KR20080062615A - Compressor and control method of the same and refrigerator having the same - Google Patents

Abstract

A compressor, a control method thereof, and a refrigerator having the same are provided to minimize the vibration transmitted from the compressor to the outside and to minimize the number of required component parts, by using a vibration absorber for additional fluid compression in addition to vibration absorbing. A compressor includes a linear compression part(100), a vibration absorber(210) connected to the linear compression part for absorbing the vibration of the linear compression part, and an absorber cylinder(220) in which the vibration absorber reciprocates straightly for compressing fluid during the vibration absorber vibrates, thereby serving as an additional compression part.

Description

Compressor and Control method of the same and Refrigerator having the same

1 is a longitudinal sectional view of a compressor having a plurality of compression units according to the prior art;

2 is a cross-sectional view of a compressor having a plurality of compression units according to the prior art,

3 is a schematic structural diagram of a compressor first embodiment according to the present invention;

4 is a cross-sectional view showing the detailed structure of a first embodiment of a compressor according to the present invention;

5 is a graph showing a change in stroke of pistons according to a voltage applied to the linear motor shown in FIG. 4;

6 is a graph showing a change in stroke of an absorber piston according to the frequency applied to the linear motor shown in FIG.

7 is a flowchart illustrating a first embodiment of a control method of a compressor according to the present invention;

8 is a sectional view of a second embodiment of a compressor according to the present invention;

9 is a flowchart illustrating a second embodiment of a control method of a compressor according to the present invention;

<Explanation of symbols on main parts of the drawings>

100: linear compression portion 102, 102 ': shell

103: suction port 104, 105: discharge port

106: suction pipe 106 ': connecting pipe

107: vibration absorber cover 108: inlet

109: suction pipe 110: cylinder

120: piston 122: fluid suction passage

123: suction port 124: suction valve

130: linear motor 133: coil

134: magnet 135: magnet frame

140: stator cover 142: back cover

148: linear discharge pipe 200: vibration absorbing compression portion

210: vibration absorber 212: absorber spring

214: absorber piston 220: absorber cylinder

224: absorber discharge pipe 240: radiator

The present invention relates to a compressor for compressing a fluid such as refrigerant gas, a control method thereof, and a refrigerator having the same. More particularly, the present invention relates to a compressor having a plurality of compression units operated by one motor, a control method thereof, and a refrigerator having the same.

In general, a compressor is installed in a refrigerating device such as a refrigerator or an air conditioner to compress a refrigerant gas at a high temperature and high pressure. The compressor includes a motor unit and a compression unit.

When the compressor is operated by the driving of the motor unit, the refrigerator or the air conditioner, the refrigerant compressed in the compressor is condensed in the condenser and expanded in the expansion mechanism, and then evaporated in the evaporator and then circulated back to the compressor, wherein the evaporator is surrounded by We lower temperature of the inside of room and room by cooling air of room.

Recently, a plurality of evaporators are provided in a refrigerator, an air conditioner, and the like, and a motor unit operates a plurality of compression units to supply refrigerant to a plurality of evaporators.

1 is a longitudinal sectional view of a compressor having a plurality of compression units according to the prior art, and FIG. 2 is a cross sectional view of a compressor having a plurality of compression units according to the prior art.

In the conventional compressor, as illustrated in FIGS. 1 and 2, a plurality of compression units 32 and 34 are installed together with the motor 38 in the shell 36.

Each of the plurality of compression parts 32 and 34 includes a piston 40a and 40b, cylinders 42a and 42b in which the pistons 40a and 40b are linearly reciprocated, and the cylinder 42a. And a suction / ejection portion (48a) (48b) for allowing the refrigerant gas to flow into the (42b) and for discharging the refrigerant gas inside the cylinders (42a) and (42b).

The motor 38 has an eccentric shaft 41 is formed on the upper end of the rotating shaft 39, the rod 44a (44b) is connected to the plurality of compression units 32, 34 in the eccentric shaft 41 Is connected.

