RU2429376C2 - Linear compressor and driven unit for it - Google Patents

Abstract

FIELD: machine building. ^ SUBSTANCE: driven unit of linear compressor consists of frame (1) and oscillating body (12) connected to frame (1) by means of at least one diaphragm spring (6) and directed for rectilinear reciprocating motion relative to frame. Spiral spring (17) is secured on oscillating body (12) and the frame and is stretched and compressed in the direction of motion. ^ EFFECT: large working volume at small diametre of piston. ^ 11 cl, 5 dwg

Description

Technical field

The present invention relates to a linear compressor, especially for use in compressing refrigerant in a refrigeration apparatus, as well as to a drive unit for such a linear compressor for driving a piston.

State of the art

A linear compressor is known from US 6,596,032 B2, the drive unit of which comprises a frame and an oscillating body supported in the frame by means of a diaphragm spring. The oscillating body contains a permanent magnet, a piston rod rigidly connected to the permanent magnet, and a piston that is connected to the piston rod and moves reciprocally in the cylinder. The movement of the piston is created by an electromagnet located around the cylinder and interacting with a permanent magnet. A leaf diaphragm spring is fixed to the piston rod in the middle, and the outer edge of the diaphragm spring is connected to the crossbar that surrounds the cylinder, electromagnet and permanent magnet.

The diaphragm spring has the advantage over many other types of springs in that it is severely deformed across the direction of oscillation. The oscillating body therefore has only one degree of freedom, unlike, for example, an oscillating body suspended on a helical spring, which in principle has three degrees of freedom of translational motion and needs a direction when mobility should be limited to a single degree of freedom. In the case of an oscillating body supported by a diaphragm spring, this direction is not required. Therefore, the motion of such an oscillating body can be transformed with small friction losses, if necessary, into a strictly linearly directed motion of the piston in the compressor.

The oscillating body and the diaphragm spring form an oscillating system, the natural frequency of which is determined by the mass of the oscillating body and the diaphragm spring, as well as the stiffness of the diaphragm spring. The diaphragm spring allows only small amplitudes of vibrations, since each deviation of the oscillating body is associated with the expansion of the diaphragm spring. Due to the small amplitude of the oscillations, it is difficult to make the dead volume of the cylinder reliably small. However, the greater the dead volume, the worse the efficiency of the compressor. In addition, a small stroke forces the cylinder to be made with a diameter larger than the length in order to achieve a given cylinder working volume. Compaction with a larger circumference means higher costs.

Another possibility to increase the working volume of the cylinder is to make the diaphragm spring very stiff so as to increase the resonant frequency. The stiffer the diaphragm spring, the higher the risk that material fatigue will occur at a given vibration amplitude. That is, in order to avoid fatigue, the amplitude should be made the smaller, the stiffer the spring, and therefore, a satisfactory increase in the working volume of the cylinder is also not created.

Disclosure of invention

An object of the present invention is to provide a drive unit for a linear compressor with a frame and an oscillating body attached to the frame by means of a diaphragm spring, the diaphragm spring allowing a large stroke of the oscillating body without the risk of material fatigue. Thus, a large displacement can be achieved with a small piston diameter.

The problem is solved by the fact that in addition to the diaphragm spring, a spiral spring is fixed on the oscillating body and on the frame, made with the possibility of tension and compression in the direction of movement. Due to this, it is possible to separate the direction function of the oscillating body and the function of the temporary accumulation of kinetic energy of the oscillating body. A spiral spring is not very suitable for forcing an oscillating body to move along a precisely defined rectilinear path; however, it is not difficult to choose its dimensions in such a way that it supports both the desired amplitude of motion and the desired frequency of motion of the oscillating body without the risk of material fatigue. The diaphragm spring can have only a small thickness of the material in order to achieve the desired large amplitude of oscillation. Such a diaphragm spring, when it perceives only the function of temporary energy storage, allows only a low natural frequency of the oscillating body. However, due to the parallel connection of the two types of springs, all three requirements can be simultaneously fulfilled - the requirement of strict direction of the oscillating body, the requirement of large amplitude and the requirement of a high frequency of oscillations.

In the ideal case, the springs should apply only forces, but not torques, to the oscillating body. To this end, a spiral spring is located around an imaginary straight line along which the center of gravity of the oscillating body moves back and forth. Preferably, the straight line coincides with the longitudinal axis of the coil spring.

In order to prevent the case where the diaphragm spring applies torque, or to reduce the torque, the diaphragm spring preferably has an axis of symmetry that coincides with a straight line, or a plane of symmetry in which the straight line passes.

