KR20050038708A - Linear compressor - Google Patents

Abstract

The present invention relates to a linear compressor capable of reducing noise generated in the process of compressing and suctioning refrigerant into a compression chamber.

The linear compressor according to the present invention includes a linear motor including a case forming an exterior, a stator installed in the case, and a linear motor including a mover that linearly reciprocates and interacts with the stator, and a cylinder forming a compression chamber in which refrigerant is compressed. And a piston installed in the compression chamber so as to move forward and backward and linearly reciprocated by the mover and compressing the refrigerant in the compression chamber, and a refrigerant guide provided inside the piston to allow the refrigerant to flow through the piston to the compression chamber. In one embodiment, since a noise reduction device for reducing noise is provided between the compression chamber and the suction pipe, the noise generated during the suction, compression, and discharge of the refrigerant is attenuated and reduced by the noise reduction device.

Description

Linear Compressor {LINEAR COMPRESSOR}

The present invention relates to a linear compressor, and more particularly to a linear compressor having a noise reduction device for reducing noise.

In general, the linear compressor is applied to a product to which a refrigeration cycle such as a refrigerator or an air conditioner is applied, and is a device that sucks and discharges a refrigerant.

Such a conventional linear compressor has an external appearance and includes a case in which a suction pipe through which refrigerant is sucked is installed on one side, a driving device installed in the case to generate power, and a compression device receiving and compressing a fluid by receiving power from the driving device. .

The compression device includes a cylinder provided with a compression chamber therein, and a piston for linearly reciprocating the cylinder, and the driving device includes an inner stator and an outer stator for forming a magnetic field by receiving AC power, and an outer stator and an inner stator. And a mover disposed between and having a magnet to linearly reciprocate and interact with a magnetic field formed in the outer stator and the inner stator and causing the piston to reciprocate in the compression chamber.

Therefore, when the power is applied, the mover moves forward and backward between the outer stator and the inner stator, so that the piston moves forward and backward in the compression chamber and compresses the refrigerant.

By the way, in such a linear compressor, the piston is provided with a refrigerant guide portion so that the refrigerant sucked through the suction pipe can be guided into the compression chamber through the inside of the piston, the noise generated when the refrigerant is compressed and suction guides the refrigerant There is a problem that is transmitted to the outside through wealth.

The present invention is to solve such a problem, it is an object of the present invention to provide a linear compressor that can reduce the noise generated in the process of the refrigerant is sucked, compressed and discharged.

The linear compressor according to the present invention for achieving the above object, the linear motor comprising a case forming an appearance, a stator fixed in the case and a mover that linearly reciprocates and interacts with the stator, A cylinder forming a compression chamber in which compression is performed, a piston installed in the compression chamber so as to move forward and backward and linearly reciprocated by the mover to compress the refrigerant in the compression chamber, and a refrigerant penetrating the inside of the piston; A refrigerant guide unit provided inside the piston to flow toward the compression chamber, and a noise reduction device disposed between the compression chamber and the suction pipe to reduce noise generated during the suction, compression, and discharge of the refrigerant; Noise reduction device is an outer tube formed in a cylindrical shape, the outer tube inside the An inner tube disposed to be spaced apart from the outer tube to allow the space between the outer tube to operate as a resonance chamber, and a through-hole provided in the middle of the inner tube so that the space inside the resonance chamber and the inner tube communicate with each other. It features.

In addition, the inner tube is characterized in that it comprises a first inner tube and a second inner tube is connected to both ends of the outer tube and the corresponding ends are spaced from each other to form the through hole.

In addition, the case is provided with a suction tube for the refrigerant suction and discharge tube for discharging the refrigerant, the noise reduction device is disposed between the suction tube and the refrigerant guide portion and the refrigerant introduced through the suction tube is guided to the refrigerant guide portion The noise transmitted from the refrigerant guide portion to the suction pipe side is attenuated.

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

As shown in FIG. 1, the linear compressor according to the present invention has an outer shape and includes a case 10 in which a suction pipe 11 into which a refrigerant is introduced and a discharge tube (not shown) through which the refrigerant is discharged are installed, and in the case 10. A compression device 20 installed to suck and discharge a fluid, a drive device 30 to generate power by receiving power from the outside to drive the compression device 20, and to suck, compress, and discharge the refrigerant. It includes a noise reduction device 40 for reducing the noise generated when.