That is, in the compressor, the plurality of pistons 40a and 40b are mechanically connected to each other through the eccentric shaft 41 and the rods 44a and 44b.

On the other hand, the shell 36 is a suction suction / discharge of any one of the fluid suction pipe 66 and the plurality of compression units 32, 34 to guide the fluid into the shell 36; Discharged through a first discharge pipe 68 for guiding the fluid discharged through the portion 48a and the suction / discharge portion 48b of the other one of the plurality of compression portions 32 and 34. It further comprises a second discharge pipe 70 for guiding the fluid.

However, in the compressor according to the prior art, since the plurality of pistons 40a and 40b are reciprocated in a reciprocating manner and the plurality of pistons 40a and 40b are mechanically connected to each other, the motor 38 is a Bieldi motor Even if it is made of a plurality of compression section 32, 34 has a problem that it is difficult to adjust each independently to match the external load.

The present invention has been made to solve the above problems of the prior art, the object of the present invention is to provide a compressor that minimizes the number of parts while minimizing the vibration by using a vibration absorber that absorbs vibration as a compression unit.

Another object of the present invention is to provide a refrigerator having a compressor in which a plurality of compression units can independently change the refrigerating capacity.

Compressor according to the present invention for solving the above problems is a linear compression unit; A vibration absorber connected to the linear compression unit to absorb the vibration of the linear compression unit; And an absorber cylinder in which the vibration absorber is linearly reciprocated so as to compress the fluid upon vibration of the vibration absorber.

The vibration absorber comprises an absorber spring connected to the linear compression unit and an absorber piston connected to the absorber spring and linearly reciprocated into the absorber cylinder to compress the fluid.

The compressor further includes an absorber suction part through which the fluid is sucked into the absorber cylinder, and an absorber discharge part through which the fluid compressed in the absorber cylinder is discharged.

The compressor has an absorber compression section including the vibration absorber and the absorber cylinder and the linear compression section have separate absorption and discharge lines.

The compressor further includes a connection flow path for guiding the fluid compressed from one side of the linear compression part and the absorber compression part to the other side, and a radiator installed in the connection flow path.

The linear compression portion includes a cylinder, a piston arranged to be linearly inside the cylinder, and a linear motor for linearly reciprocating the piston into the cylinder.

The control method of the compressor according to the present invention includes a voltage adjusting step of adjusting a voltage applied to the linear motor to adjust the compression capacity of the linear compression unit and the vibration absorbing compression unit; And a frequency adjusting step of adjusting a frequency applied to the linear motor to adjust the compression capability of the vibration absorbing compression unit.

A refrigerator having a compressor according to the present invention is a refrigerator having a compressor having a plurality of compression parts to supply refrigerant to a plurality of evaporators, wherein the compressor is configured to supply fluid while the piston is linearly reciprocated into a cylinder by a linear motor. A linear compression unit for compressing; And a vibration absorber having a vibration absorber connected to the linear compressor to absorb vibrations of the linear compression unit, and an absorber cylinder in which the vibration absorber is linearly reciprocated so that fluid is compressed during vibration of the vibration absorber.

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

3 is a schematic structural diagram of a compressor first embodiment according to the present invention;

The compressor shown in FIG. 3 includes a linear compression unit 100 for compressing a fluid (hereinafter, referred to as a fluid) such as a refrigerant gas; It is connected to the linear compression unit 100 is configured to include a vibration absorbing compression unit 200 to compress the fluid separately from the linear compression unit 100 while absorbing the vibration of the linear compression unit 100.

The linear compression unit 100 includes a cylinder 110, a piston 120 linearly disposed into the cylinder 10, and a linear motor 130 for linearly reciprocating the piston 120 into the cylinder 110. It is configured to include.

The vibration absorbing compression unit 200 includes a vibration absorber 210 connected to the linear compression unit 102 to absorb the vibration of the linear compression unit 102; The vibration absorber 210 includes an absorber cylinder 220 in which the vibration absorber 210 is linearly reciprocated so that the fluid is compressed during the vibration of the vibration absorber 210.

