the path of the oscillating body during the oscillating movement.

The auxiliary spring may conveniently be a coil spring. The center of gravity of the oscillating body (5) is then preferably movable along the longitudinal axis of the helical spring.

Preferably, the drive unit comprises two auxiliary springs, which are connected to each other at two first ends and to the oscillating body and extend in opposite directions in the direction of movement. Such an arrangement allows a compact construction of a linear compressor, which uses the drive unit according to the invention. Such a linear compressor preferably has a compressor chamber coupled to the oscillating body by a piston rod. Since the suspension of the oscillating body on the leaf spring guides the oscillating body on a slightly curved path, but the compressor chamber requires an exactly linear drive movement, a transverse component of the movement of the oscillating body can be compensated by means of the piston rod.

In a space-saving construction, the piston rod is surrounded by the at least one auxiliary spring.

In order to introduce the force of the auxiliary springs in the oscillating body, preferably carries the piston rod a flange, press against the two auxiliary springs from opposite directions.

Further features and advantages of the invention will become apparent from the following description of embodiments with reference to the accompanying figures. Show it:

Fig. 1 is a perspective view of a linear compressor;

Fig. 2 is a plan view of a diaphragm spring of the linear compressor of Fig. 1; and

3 shows a longitudinal section of the diaphragm spring in the deflected state.

The linear compressor shown in Fig. 1 has a frame 1 with a base plate on which two E-shaped soft iron cores 2 are mounted mirror-symmetrically opposite each other. Of the three mutually facing legs 3 of the soft iron cores 2 each of the middle is hidden by a magnetic coil 4, by the winding it extends.

In a gap between the mutually facing free ends of the legs 3 of the soft iron cores 2, a vibrating body 5 by means of two diaphragm springs 6, 7 suspended. As can be seen in particular in the plan view of FIG. 2, the Membrane springs 6, 7 made of spring steel in each case substantially the shape of a rectangle waisted by recesses along its longitudinal sides. On the narrow sides of the rectangle in each case a plurality of mounting holes 8 are formed, which serve for anchoring the diaphragm spring 6, 7 on an end face of the oscillating body 5 or on an edge of a projecting from the base plate side wall 9 of the frame 1 by means of screws, rivets or the like , which pass through the mounting holes 8 and openings of clamping plates 14. The clamping plates 14 are shown in Fig. 1 transparent to leave the mounting holes 8 visible. The edge portions of the diaphragm spring 6 are, by being clamped between the clamping plates 14 and the end face of the oscillating body 5 and the edge of the side wall 9, protected from any deformation. The deformable surface of the diaphragm spring 6 lying between the attachment points is free of openings of any kind.

By a larger, central bore 10 on one of the narrow sides of the diaphragm spring 6, a piston rod 11 which connects the vibrating body 5 with a reciprocating in a pumping chamber 12, not shown piston extends. For ease of assembly because of the spring 6, 7 symmetrically, each with a larger bore 10 on each narrow side formed. The holes 8 are each on two mutually parallel, dash-dotted line in Fig. 2 lines.

A control circuit, not shown, applied to the magnetic coils 4 with an alternating current of controlled frequency and amplitude, to generate between each of the middle and the two outer legs 3 magnetic fields with alternating orientation. The vibrating body 5 includes a permanent magnet which is subjected to an oscillating force by the magnetic field thus generated and drives a swinging motion of the vibrating body 5. The two diaphragm springs 6, 7 guide the vibrating body 5 on a slightly curved path, wherein movement of the vibrating body 5 transversely to the direction of movement of the piston in the pumping chamber 12 is absorbed by a corresponding oscillating movement of the piston rod 11 and is not transmitted to the piston. The path on which the oscillating body 5 moves is exactly defined by the diaphragm springs 6, 7.

The capacity of the compressor is proportional to the resonant frequency of the oscillating body 5. To order at low material thickness of the diaphragm springs 6, 7 a To achieve sufficient flow rate, it is therefore desirable to make the resonance frequency higher than would be possible using only the diaphragm springs 6, 7. To stiffen the oscillatory system in the direction of movement of the piston are two coil springs 16, 17, each attacking on opposite sides of a protruding from the piston rod 1 1 flange 18 and of which the 16 at a movement of the diaphragm spring 6 limiting intermediate edge 19 of the Frame 1 and the other 17 is supported on the pumping chamber 12. The coil springs 16, 17 are exactly centered on the piston rod 11 by means of flat circular disks 20 and a ring 21, and by a truncated cone 22, of the flange 18 on its two sides, of the intermediate wall 19 and of the pumping chamber 12 from into the interior of the coil springs 16, 17 engage. By centering is excluded that the coil springs 16, 17 except a desired force in the direction of the piston rod 1 1 also exert a torque on the oscillating system of oscillating body 5, piston rod 11 and piston.