The compression device 20 is provided with a cylinder 21 forming a compression chamber 21a through which the refrigerant is compressed, and installed in the compression chamber 21a so as to move forward and backward, and linearly reciprocate and have a refrigerant in the compression chamber 21a. The piston 22 for compressing the pressure, the cylinder block 23 is formed in an annular shape so that the cylinder 21 protrudes toward the suction pipe 11 side, and the other side of the cylinder 21 is installed in the compression chamber ( Cylinder head 24 for guiding the discharge of the refrigerant compressed in 21a). In this embodiment, for convenience, the side on which the cylinder head 24 of the cylinder 21 is installed is called the discharge side of the cylinder 21, and the opposite side is called the suction side of the cylinder 21.

The piston 22 has a refrigerant guide part 22a formed therein to allow the refrigerant introduced through the suction pipe 11 to flow therein, and at the end of the piston 22, the refrigerant guide part 22a passes through. Inlet 22b for allowing the refrigerant to flow into the compression chamber 21a, and elastically deformed to allow the refrigerant to enter the compression chamber 21a when the pressure inside the compression chamber 21a is low. The suction plate 22c of the leaf | plate spring type which opens | releases is provided.

The cylinder head 24 has a discharge plate 24a for opening and closing the discharge side of the cylinder 21 therein and an opening / closing spring 24b having one side supported inside the cylinder head 24 and the other side supported by the discharge plate 24a. And a discharge port 24c communicating with the discharge tube on one side thereof. When the inside of the compression chamber 21a is below a certain pressure, the discharge plate 24a closes the discharge side of the cylinder 21, and then the compression chamber When the pressure in the 21a rises above a certain level, the opening / closing spring 24b elastically deforms and the discharge side of the cylinder 21 is opened to allow the refrigerant to move from the compression chamber 21a to the cylinder head 24 side. .

The drive device 30 is disposed outside the cylinder 21 and is installed to surround the outside of the mover 31 and the mover 31 linearly moving together with the piston 22. A linear motor having an outer stator 32a for generating a magnetic field and an inner stator 32b disposed on the outer circumference of the cylinder 21 so as to maintain a predetermined distance from the outer stator 32a.

The mover 31 has a cylindrical shape in which a piston 22 is connected to a central portion, and a magnet 31a is installed at a skirt portion of the mover 31, and the magnet 31a is formed with an outer stator 32a. The reciprocating motion is arranged between the inner stator 32b and reciprocates between the outer stator 32a and the inner stator 32b by a magnetic field generated between the outer stator 32a and the inner stator 32b according to the application of power. And causes the piston 22 to reciprocate linearly.

At this time, in order to allow the piston 22 to elastically support the reciprocating motion, a support member 33 on which the other end of the piston 22 is elastically supported at one end of the suction pipe 11 side of the cylinder block 23, and one end thereof is A first resonant spring 34a which is supported by the cylinder block 23 and the other end is supported by the mover 31 so that the mover 31 is elastically supported by the cylinder block 23, and one end of the mover 31; The second resonant spring (34b) is supported on the other end is supported by the support member 33 is included. Therefore, when the AC power is applied and the mover and the piston move forward and backward, their reciprocating force is doubled by the first resonance spring 34a and the second resonance spring 34b, so that the cylinder block 23 and the support member 33 are moved. It will be easier to reciprocate between.

As shown in FIG. 2, the noise reduction device 40 includes an outer tube 41 formed in a cylindrical shape and an inner tube spaced apart from the outer tube 41 by a predetermined distance within the outer tube 41. 42a and 42b are provided so that the space between the inner tubes 42a and 42b and the outer tube 41 acts as a resonance chamber 43 for resonating and canceling sound waves of noise. 42a and 42b include a first inner tube 42a and a second inner tube 42b having one side connected to both ends of the outer tube 41, respectively, and include a first inner tube 42a and a second inner tube. Corresponding ends of the pipe 42b are spaced apart from each other to form a through hole 42c that allows sound waves of noise generated during suction, compression, and discharge of the refrigerant to flow into the resonance chamber 43.

That is, some of the sound waves of the noise generated during the suction, compression, and discharge of the refrigerant into the compression chamber 21a flow into the resonance chamber 43 through the through hole 42c, and the inside of the resonance chamber 43 penetrates. Except for the ball 42c, all are closed, so sound waves are generated by the repulsive force against the incoming sound waves. As such, the sound waves generated in the resonance chamber 43 by the repulsive force have a phase difference of 180 degrees with the same frequency as the sound waves flowing into the resonance chamber 43 through the through hole 42c, and are canceled with each other, thereby reducing noise. Will be able to represent.

In this embodiment, the end portions corresponding to each other of the first inner tube 42a and the second inner tube 42b are spaced apart from each other to form the through holes 42c. However, the present invention is not limited thereto. It is also possible to configure only the inner tube and to form a through hole of a predetermined size in the middle of the inner tube.