The vibration absorber 210 includes an absorber spring 212 connected to the linear compression unit 2 and an absorber piston connected to the absorber spring 212 and linearly reciprocated into the absorber cylinder 220 to compress the fluid. 214).

The compressor is a compressor of one stage and two compression, when the linear compression unit 100 and the absorber compression unit 200 have separate discharge lines.

4 is a cross-sectional view showing the detailed structure of the first embodiment of the compressor according to the present invention.

In the compressor illustrated in FIG. 4, the linear compression unit 100 and the vibration absorption compression unit 200 are installed in one shell 102.

The shell 102 forms the appearance of the compressor, and the inlet port 103 through which the fluid is introduced and the discharge port 104 and 105 through which the compressed fluid is discharged are formed.

The shell 50 is formed in a cylindrical structure, the inlet 103 is formed on one side of the circumference, the discharge port 104 of the linear compression unit 100 is formed on one of the left and right sides, the other side of the left and right sides The discharge port 105 of the vibration absorption compression section 200 is formed.

The shell 102 has a suction pipe 106 connected to the suction port 103 to suck the fluid from the outside.

In the linear compression unit 100, the cylinder 110 is fixed to the shell 102.

The linear compression unit 100 is coupled to a spring support 121 for supporting the spring 144 to be described later to the piston 120.

The piston 120 is provided with a linear suction unit.

The linear suction unit includes a suction passage 122 formed to suck fluid into the piston 120, a plurality of suction ports 123 formed on one surface of the piston 63, and a plurality of suction ports 123 on one surface of the piston 63. Intake valve 124 is installed to open and close).

The piston 120 is provided with a silencer 125 to reduce the noise.

The linear motor 130 largely consists of a stator and a mover.

The stator includes an outer stator 131 formed of a laminate, an inner stator 132 disposed to have a predetermined gap with the outer stator 131, and a coil 133 mounted to the outer stator 131 to form a magnetic field.

The mover is located between the outer stator 131 and the inner stator 132 and the magnet 134 is linearly moved by the magnetic force formed around the coil 133, the magnet 134 and the piston 120 is fixed to the magnet It consists of a magnet frame 135 to transmit the linear movement force of the 134 to the piston 130.

The linear compression unit 100 is a stator cover 140 fixed to the shell 102 to support the linear motor 130 and a back cover fixed to the shell 102 and spaced apart from the stator cover 140 by a predetermined interval. And a spring 144 elastically supporting the piston 120 between the stator cover 140 and the back cover 142.

On the other hand, the shell 102 is provided with a linear discharge portion for determining whether to discharge the fluid compressed by the linear compression portion 100.

The discharge part 145 is fixed to the outside of the shell 102 to buffer the fluid discharged through the toe outlet 104 of the linear compression part 100, and the discharge spring 145 in the discharge cover 145. And a discharge valve 147 which is supported by 147 to open and close the compression chamber C1 of the cylinder 110.

One side of the discharge cover 145 is connected to a linear discharge pipe 148 for guiding the fluid discharged into the discharge cover 145 to the outside.

On the other hand, the vibration absorbing compression unit 200 is the absorber spring 212 of the vibration absorber 210 is connected to the back cover 142.

Here, the absorber piston 214 is a kind of mass, which is a type of dynamic absorber that absorbs the vibration of the linear compression unit 100 while vibrating with the absorber spring 212 during the vibration of the linear compression unit 100.

Absorber cylinder 220 is secured to shell 102.

The absorber piston 214 is provided with an absorber suction part.

The absorber suction part includes a suction passage 215 formed to suck fluid into the absorber piston 214, a plurality of suction ports 216 formed on one surface of the absorber piston 214, and a plurality of suction ports on one surface of the absorber piston 214. And a suction valve 217 installed to open and close the suction port 216.

Absorber piston 214 is provided with an absorber silencer 218 to reduce noise.