In order to direct the force from the spiral spring without torque to the oscillating body, it will be preferable if the end of the spiral spring acts on the peripheral part of the spring plate, at the midpoint of which the oscillating body is fixed.

In order to make the diaphragm spring easily deformable in the direction of movement, it preferably comprises a plurality of curved shoulders, one end of which is fixed to the frame and the other end is fixed to the oscillating body.

In order to improve the accuracy of the direction of the oscillating body along the straight line, at least two diaphragm springs are preferably provided, which are fixed to portions of the oscillating body at a distance in the direction of movement of the oscillations.

The subject of the invention is also a linear compressor with a working chamber, a piston reciprocating in the working chamber for compressing the working medium, and also with a drive unit, as described above, which is connected to the piston to create a reciprocating motion. In order to make such a linear compressor compact, it may be appropriate for the working chamber to be at least partially surrounded by a coil spring.

Brief Description of the Drawings

Other features and advantages of the invention result from the following description of embodiments with reference to the accompanying figures. They show the following.

Figure 1 is a perspective view of a linear compressor proposed by the invention.

Figure 2 - one of the two diaphragm springs of the linear compressor of figure 1.

Figure 3 is a schematic sectional view of a portion of a linear compressor along an imaginary straight line G.

4 is an alternative embodiment of the diaphragm spring of a linear compressor.

5 is another simplified embodiment of a diaphragm spring.

The implementation of the invention

The linear compressor frame 1 comprises a base 2, from which plate-shaped or rib-shaped protrusions 3, 4, 5 are spaced. Two diaphragm springs 6 of the type shown in FIG. 2 are screwed on the narrow sides of two opposing protrusions 3. The diaphragm springs 6 contain jumper 7 adjacent to the ends of the protrusions 3, the Z- or S-shaped spring arms 8 are spaced from their ends. The ends of the spring arms 8 remote from the jumper 7 collide with each other in the middle section 9 of the diaphragm spring 6, in which three holes 10, 11. An oscillating body 12 is secured between two diaphragm springs 6 with bolts or rivets not shown, which pass through the upper and lower holes 10 of the diaphragm springs 6. A hole 11 forms a passage for the piston rod 13, which passes between the oscillating body 12 and the compressor unit 14 carried by the protrusion 5.

In the cavity bounded by the protrusions 3 and the diaphragm springs 6, on both sides of the oscillating body 12, which is made of a permanent magnet, there are two electromagnets 15, configured to supply current to them to create two opposite magnetic fields between them. These magnetic fields deflect the oscillating body 12 from its equilibrium position shown in FIG. 1 along a straight line G passing through the center of gravity of the oscillating body 12, in one or the other direction.

The straight line G extends axially through the piston rod 13 and the compressor assembly 14, and at the same time it is the axis of symmetry of two spring plates 16, which are pressed by spiral springs 17 towards the outer sides of the two diaphragm springs 6. Figure 3 shows a longitudinal section of part of a linear compressor along these straight lines G. The spring plates 16 have, on the edge of their concave side facing away from the diaphragm springs 6, a rib along the circumference by means of which an adjacent to the spring plate is fixed in the radial direction the last turn of the coil spring 17. The opposite ends of the coil springs 17 are fixed by means of projections entering into the interior springs. One of the protrusions is a flat protrusion 18 on the plate 4 of the frame 1, the other protrusion 19 is part of the compressor housing 14.

The coil springs 17 are pre-compressed between the spring plates 16 and their protrusions 18 or 19 so that at any of the points of change in the direction of motion of the oscillating body 12, one of the coil springs 17 is not without voltage. The coil springs 17 therefore hold the spring plates 16 constantly pressed against the diaphragm springs 6 also when the compressor is in operation and the oscillating body oscillates. Therefore, a rigid connection between the spring plates 16 and the diaphragm springs 6 touching them is not required in order to constantly maintain contact between them. Since the force of the springs 17, distributed very evenly over the entire span of the spring plates 16, acts on the spring plates 16, it turns out that only a small torque that can contribute to the inclination of the axes of the spring plates relative to the straight line G. But even if such a torque occurred, then due to the lack of communication between the spring plates 16 and the diaphragm springs 6, he could not be transferred to the diaphragm springs 6. Due to the shape of the spring plates 16, which is narrowed in the direction of the diaphragm springs 6, they transmit force of the coil springs 17 in the diaphragm spring 6 is very close to the straight line G. Thus, even at an irregular distribution of forces resultant torque acting on the diaphragm spring 6 remains low. The diaphragm springs 6 and the oscillating body 12 held by them by means of the coil springs 17 are thus subject to essentially only forces oriented exactly in the direction of the straight line G, but not to any nominal torques that can initiate the center of gravity of the oscillating body 12 to move towards from line G.

