KR100591315B1 - Compressor - Google Patents

Abstract

The present invention relates to a compressor for minimizing noise and vibration generation, comprising: a fixed cell; A vibrating part supported by the fixed cell so as to vibrate and suck and cool the refrigerant; An excitation point connected to the discharge part of the vibrating part and a fixing point connected to the fixed cell, the loop pipe being positioned on an axis of motion of the vibration part or parallel to an axis of motion of the vibration part; do.

Compressor, fixed cell, vibrator, loop pipe, excitation point, fixed point

Description

Compressor

1 is a perspective view showing the inside of a first embodiment of a compressor according to the present invention;

2 is a sectional view showing a first embodiment of a compressor according to the present invention;

3 is a perspective view showing the inside of a second embodiment of the compressor according to the present invention;

<Explanation of symbols on main parts of the drawings>

50: fixed cell 52: lower cell

53: suction pipe 54: upper cell

60: vibration part 62: cylinder

64: cylinder block 65: first damper

66: refrigerant suction 68: back cover

70: linear motor 72: coil

74: bobbin 76: outer stator

78: inner stator 80: magnet

82: magnet frame 83: bent portion

84: piston 86: protrusion

88: suction hole 90: first spring

92: second spring 94: suction valve

110: discharge part 112: discharge valve

114: discharge spring 116: discharge hole

118: inner discharge cover 120: discharge pipe

122: outer discharge cover 130: loop pipe

140: loop pipe A: excitation point

B: fixed point C: axis of motion

D: parallel axis of the axis of motion

The present invention relates to a compressor, and more particularly to a compressor in which the excitation point and the fixed point of the loop pipe are located coincident with or parallel to the axis of motion of the vibrator.

In general, a compressor is a mechanical device that compresses gas and increases its pressure, and can be divided into two types, a positive displacement type and a dynamic type.

A typical example of the displacement compressor is a reciprocating piston compressor such as a linear compressor. The compressor is a cycle in which air is drawn in and compressed and discharged according to the reciprocating motion of the piston in the cylinder and opening and closing of the valve. consist of. This form is generally used when high pressures are required rather than flow rates.

A dynamic compressor is a device that rotates a rotor at a very high speed, and raises the pressure of the gas by the momentum due to the large flow velocity obtained at this time, and is often used when a large flow rate is required.

Dynamic compressors can be subdivided into centrifugal and axial flows and range in size and use from compressors for large industrial compressors and gas turbine engines to compressors for passenger car turbochargers. . In addition, there are many other forms, such as a screw compressor for rotating the gas in a space where two screws are engaged, and a scroll compressor for compressing the gas between two spiral grooves by rotation.

The compressor includes a vibration unit including a motor generating a driving force and a compression unit compressing gas by the motor so as to be vibrated inside the fixed cell.

In the compressor, the gas compressed in the compression unit passes through a loop pipe and is discharged to the outside of the fixed cell.

One end of the loop pipe is connected to the discharging part of the vibrating part, the other end is connected to the fixed cell, and a mass body is provided at a predetermined position to partially reduce the vibration and noise generated when the compressed gas is discharged. It is arranged to be wound or bent.

However, in the compressor according to the prior art, the extension line connecting the excitation point at which the loop pipe is connected to the discharge part of the vibrator and the fixing point at which the loop pipe is connected to the fixed cell is disposed to be inclined at a predetermined angle or perpendicular to the motion axis of the true eastern part. When the vibration part vibrates, a moment is generated at the fixed point, causing noise and vibration.

The present invention has been made to solve the above problems of the prior art, to provide a compressor that minimizes the generation of noise and vibration by making the excitation point and the fixed point of the loop pipe coincident with or parallel to the axis of motion of the vibrator. There is a purpose.

Compressor according to the present invention for solving the above problems is fixed cell; A vibrating part which is supported to be vibrated inside the fixed cell, and sucks and then compresses and discharges the refrigerant; In order to guide the refrigerant discharged from the vibrating unit to the outside of the fixed cell, one end is connected to the discharge unit of the vibrating unit and fixed to the fixed cell and connected to the discharge unit, and a fixed point fixed to the fixed cell. And a loop pipe positioned on an axis parallel to the axis of motion of the vibrator.

