KR200147723Y1 - Piston typed compressor - Google Patents

Abstract

The present invention relates to a reciprocating compressor, the purpose of which is to improve the suction muffler to improve its noise shielding ability and to facilitate the suction of the refrigerant to improve the compression efficiency.

In the reciprocating compressor according to the present invention, the suction muffler 500 is divided into an outer case 510 and a resonance room 511 in which a resonance room 511 is formed therein, and a suction guide room 521 so that refrigerant is temporarily stored. It consisted of an inner case 520 equipped with. Therefore, most of the refrigerant gas is smoothly supplied to the compression chamber 320 of the cylinder block 310 through the suction guide room 521 and the suction pipe 600 in the state of not receiving heat transfer to increase the compression efficiency thereof. The generated noise is shielded in the resonance room 511, the noise flowing back from the cylinder block 310 is shielded in the suction guide room 521, there is an advantage that the noise generated during its operation is greatly reduced.

Description

Reciprocating compressor

The present invention relates to a reciprocating compressor, and more particularly to a suction muffler that shields the noise generated during refrigerant suction.

In general, the reciprocating compressor serves to compress the refrigerant to a high temperature and high pressure in a refrigeration cycle in which the compression, condensation, expansion, and evaporation processes are continuously performed through the refrigerant to be discharged to the condenser.

As shown in FIG. 1, the general reciprocating compressor having such a function includes a driving unit 20 for generating power inside the hermetically sealed container 10 by combining the upper container 11 and the lower container 12. Consists of a compression unit 30 for receiving and compressing the refrigerant to receive the power, the oil is stored in the bottom of the oil for lubricating and cooling the sliding portion.

The driving unit 20 is installed on the top of the sealed container 10, the stator 21 to form a magnetic field by applying power, the rotor 22 to rotate in interaction with the rotor 22, and in the center of the rotor 22 A support bearing is supported in the lower portion so that the rotor 22 and the rotating shaft 23 can be rotated smoothly with the rotary shaft 23 is pressed in the axial direction and rotated integrally and the eccentric shaft 24 is provided at the lower end thereof. (25) is comprised. In addition, the compression unit 30 supports the driving unit 20 from the lower portion, and a cylinder block 31 having a compression chamber 32 in which a refrigerant is sucked and discharged inside the compression block 32 and suction and discharge of the refrigerant in the compression chamber 32 is provided. The cylinder head 35 is provided with a suction chamber 35a and a discharge chamber 35b for guiding the pressure, and the suction hole 36a and the discharge hole are selectively opened and closed between the cylinder head 35 and the compression chamber 32. The valve plate 36 in which the ball 36b is formed is interposed. On the other hand, a piston 33 for linearly reciprocating the compression chamber 32 is installed, which is connected to the eccentric shaft 24 and the connecting rod 34 so that the eccentric rotation of the rotary shaft 23 is the piston 33. Is converted into a linear reciprocating motion of. Reference numerals 40 and 41 are refrigerant inlet tubes through which refrigerant flows into the sealed container 10 from the outside, and refrigerant discharge tubes through which the compressed refrigerant is discharged to the outside.

In addition, a suction muffler 50 having a resonance chamber 51 formed therein is installed in the vertical direction of the cylinder head 35 to shield noise generated when the refrigerant is introduced. As shown in FIG. 2, the suction muffler 50 has an inlet 52 for guiding the inflow of the refrigerant therein, and the lower portion of the suction muffler 50 is coupled to communicate with one end of the suction pipe 60. Is in communication with the suction chamber 35a. Therefore, the refrigerant flows into the resonance chamber 51 of the suction muffler 50 through the inlet port 52, and is then guided to the compression chamber 32 through the suction tube 60 and the suction chamber 35a and at a high temperature and high pressure. It is compressed and discharged to the discharge chamber 35b, and it is comprised so that it may be sent out.

In the general reciprocating compressor configured as described above, as the power is applied, the rotor 22 in which the rotating shaft 23 is press-fitted by the magnetic field formed in the stator 21 rotates to interact. At the same time as the piston 33 coupled through the eccentric shaft 24 and the connecting rod 34 of the rotary shaft 23 reciprocates inside the compression chamber 32, the refrigerant in the suction muffler 50 is sucked and compressed, Discharged.