Fig. 2 shows a plan view of one of the two identical spring plates 6.7. Between the clamped edge portions of the deformable main portion extends with continuous, inwardly curved longitudinal edges 15. The course of the longitudinal edges is chosen so that when the spring plate 6 and 7 is deflected, a longitudinal section results in the greatly over-marked in Fig. 3 course The main section has two oppositely curved halves 23, 24. The curvature is zero at each edge of each half 23, 24, ie at a center line 25, at which the halves 23, 24 adjoin one another, and where the halves pass into the clamped edge portions. The center line 25 is also the point at which the width of the diaphragm spring 26 is minimal. From each edge, the curvature increases linearly toward the center of the respective half 23, 24, i.e., in the direction of the center. the points 26 of maximum curvature are in each case in a distance corresponding to one quarter of the length of the main section from its center 25 or its edges.

Claims

claims

1. Drive unit for a linear compressor with a frame (1, 9), a vibrating body (5) and a diaphragm spring (6, 7), at a first attachment point on the frame (1) and at a second attachment point on

Oscillating body (5) is fixed to the oscillating body (5) on the frame (1, 9) to move back and forth, characterized in that the diaphragm spring (6, 7) in a region (25) between the two attachment points a having smaller cross-sectional area than at the attachment points.

2. Drive unit according to claim 1, characterized in that the region (25) is at least approximately in the middle between the first and second attachment point.

3. Drive unit according to claim 1 or 2, characterized in that the

Attachment points are located at two opposite ends of the elongated diaphragm spring (6, 7).

4. Drive unit according to one of claims 1 to 3, characterized in that the diaphragm spring (6, 7) has a constant material thickness and in the middle

Region (25) has a smaller width than at the attachment points.

5. Drive unit according to one of the preceding claims, characterized in that the cross section in the longitudinal direction of the diaphragm spring (6, 7) varies continuously.

6. Drive unit according to claim 5, characterized in that the cross section in the longitudinal direction of the diaphragm spring (6, 7) is continuously differentiable.

7. Drive unit according to one of the preceding claims, characterized in that a deformable region (23, 24) of the diaphragm spring (6, 7) is free of openings.

8. Drive unit according to one of the preceding claims, characterized in that the diaphragm spring (6, 7) at least on one of its longitudinal sides has a concave edge (15).

9. Drive unit according to one of the preceding claims, characterized in that the curvature of the diaphragm spring (6, 7) over the central region (25) away changes its sign.

10. Drive unit according to claim 9, characterized in that the deflected diaphragm spring (6, 7) in a longitudinal section comprises two mutually inversion symmetrical arcs (23, 24).

11. Drive unit according to claim 10, characterized in that the sheets (23, 24) are parabolic.

12. Drive unit according to claim 10, characterized in that the curvature over the length of the sheets (23, 24) varies linearly away.

13. Drive unit according to one of the preceding claims, characterized in that it comprises at least one second diaphragm spring (7, 6), and in that the first and the second diaphragm spring (6, 7) at in the direction of the oscillating movement spaced areas of the oscillating body (5) attack.

14. Drive unit according to one of the preceding claims, characterized by at least one parallel to the movement of the oscillating body (5) acting auxiliary spring (16, 17).

15. Drive unit according to claim 17, characterized in that the rigidity of the diaphragm spring (6, 7) parallel to the movement is smaller than that of the auxiliary spring (16, 17)

16. Drive unit according to claim 14 or 15, characterized in that the auxiliary spring (16, 17) is a helical spring and that the center of gravity of Oscillating body (5) along the longitudinal axis of the coil spring (16, 17) is movable.

17. Drive unit according to one of claims 14 to 16, characterized in that it comprises two auxiliary springs (16, 17) which are connected to each other at two first ends and with the oscillating body (5) and in the

Extend direction of movement in opposite directions.

18. A linear compressor with a in a compression chamber (12) slidably guided piston, which is connected by a piston rod (11) with the oscillating body (5), characterized by a drive unit according to one of the preceding claims.

19. A linear compressor according to claim 18, characterized in that the piston rod (11) is at least partially surrounded by the at least one auxiliary spring (16, 17).

20. A linear compressor according to claim 18 or 19, characterized in that the piston rod (11) carries a flange (18) against which two auxiliary springs (16, 17) press from opposite directions.

21. Refrigerating appliance with a linear compressor according to one of claims 18 to 20.