In addition, the compressor according to the present invention includes a fixed cell; A vibrating part which is supported to be vibrated inside the fixed cell, and sucks and then compresses and discharges the refrigerant; In order to guide the refrigerant discharged from the vibrating unit to the outside of the fixed cell, one end is connected to the discharge unit of the vibrating unit and fixed to the fixed cell and connected to the discharge unit, and a fixed point fixed to the fixed cell. And a loop pipe positioned on an axis parallel to the axis of motion of the vibrator.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a first embodiment of the compressor according to the present invention, Figure 2 is a cross-sectional view showing a first embodiment of the compressor according to the present invention.

1 and 2, the compressor according to the present embodiment includes a fixed cell 50; It is configured to include a vibrating unit 60 is supported by the fixed cell 50 so as to vibrate to suck the refrigerant and then compress and discharge the refrigerant.

The fixed cell 50 includes a lower cell 52 having an open upper surface, and an upper cell 54 covering an upper surface of the lower cell 52 to be sealed inside.

One of the lower cell 52 and the upper cover 54 is equipped with a suction connection pipe 53 so that refrigerant is sucked into the fixed cell 50.

The vibrator 60 includes a cylinder block 64 having a cylinder 62, a back cover 68 having a refrigerant suction path 66, and a space between the cylinder block 64 and the back cover 68. It consists of a linear motor 70 of.

As the cylinder block 64 is mounted on the first damper 65 mounted on one side of the lower cell 52, the cylinder block 64 is supported to be buffered in the vertical direction or the front-back direction, and the cylinder 62 is moved in the front-rear direction. It is placed long.

As the back cover 68 is mounted on the second damper 69 mounted on the other side of the lower cell 52, the back cover 68 is supported to be buffered vertically or vertically.

The linear motor 70 is fixed to the cylinder block and the back cover by using fastening means such as fastening bolts or fixing rings.

The linear motor 70 includes a coil 72, a bobbin 74 on which the coil 72 is wound, an outer core 76 made of a laminate surrounding the bobbin 74, and the outer core 76. ) And a magnet 80 positioned between the outer core 76 and the inner core 78 so as to linearly reciprocate by the electromagnetic force formed in the coil 72 and the inner core 78 of the laminate disposed to have a predetermined gap. ) And a magnet frame 82 equipped with the magnet 132 to linearly reciprocate with the magnet 80.

The magnet frame 82 is formed in a cylindrical shape and disposed long in the front-back direction, and a bent portion 83 bent inward in the radial direction at one end thereof has a hollow disc shape.

The bent portion 83 is connected to the piston 84 which is linearly reciprocated with the magnet frame 82.

The piston 84 is a cylindrical body disposed long in the front and rear direction, the projection 86 coupled to the bent portion 83 protrudes radially outward, the suction hole 88 is formed long in the longitudinal direction It is made of a diameter smaller than the inner core 78 and the cylinder 62.

The piston 84 is carried forward and backward by a first spring 90 between one surface of the protrusion 86 and the cylinder block 64, and between the other surface of the protrusion 86 and the back cover 68. It is supported by the second spring 92 in the front-rear direction.

The piston 84 is equipped with a suction valve 94 for opening and closing the suction hole 88 at the end inserted into the cylinder 62.

The suction valve 94 is made of an elastic material so that one side is tightly coupled to the piston 84 by a fastening bolt or permanent magnet, and a portion facing the suction hole 88 can be bent by the pressure of the refrigerant. A separate elastic groove is formed.

The vibrator 60 further includes a discharge unit 110 for discharging the compressed refrigerant.

The discharge part 110 is disposed to face the intake valve 100 and forms a compression chamber together with the cylinder 62 and the piston 84, and the discharge valve 112 is compressed. An inner discharge in which a discharge spring 114 for holding the discharge valve 112 to open the cylinder 62 by a pressure in a chamber, and a discharge discharge hole 116 are formed on one side with the discharge spring 114 embedded therein; An outer discharge cover disposed to be spaced apart from the inner discharge cover 118 and having a discharge pipe 120 for discharging a refrigerant at one side thereof so as to reduce noise in a space between the cover 118 and the inner discharge cover 118 ( 122).

