KR19980062597U - Linear compressor - Google Patents

Abstract

The present invention relates to a linear compressor. The linear compressor of the present invention includes a cylinder provided with a compression chamber, a piston linearly reciprocating inside the cylinder, a piston rod extending to one side from the piston, and a leaf spring installed at the lower end of the piston rod. And a housing coupled to the piston rod to electromagnetically drive the piston to drive up and down. In addition, a coil spring having one end supported by a piston and the other end supported by a housing is installed in the piston rod, and a cylinder is provided with a partition member for partitioning the coil spring into one side and the other side. In the other part, a separate elastic restoring force is generated.

Description

Linear compressor

The present invention relates to a linear compressor, and more particularly to a spring of the linear compressor improved spring installed to help compress the refrigerant of the piston.

Generally, a compressor used in an air conditioner or a refrigerator is a device that repeatedly performs compression, expansion, and evaporation processes of a refrigerant, thereby generating harmonic air in a refrigeration cycle.

Among these compressors, a linear compressor includes a linear motor driven by an interaction caused by a change in the direction of a magnetic flux with a magnet to linearly reciprocate the piston, which is a refrigerant in the sealed container 10 as shown in FIG. Is divided into a compression unit for suction, compression and discharge, and a driving unit for generating a compression force.

The compression section includes a piston 11 and a cylinder 12 on which the piston 11 is built, and the cylinder 12 is provided with a cylinder head 13 having a suction port 13a and a discharge port 13b.

The driving unit is provided with an internal stator 14 and an external stator 15, and a coil 16 and a magnet 17 for generating a magnetic field are provided between the stators 14 and 15. And a cylindrical housing 18 for fixing the magnet 17 is provided, the housing 18 is a coupling shaft 19 formed in the lower portion of the piston 11 penetrates the bottom surface of the housing 18 to bolt The leaf spring 20 is coupled to the end of the coupling shaft (19).

In the conventional linear compressor configured as described above, the permanent magnet 17 moves up and down by the coil 16 magnetized in the radial direction by the application of an external power source, and the power supplied is alternated with a constant supply frequency. At this time, in order to amplify the excitation force generated by the permanent magnet 17 and the coil 16, the resonance frequency of the leaf spring 20 is substantially matched with the power frequency supplied. With the increased driving force due to this resonance, the piston 11 sucks, compresses, and discharges the refrigerant introduced into the cylinder 12.

In this operation, reducing the thickness of the leaf spring 20 to maintain the amplitude of the piston 11 increases the reliability of the spring, but the system is out of the resonance zone, thereby reducing the efficiency of the compressor, and also the thickness of the spring 20. Since the decrease in the radial stiffness has a problem that the driving loss and wear caused by friction between the piston 11 and the cylinder 12 occurs.

The present invention is to solve the above problems, the purpose of the present invention is to increase the reliability of the spring, improve the rigidity of the spring by a separate device that can be manufactured and mounted relatively easily while improving the manufacturability, cylinder and piston It is to provide a linear compressor to reduce friction.

1 is a cross-sectional view showing a conventional linear compressor.

2 is a cross-sectional view showing a linear compressor according to the present invention.

3 is an operating state diagram showing the suction drive of the linear compressor according to the present invention.

Figure 4 is an operating state diagram showing the compression drive of the linear compressor according to the present invention.

* Description of Signs of Main Parts

50 ... Airtight container 52 ... Cylinder

53 ... piston 54 ... cylinder head

55,56 Stator 58 Permanent magnet

61 ... leaf spring 62 ... coil spring

63.Compartment member 65 ... Bearing

In order to achieve the above object, the present invention provides a cylinder provided with a compression chamber, a piston reciprocating linearly inside the cylinder, a piston rod extending to one side from the piston, and coupled to the piston rod, so that the piston is driven up and down. In a hermetic compressor having a housing driven by a coil, the piston rod is provided with a coil spring having one end supported by the piston and the other end supported by the housing, and the cylinder partitioning the coil spring to one side and the other side. A member is installed so that a separate elastic restoring force is generated at one side and the other side of the coil spring by using the partition member as a separating point.

Hereinafter, one preferred embodiment according to the present invention will be described in detail with reference to the drawings.

As shown in FIG. 2, the linear compressor according to the present invention is provided with a sealed container 50 in which an upper container 50a and a lower container 50b are combined, and the sealed container 50 sucks and compresses a refrigerant to be discharged. A compression unit and a driving unit for driving electromagnetically to generate a compression force is provided, and a support spring 51 for supporting the entire system consisting of the driving unit and the compression unit in the sealed container 50 is provided.

The compression unit includes a cylinder 52 having a compression chamber 67 formed therein for compressing the refrigerant therein and a piston 53 linearly reciprocating in the cylinder 52. A refrigerant inlet is provided at an upper opening of the cylinder 52. A cylinder head 54 provided with a 54a and a discharge port 54b is provided to guide the suction and discharge of the refrigerant. Each suction port 54a and the discharge port 54b are provided with a suction valve 54c and a discharge valve 54d. On the other hand, the piston 53 is composed of a piston head 53a and a piston rod 53b.