On the other hand, the shell 102 is provided with a vibration-absorbing discharge unit for determining whether or not to discharge the fluid compressed by the vibration-absorbing compression unit 200.

 The vibration absorbing discharge part has the same structure as the linear discharge part, and is fixed to the outside of the shell 102 and discharge cover 221 for buffering the fluid discharged through the discharge port 105 of the vibration absorbing compression unit 200 and The discharge valve 223 is supported by the discharge spring 222 in the discharge cover 221 to open and close the compression chamber C2 of the absorber cylinder 220.

One side of the discharge cover 221 is connected to the absorber discharge pipe 224 for guiding the fluid discharged into the discharge cover 221 to the outside.

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

When a predetermined voltage (for example, 220 V) is applied to the coil 133 of the linear motor 130, a current flows in the coil 133, and a magnetic field is formed around the coil 133.

The magnet 134 is linearly reciprocated by a magnetic field formed around the coil 133, the momentum force is transmitted to the piston 120 through the magnet frame 135 so that the piston 120 linearly reciprocates inside the cylinder 110. While moving, the fluid in the compression chamber C1 of the linear compression unit 110 is compressed.

That is, when the piston 120 of the linear compression unit 100 reverses in the opposite direction of the linear discharge unit, the suction valve 124 is opened, and the fluid in the suction passage 122 of the piston 120 is sucked in the suction port 123. Through the inlet into the compression chamber (C1) of the cylinder 110, when the piston 120 is advanced toward the linear discharge portion, the fluid inside the compression chamber (C1) of the cylinder 110 is compressed and then the discharge valve ( The discharge valve 147 is opened while pushing the 147, and then flows out to the linear discharge pipe 148 through the discharge cover 145.

At this time, the vibration absorber 210 is vibrated with the linear compression unit 110 and the linear compression unit 100 together with the absorber spring 212 while the absorber piston 214 linearly moves inside the vibration absorption cylinder 220. ) Vibration is absorbed.

That is, in the compressor, when the driving frequency of the linear compression unit 100 matches the natural frequency of the vibration absorber 210, the vibration absorber 210 cancels all the vibrations of the linear compression unit 100.

On the other hand, during the linear reciprocation of the absorber piston 214, the fluid inside the shell 102 is compressed in the vibration absorbing compression unit 200.

That is, when the absorber piston 214 of the vibration absorber compression unit 200 reverses in the opposite direction of the vibration absorbing discharge unit, the suction valve 217 is opened, and the fluid in the suction flow path 215 of the absorber piston 214 is sucked in. Through the port 216 is introduced into the compression chamber (C2) of the absorber cylinder 220, when the absorber piston 214 advances toward the vibration absorbing discharge portion, the fluid inside the compression chamber (C2) of the cylinder 220 After the compression is performed, the discharge valve 223 is opened while pushing the discharge valve 223, and then is discharged to the absorber discharge pipe 224 through the discharge cover 221.

That is, when a predetermined voltage (for example, 220V) is applied to the coil 133 of the linear motor 130, the compressor flows into the shell 102 through the suction pipe 106 and then the linear compression unit ( 100 and the vibration absorbing compression unit 200 are compressed in each, and supplied to the condenser connected to each of them through the linear discharge pipe 148 and the absorber discharge pipe 224.

On the other hand, the compressor according to the voltage applied to the coil 133 of the linear motor 130, as shown in Figure 5, the stroke of the magnet 134, that is, the stroke and vibration of the piston 120 of the linear compression unit 100 The stroke of the absorber piston 214 of the absorption compression unit 200 is also determined, and the stroke of each of the pistons 120 and 214 varies in proportion to the voltage applied to the coil 133 of the linear motor 130.

In addition, when the compressor changes the frequency applied to the coil 133 of the linear motor 130, as shown in FIG. 6, the absorber piston 214 of the vibration absorbing compression unit 200 is the absorber spring (212) Since it is connected to the linear compression unit 100 through, the stroke is variable.

7 is a flowchart illustrating a first embodiment of a control method of a compressor according to the present invention.