Hereinafter, the suction discharge process of the refrigerant will be described in more detail. The refrigerant flowing through the refrigerant inlet pipe 40 and the inlet port 52 generates noise due to the flow rate difference, which becomes a shield in the resonance chamber 51 of the suction muffler 50, and the refrigerant continues to the suction pipe 60. And into the compression chamber 32 through the suction chamber 35a. Then, the piston 33 reaches the top dead center, and the refrigerant compressed at high temperature and high pressure is discharged to the discharge chamber 35b, and is supplied into the refrigeration cycle again.

However, the suction muffler 50 of the reciprocating compressor has a noise generated at the suction of the refrigerant and a noise generated at the suction chamber 35a conversely concentrated to the countercurrent resonance chamber 51 through the suction tube 60 and shielded therefrom. Therefore, since the noise generated by the inflow of the refrigerant gas is concentrated only in the resonance room 51, there is a limit to its noise shielding. In addition, as shown in Fig. 2, the suction muffler 50 made of a single layer becomes easy to conduct heat from the outside, so that a large amount of the refrigerant gas remaining in the resonance chamber 51 is overheated. As a result, the cost of the refrigerant gas itself increases, so that the volumetric efficiency of the suction muffler 50 is lowered, and the compression efficiency of the compressor is also lowered. In order to compensate for this, there is a problem that the size of the suction muffler 50 must be increased.

The present invention is to solve this problem, the purpose of the suction muffler is composed of an inner case having a resonance chamber formed inside, the inner case having a suction guide room to be partitioned separately inside the resonance room, the refrigerant is temporarily stored, The refrigerant gas is smoothly supplied to the cylinder block through the suction guide room and the suction pipe to increase the compression efficiency, and the noise generated when the refrigerant is sucked is shielded in the resonance room, and the backflow of the cylinder block is blocked in the suction guide room. To provide.

1 is a cross-sectional view schematically showing the internal configuration of a typical reciprocating compressor.

Figure 2 is a side cross-sectional view showing the internal structure of a conventional suction muffler.

3 is a cross-sectional view showing a schematic configuration of a reciprocating compressor according to the present invention.

Figure 4 is a schematic cross-sectional view showing the internal structure of the suction muffler according to the present invention.

* Description of symbols on the main parts of the drawings *

100. Airtight container 310. Cylinder block 320. Compression chamber 330. Piston

500 .. Suction muffler 510. Outer case 511. Room 512. Inlet

520. Outer case 521 Suction guide 522 Guide 523 Joiner

524. Protrusion 600. Suction tube

The present invention for achieving the above object is a sealed container, a cylinder block which is built in a sealed container and a compression chamber formed therein, a suction muffler and a suction muffler that shield noise generated by the refrigerant flowing into the compression chamber from the outside of the sealed container. A reciprocating compressor having a suction pipe interposed between the compression chambers and guiding the refrigerant to the compression chamber, wherein the suction muffler has an outer case having a resonance room formed therein, and an inner case having a suction guide room installed inside the resonance room to temporarily store the refrigerant. Characterized in that.

Hereinafter, one preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings. 3 is a cross-sectional view schematically showing a reciprocating compressor according to the present invention, Figure 4 is an excerpt sectional view showing the internal configuration of the suction muffler which is a characteristic element of the present invention.

The reciprocating compressor according to the present invention is composed of a driving unit 200 for generating power in the sealed container 100 in which oil is stored, and a compression unit 300 for receiving and compressing a refrigerant by receiving power. It is. The driving unit 200 includes a stator 210 forming a magnetic field and a rotor 220 into which the rotating shaft 230 is press-fitted, and an eccentric shaft 240 is formed below the rotating shaft 230. In addition, the rotor 230 of the driving unit 200 is rotatably supported by the support bearing 250 interposed on the upper portion of the cylinder block 310 of the compression unit 300 to be described later.