The following describes the operation and effect of the linear compressor according to the present invention configured as described above.

First, when AC power is applied to the coil of the outer stator 32a, when a magnetic field is formed, the movable element 31 having the magnet 31a is linearly reciprocated by an electromagnetic interaction with the magnetic field generated by the outer stator 32a. In addition, the piston 22 connected to the mover 31 linearly reciprocates in the compression chamber 21a. At this time, the reciprocating motion of the piston 22 and the mover is easily achieved by doubling the reciprocating force by the first resonant spring 34a and the second resonant spring 34b.

When the piston 22 moves to the discharge side of the cylinder 21 according to the reciprocating motion, the refrigerant in the compression chamber 21a is compressed, and when the pressure inside the compression chamber 21a becomes higher than or equal to a certain level, the opening / closing spring 24b is elastic. As the discharge plate 24a is deformed and the discharge side of the cylinder 21 is opened, the refrigerant moves from the compression chamber 21a to the cylinder head 24 and is discharged through the discharge port 24c. At this time, since the suction port 22b is kept closed by the suction plate 22c provided in the piston 22, the refrigerant is prevented from flowing to the suction port 22b side.

Subsequently, when the piston 22 moves to the suction side of the cylinder 21, the pressure in the compression chamber 21a is lowered. As a result, when the pressure in the compression chamber 21a becomes below a certain level, the suction plate 22c becomes elastic. The suction port 22b is opened while being deformed. At this time, since the inside of the compression chamber 21a is in a low pressure state, the refrigerant flows in through the open suction port 22b. At this time, the discharge side of the cylinder 21 is kept closed by the discharge plate 24a, so that the coolant is prevented from flowing to the discharge port 24c side.

At this time, the noise generated while the refrigerant is sucked into the compression chamber 21a is transmitted to the suction pipe 11 side through the refrigerant guide part 22a of the piston 22, and the noise is transferred to the suction pipe 11 side. When some of the sound waves of the noise is delivered to the resonance chamber 43 through the through portion provided in the noise reduction device 40 in the process of resonating chamber 43, except for the through hole 42c is closed because the resonance chamber (43) Inside, sound waves are generated by the repulsive force, and the sound waves generated in the resonance chamber 43 come out through the through holes 42c and are attenuated by mutual interference with the sound waves introduced through the through holes 42c.

As described above in detail, the linear compressor according to the present invention is provided with a noise reduction device between the suction pipe and the compression chamber so that the noise generated during the suction, compression and discharge of the refrigerant is attenuated and reduced by the noise reduction device. It has an effect.

1 is a cross-sectional view showing the overall configuration of a linear compressor according to the present invention.

FIG. 2 is an enlarged view of part II of FIG. 1.

Explanation of symbols on the main parts of the drawings

10: case 11: suction tube

20: compression apparatus 21: cylinder

22: piston 23: cylinder block

24: cylinder head 30: drive device

31: mover 32a, 32b: stator

40: noise reduction device 41: outer tube

42a, 42b: inner tube 42c: through hole

43: resonance room

Claims (3)

A linear motor including a case forming an external appearance, a stator fixedly installed in the case, and a linear actuator reciprocating linearly with the stator, a cylinder forming a compression chamber in which refrigerant is compressed, and a compression chamber in the compression chamber. A piston that is installed to move forward and backward and linearly reciprocates by the mover and compresses the refrigerant in the compression chamber, and a refrigerant guide part provided inside the piston to allow the refrigerant to flow through the piston to the compression chamber side. And a noise reduction device disposed between the compression chamber and the suction pipe to reduce noise generated during the suction, compression, and discharge of the refrigerant. The noise reduction device includes an outer tube formed in a cylindrical shape, an inner tube disposed to be spaced apart from the outer tube inside the outer tube so that a space between the outer tube and the inner tube operates as a resonance chamber, and a middle tube of the inner tube. And a through hole through which the resonance chamber and the space inside the inner tube communicate with each other. The method of claim 1, The inner tube may include a first inner tube and a second inner tube each having one end connected to both ends of the outer tube and corresponding ends spaced apart from each other to form the through hole. The method of claim 1, The case is provided with a suction tube for suction of the refrigerant and a discharge tube for discharging the refrigerant, and the noise reduction device is disposed between the suction tube and the refrigerant guide part to guide the refrigerant introduced through the suction tube to the refrigerant guide part. And a noise transmitted from the refrigerant guide portion to the suction pipe side is attenuated.