 First, the load in which the linear compression unit 100 supplies the refrigerant, for example, the load of the first evaporator (not shown) of the refrigerator is changed, and the load in which the absorber compression unit 200 supplies the refrigerant, for example When the load of the second evaporator (not shown) of the refrigerator is changed, the controller (not shown) installed in the refrigerator may adjust the compression capacity of the linear compressor 130 and the absorber compressor 200. The voltage applied to the coil 133 is changed in correspondence with the load (S1) (S2).

That is, when the loads of the first evaporator and the second evaporator of the refrigerator both increase, the voltage applied to the coil 133 of the linear motor 130 is increased, and the loads of both the first evaporator and the second evaporator of the refrigerator decrease. The voltage applied to the coil 133 of the linear motor 130 is lowered.

Then, when only the load of the absorber compression unit 200 to supply the refrigerant, for example, the load of the second evaporator (not shown) of the refrigerator, the control unit may adjust the linear motor to adjust the compression capacity of the vibration absorption compression unit 200. The frequency applied to the coil 133 of 130 is changed in response to the load (S3) (S4).

8 is a cross-sectional view of a second embodiment of a compressor according to the present invention.

In the compressor according to the present embodiment, as shown in FIG. 8, only the linear compression unit 100 is installed inside the shell 102 ′, and the absorber compression unit 200 is located outside the shell 102 ′. Connected.

The shell 102 'is separately provided with an absorber compression section cover 107 surrounding the absorber compression section 200.

The absorber compression unit cover 107 is formed with a separate suction inlet 108 for fluid intake from the outside, the suction pipe 108 is connected to the suction pipe 109.

In addition, the refrigerant compressed in the absorber compression unit 200 may be introduced into the shell 102 'in the discharge port 221 of the absorber compression unit 200 and the inlet 103' formed in the shell 102 '. The connection pipe 106 'which is a connection flow path is connected.

In the connection pipe 106 ′, a radiator 240 is installed to radiate the refrigerant compressed in the compression chamber C2 of the absorber compression unit 200.

The configuration and operation other than the shell 102 ', the absorber compression section cover 107', the connecting pipe 106 ', the radiator 240, etc. are the same or similar to those of the first embodiment of the present invention, and therefore the same reference numerals are used. Detailed description thereof will be omitted.

In the compressor according to the present embodiment, when voltage is applied to the coil 133 of the linear motor 130, the fluid flows into the absorber compression unit cover 107 and is compressed in the compression chamber C2 of the absorber compression unit 200. And through the absorber discharge cover 221 and the connecting pipe 106 '.

The fluid passing through the connection pipe 106 ′ releases heat to the outside while passing through the radiator 240, thereby lowering the temperature, and is then moved into the shell 102 ′ to move the compression chamber C1 of the linear compression unit 100. Is compressed again. The fluid compressed in the compression chamber C1 of the linear compression unit 100 is supplied to the condenser through the linear discharge cover 145 and the linear discharge pipe 148.

That is, since the compressor first compresses the fluid in the compression chamber C1 of the linear compression unit 100 and then dissipates the fluid, the compressor compresses the second stage overall in the compression chamber C1 of the linear compression unit 100, thereby compressing the fluid as a whole. .

9 is a flowchart illustrating a second embodiment of a control method of a compressor according to the present invention.

First, when a load for supplying a refrigerant by a compressor, for example, an evaporator load of a refrigerator, is changed, a controller (not shown) installed in the refrigerator may adjust the linear capacity of the linear compression unit 100 and the absorber compression unit 200 to adjust the compression capacity. The voltage applied to the coil 133 of the motor 130 is changed corresponding to the load (S11) (S12).

Subsequently, when the load to which the compressor supplies the refrigerant, for example, the load of the evaporator of the refrigerator is changed again or a load equal to or larger than the load corresponding to the change of the voltage is applied, it is applied to the coil 133 of the linear motor 130. The frequency is changed in response to the load (S13) (S14).