The drive unit is provided with an internal stator 55 and an external stator 56, and a coil 57 and a magnet 58 for generating a magnetic field are provided between the respective stators 55 and 56. In addition, a cylindrical housing 59 for fixing the magnet 58 is provided, and a piston rod 53b penetrates through the bottom surface of the housing 59 to be coupled to the bolt 60. The leaf spring 61 is bolted to the lower end of the piston rod 53b, and a coil spring 62 is provided between the bottom surface of the housing 59 and the piston head 53a. The coil spring 62 is supported so that the upper end is supported by the head of the piston 53, the lower end is supported by the housing 59, and is partitioned by a partition member 63 to be described later in the middle. The partition member 63 is installed so that the operating part by the elastic restoring force of the coil spring 62 is divided into upper and lower sides 62a and 62b, and the coupling end has a bolt 64 at the lower end of the cylinder 52. The free end is extended inwardly of the cylinder 52 and vertically bent inward at the intermediate compartment point. Accordingly, the free end of the partition member 63 is partially inserted into the middle portion of the coil spring 62 so that the operating portion of the coil spring 62 is divided up and down. A support member 68 is installed between the outer end of the cylinder 52 to which the leaf spring 61 is coupled, that is, the lower side of the housing 59 and the upper side of the leaf spring 61. The bearing 65 provided with the ball bearing etc. is provided in the part which the piston rod 53b penetrates and abuts, and the piston rod 53b is installed penetrating this bearing 65. As shown in FIG.

The operation of the linear compressor of the present invention configured as described above with reference to FIGS. 3 and 4, the permanent magnet 58 is moved up and down by the coil 57 magnetized in the radial direction by the application of an external power source. The power supplied is alternating with a constant supply frequency. To amplify the excitation force generated by the permanent magnets 58 and the coils 57, the resonance frequency of the leaf spring 61 is substantially matched with the supply frequency supplied. Will cause. Due to the increased driving force due to this resonance, the piston 53 more strongly sucks, compresses, and discharges the refrigerant introduced into the cylinder 52.

First, as shown in FIG. 3, the permanent magnet 58 and the housing 59 move downward by the electromagnetic force during the suction driving. At this time, the piston 53 coupled to the housing 59 is also moved downward, so that the refrigerant flows into the compression chamber 67 through the suction port 54a. The coil spring 62 has the upper portion 62a contracted during the suction driving, and the leaf spring 61 partially expands downward.

In the compression and discharge driving of FIG. 4, the direction of the magnetic flux is reversed, and the housing 59 and the piston 53 are driven upward. At this time, the compression portions of the coil spring 62 and the leaf spring 61 are compressed. While the restoring operation is added to the piston 53, this restoring force is compression-driven. At this time, the lower portion 62b of the coil spring 62 is contracted in contrast to the upper portion 62a which is relatively restoring, and the leaf spring 61 expands to the upper portion. The coil spring 62 and the leaf spring 61 is restored to help drive the piston 53.

In the linear spring of the present invention as described above, the spring constant value required by the conventional plate spring is k, and the spring constant value of each part of the coil spring 62 of the present invention is k ₂ . The constant value of the resonant leaf spring required in the present invention is k-2k ₂ . Therefore, the resonant leaf spring 61 of the present invention can be designed with a constant value as low as 2k ₂ as compared with the prior art, thereby reducing the thickness of the leaf spring 61 is expensive and difficult to manufacture. When the thickness of the leaf spring 61 is reduced in this way, the durability limit of the leaf spring 61 is increased, so that the reliability of the leaf spring 61 is greatly improved. In addition, the bearing 65 used in the present invention has a reduced radial stiffness of the reduced leaf spring 61 so that the piston 53 moves away from the vertical reciprocating motion and friction with the inner surface of the cylinder 52 causes wear. To complement it.

The linear compressor of the present invention as described above can make the design of the leaf spring easier by dividing the stress applied to the leaf spring from the coil spring by attaching the spring of the conventional compressor installed with one resonant leaf spring together with the coil spring. At the same time, the thickness of the leaf spring can also be reduced, thereby improving the driving efficiency of the compressor.

Claims (4)

In a hermetic compressor having a cylinder provided with a compression chamber, a piston for linear reciprocating movement inside the cylinder, a piston rod extending to one side from the piston, and a housing coupled to the piston rod to electromagnetically drive the piston up and down. In The piston rod is provided with a coil spring having one end supported by the piston and the other end supported by the housing. The cylinder is provided with a partition member for partitioning the coil spring into one side and the other side is a hermetic compressor characterized in that a separate elastic restoring force is generated at one side and the other side of the coil spring by the partition member. The hermetic compressor of claim 1, wherein a leaf spring is installed at an end of the piston rod. The hermetic compressor according to claim 1, wherein the cylinder includes a support member through which the piston rod is installed so as to maintain concentricity of the piston rod. 4. The hermetic compressor according to claim 3, wherein a bearing is installed in the support member through which the piston rod penetrates.