The discharge unit 110, in particular, the discharge pipe 120 is connected to the loop pipe 130 for guiding the compressed refrigerant to the outside of the fixed cell 50.

The loop pipe 130 is disposed so that a mass is provided at a predetermined position and a portion thereof is wound or bent in a circle to reduce vibration and noise generated when the compressed refrigerant is discharged.

One end of the roof pipe 130 is fixed to the discharge pipe 120, and the other end of the roof pipe 130 is fixed to any one of the lower cell 52 and the upper cell 54.

The loop pipe 130 has an excitation point A connected to the discharge part 110 of the vibrator 60 and a fixed point B connected to the fixed cell 50 of the vibrator 60. It is located on the movement axis (C).

Looking at the operation of the present invention configured as described above are as follows.

First, when a voltage is applied to the coil 72, a magnetic field is formed around the coil 72, the magnet 80 is retracted by interaction with the magnetic field, the magnet frame 82 is the The piston 84 is advanced and retracted into the cylinder 62 while being retracted with the magnet 80.

In this case, the suction valve 94 and the discharge valve 112 are opened and closed by the flow of the gas refrigerant according to the linear reciprocating motion of the piston 84, the gas refrigerant is introduced into the fixed cell 50. After passing through the refrigerant suction path 66 of the back cover 68 and the suction hole 88 of the piston 84 in order to be sucked into the compression chamber.

The refrigerant sucked into the compression chamber is compressed by the piston 84, and then passes through the discharge hole 116 and the discharge pipe 120 of the discharge valve 112, the inner discharge cover 118, and the loop pipe ( It is introduced into the interior of the 130, and passes through the loop pipe 130 and is discharged to the outside of the fixed cell 50.

On the other hand, when the piston 84 is moved back and forth the vibration portion 60 is generated in the direction in which the piston 84 is advanced, the loop pipe 130 has an excitation point (A) and a fixed point (B) ) Is located on the movement axis (C) of the vibration unit 60, the moment is not generated at the fixed point (B), the noise and vibration transmitted to the outside from the compressor is minimized.

3 is a perspective view showing a second embodiment of the compressor according to the present invention.

The compressor according to the present embodiment includes a fixed cell 50; A vibrating part 60 supported by the fixed cell so as to vibrate to suck the refrigerant, and to compress and discharge the refrigerant; An excitation point connected to the discharge part of the vibrating part and a fixing point connected to the fixed cell include a loop pipe 140 positioned on an axis parallel to the axis of motion of the vibrating part, Since the structure and operation of the eastern part 60 are the same as in the first embodiment of the present invention, the same reference numerals are used, and the same description is omitted.

In the compressor according to the present embodiment, since the excitation point A and the fixing point B of the loop pipe 140 are located on the axis D that is flat with the movement axis C of the vibration unit 60. The moment is not generated in the fixing point (B) of the loop pipe 140, the noise and vibration transmitted to the outside from the compressor is minimized.

The compressor according to the present invention configured as described above includes a loop pipe having an excitation point connected to the discharge part of the vibrating part and a fixing point connected to the fixed cell located on the axis of motion of the vibrating part or on an axis parallel to the axis of motion. Since there is no moment of the fixed point that can be generated during the vibration of the vibrating unit, there is an advantage that the vibration and noise transmitted to the outside can be minimized.

Claims (2)

A fixed cell; A vibrating part that is supported to be vibrated in the fixed cell and sucks the refrigerant and compresses and discharges the refrigerant; In order to guide the refrigerant discharged from the vibrating unit to the outside of the fixed cell, one end is connected to the discharge unit of the vibrating unit and fixed to the fixed cell and connected to the discharge unit, and a fixed point fixed to the fixed cell. Compressor comprising a loop pipe located on the axis of motion of the vibrator. A fixed cell; A vibrating part which is supported to be vibrated inside the fixed cell, and sucks and then compresses and discharges the refrigerant; In order to guide the refrigerant discharged from the vibrating unit to the outside of the fixed cell, one end is connected to the discharge unit of the vibrating unit and fixed to the fixed cell and connected to the discharge unit, and a fixed point fixed to the fixed cell. And a loop pipe positioned on an axis parallel to the axis of motion of the vibrator.

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