Meanwhile, the present invention is not limited to the above embodiments, and the absorber compression unit 200 may be connected to the linear discharge unit of the linear compression unit 100, and after the fluid is compressed in the linear compression unit 100, It is also possible for the connecting pipe 106 'to be connected to the linear discharge part and the vibration absorber cover 107 so as to be compressed again in the absorber compression part 200, and various implementations are possible within the technical scope of the present invention. .

Compressor of the present invention configured as described above, the vibration absorber is connected to the linear compression unit, the absorber cylinder is installed in which the vibration absorber is linearly reciprocated is installed, the vibration absorber and the linear compression unit while minimizing vibration Since the fluid is compressed separately, there is an advantage that can minimize the number of parts while minimizing the vibration transmitted to the outside of the compressor.

Further, in the compressor of the present invention, since the absorber compression unit and the linear compression unit have separate absorption and discharge lines, and the absorption capacity of the compression unit is changed by the variable frequency applied to the linear motor, the plurality of compression units are independently refrigerated. There is an advantage to varying capabilities.

In addition, the compressor of the present invention includes a connection flow path for guiding the fluid compressed from one side of the linear compression unit and the absorber compression unit to the other side, and a radiator provided in the connection flow path, and the compressor can compress the fluid in multiple stages. have.

In addition, the control method of the compressor of the present invention, the voltage applied to the linear motor for adjusting the compression capacity of the linear compression unit and the vibration absorption compression unit, and adjusts the frequency applied to the linear motor for adjusting the compression capacity of the vibration absorption compression unit. Therefore, the compression capacity of the linear compression unit and the vibration absorbing compression unit can be different from each other, or even if a large load greater than the load corresponding to the voltage adjustment applied to the linear motor is applied to the large load due to the adjustment of the frequency applied to the linear motor. There is an advantage to respond.

In addition, the refrigerator having the compressor of the present invention has the advantage that it is convenient to individually control the plurality of evaporator temperatures without installing a separate temperature control mechanism or additional compressor by a simple structural change of the compressor.

Claims (8)

A linear compression unit;  A vibration absorber connected to the linear compression unit to absorb the vibration of the linear compression unit; And an absorber cylinder in which the vibration absorber is linearly reciprocated so as to compress the fluid upon vibration of the vibration absorber. The method of claim 1, And the vibration absorber comprises an absorber spring connected to the linear compression unit, and an absorber piston connected to the absorber spring and linearly reciprocated into the absorber cylinder to compress the fluid. The method of claim 1, And the compressor further comprises an absorber suction part through which the fluid is sucked into the absorber cylinder, and an absorber discharge part through which the fluid compressed in the absorber cylinder is discharged. The method of claim 1, The compressor is characterized in that the absorber compression unit including the vibration absorber and the absorber cylinder and the linear compression unit has a separate suction discharge line. The method of claim 1, The compressor is characterized in that it further comprises a connection passage for guiding the fluid compressed from one side of the linear compression unit and the absorber compression unit to the other side, and a radiator provided in the connection passage. The method according to any one of claims 1 to 5, And the linear compression unit comprises a cylinder, a piston disposed linearly into the cylinder, and a linear motor for linearly reciprocating the piston into the cylinder. In the control method of the compressor to control the compressor of claim 6, The control method of the compressor includes a voltage adjusting step of adjusting a voltage applied to the linear motor to adjust the compression capacity of the linear compression unit and the vibration absorbing compression unit; And adjusting a frequency applied to the linear motor to adjust the compression capability of the vibration absorbing compression unit. A refrigerator having a compressor provided with a plurality of compression parts to supply refrigerant to a plurality of evaporators, The compressor may include a linear compression unit compressing a fluid while the piston is linearly reciprocated into the cylinder by a linear motor; And a vibration absorber having a vibration absorber connected to the linear compressor to absorb the vibration of the linear compressor, and an absorber cylinder in which the vibration absorber is linearly reciprocated so that fluid is compressed during vibration of the vibration absorber. Refrigerator having a compressor.

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