Also, the high symmetry of the two diaphragm springs 6 helps to ensure that they accurately linearly guide the oscillating body 12.

The sectional view in FIG. 3 also shows the internal structure of the compressor assembly 14. In the inner chamber 20 of the compressor assembly 14, the piston 21 held by the piston rod 13 is reciprocated so that through the suction pipe 22, the refrigerant is sucked into the chamber 20 and the compressed refrigerant on the discharge nozzle 23. An annular chamber 24 is connected to the discharge nozzle 23, which cup-like passes around the chamber 20. In the separation wall 25, which touches the sides of the piston 21, between the chambers Ohm 20 and the annular chamber 24 there are many small passages 26 through which part of the compressed refrigerant can flow from the annular chamber 24 back to the chamber 20. The flowing back refrigerant forms a gas cushion between the separation wall 25 and the sides of the piston 21, which prevents direct the sliding contact between the piston 21 and the separation wall 25 and thus keeps the compressor assembly 14 at a low level. Thanks to the precisely rectilinear direction of the oscillating body 12, this is straightforward The direction is achieved by maintaining the diaphragm springs 6 and coil springs 17, a sufficiently small passage of gas in the passages 26 to create a gas cushion that reliably protects against slipping.

In order to mutually compensate for minor inaccuracies in the alignment of the drive unit and the compressor assembly, which otherwise could also lead to a piston 21 grouting on the wall 25, two elastically bent tapered sections 27 are made in the piston rod 13. A slight bend of these tapered sections 27 allows you to compensate for a slight shift between the straight line G, on which the center of gravity of the oscillating body 12 moves, and the longitudinal middle axis of the chamber 20, or to compensate for their slight non-parallelism.

Simplified embodiments of the diaphragm springs are shown in FIGS. 4 and 5. The spring 6 ′ of FIG. 4 corresponds to the substantially bisected diaphragm spring of FIG. 3, with only two S- or Z-shaped curved arms 8 that extend from jumpers 7 to the middle portion 9. In the case of the spring 6 ″ of FIG. 5, the curved shoulders are replaced by a straight shoulder 8 ″. Although its free end moves, strictly speaking, not exactly in a straight line, but in an arc of a circle, this deviation can be neglected when the amplitude of the oscillating body is limited so that the lateral component of the motion of the oscillating body is less than the lateral clearance of the piston.

Claims (11)

1. The drive unit for a linear compressor with a frame (1) and an oscillating body (12) connected to the frame (1) using at least one diaphragm spring (6) and guided for rectilinear reciprocating motion relative to the frame, characterized in that on the oscillating body (12) and the frame (1) a spiral spring (17) is fixed, made with the possibility of tension and compression in the direction of movement. 2. The drive unit according to claim 1, characterized in that the coil spring (17) passes around a straight line G, along which the center of gravity of the oscillating body (12) moves back and forth. 3. The drive unit according to claim 2, characterized in that the straight line (G) coincides with the longitudinal axis of the coil spring (17). 4. The drive unit according to claim 2 or 3, characterized in that the straight line (G) is the axis of symmetry or part of the plane of symmetry of the diaphragm spring (6). 5. The drive unit according to one of claims 1 to 3, characterized in that the end of the coil spring (17) acts on the peripheral part of the spring plate (16), the midpoint of which presses on the oscillating body (12). 6. The drive unit according to one of claims 1 to 3, characterized in that the diaphragm spring (6) contains many curved shoulders (8), one end of which is fixed to the frame (1), and the other end (9) is fixed to the oscillating body (12). 7. The drive unit according to claim 6, characterized in that each shoulder (8) contains two sections, curved in different directions. 8. The drive unit according to one of claims 1 to 3, characterized in that it contains at least one second diaphragm spring (6) and that the first and second diaphragm springs (6) are fixed on sections of the oscillating body (12) located on distance in the direction of motion of the vibrations. 9. A linear compressor with a working chamber (20), a piston (21), moving reciprocally in the working chamber (20) to compress the working medium, as well as with the drive unit declared in one of the previous paragraphs connected to the piston (21) for creating reciprocating motion. 10. The linear compressor according to claim 9, characterized in that the piston rod (13) passes between the piston (21) and the oscillating body (12) on a straight line (G). 11. A linear compressor according to claim 9 or 10, characterized in that the working chamber (20) is at least partially surrounded by a coil spring (17).

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