The compression unit 300 includes a cylinder block 310 having a compression chamber 320 therein, a cylinder head 350 having a suction chamber 351 and a discharge chamber 352 for guiding suction and discharge of the refrigerant, and an optional chamber. A valve plate 360 having a suction hole 361 and a discharge hole 362 formed therein is interposed between the compression chamber 320 and the cylinder head 350, and a piston moving forward and backward in the compression chamber 320. 330 and the like. The piston 330 is coupled to the eccentric shaft 240 and the connecting rod 340 provided at the end of the rotary shaft 230, the eccentric rotational motion is converted into a linear reciprocating motion to move forward and backward inside the compression chamber 320 Will be.

And, the noise is generated due to the refrigerant flowing into the sealed container 100 from the outside through the refrigerant inlet pipe 400, the suction muffler 500 for shielding this is installed on the upper side of the cylinder head 350, A suction pipe 600 for guiding the low pressure refrigerant in the suction muffler 500 to the suction chamber 351 is interposed so as to communicate with the suction muffler 500 and the suction chamber 351 of the cylinder head 350.

On the other hand, as a characteristic element of the present invention, the suction muffler 500 formed therein to shield the noise generated due to the flow rate difference of the refrigerant is shown in Figure 4, the resonance chamber 511 therein The formed outer case 510, the resonance chamber 511 is installed inside the inner case 520, the suction guide room 521 is formed so that the refrigerant gas is temporarily stored therein. The outer case 510 is formed with an inlet 512 to which the refrigerant inlet pipe 400 is coupled such that refrigerant gas is introduced from the outside. The inner case 520 is embedded to be spaced apart from the outer case 510 by a predetermined distance, and the guide 522 for introducing the refrigerant gas to the upper end adjacent to the inlet 512 is provided, and the outer portion of the inner case 520 is provided at the outer end. One end portion of the suction pipe 600 passing through the case 510 is coupled to the coupling port 523 is configured to communicate. On the other hand, the surface of the inner case 520 has a kind of embossing shape, that is, a plurality of protrusions 524 protruding outward. Therefore, most of the refrigerant gas is introduced into the suction guide room 521 of the inner case 520 through the inlet 512 and the guide 522, and the compression chamber 320 through the suction pipe 600 and the suction room 351. Is compressed to high temperature and high pressure, and then discharged to the discharge chamber 352, and is discharged to the outside. In addition, the noise formed in the compression chamber 320 of the cylinder block 310 and transmitted backward through the suction pipe 600 is shielded in the suction guide room 521 of the inner case 520, which will be described in detail in the operation description. do.

Next will be described the operation of the reciprocating compressor according to the present invention configured as described above. In the reciprocating compressor, a magnetic field is formed in the stator 210 as the power is applied, and the rotor 220 in which the rotating shaft 230 is press-fitted rotates in interaction with the eccentric shaft 240. The connecting rod 340 is converted into a linear reciprocating motion of the piston 330. In addition, the piston 330 reciprocates the compression chamber 320 to inhale and compress the refrigerant. When the piston 330 operates in the bottom dead center in the compression chamber 320 and is in the suction process, the suction muffler 500 The refrigerant in the suction guide room 521 is introduced into the suction room 351 through the suction pipe 600, and subsequently enters the compression chamber 320 through the suction hole 361. On the contrary, when the piston 330 operates at the top dead center and is in the compression discharge process, the refrigerant gas compressed at high temperature and high pressure is discharged to the discharge chamber 352 through the discharge hole 362, and the outside is discharged along the refrigerant discharge pipe 410. Is supplied.

On the other hand, the suction muffler 500 enters the refrigerant gas into the suction guide room 521 of the inner case 520 through the inlet 512 and the guide port 522, the suction noise generated at this time is characteristic of the present invention The shield is made in the resonance chamber 511 formed between the outer case 510 and the inner case 520 by the action. And the noise generated by the flow rate difference of the refrigerant in the compression chamber 320 and the suction chamber 351 side of the cylinder block 310 flows back to the suction muffler 500 through the suction pipe 600, which is not transmitted to the outside A plurality of protrusions 524 is shielded in the inner case 520 provided in an embossed shape. In addition, the suction muffler 500 has a double structure inside, so that the refrigerant gas temporarily stored in the suction guide room 521 passes through the suction pipe 600 and the suction room 351 through the compression chamber 320 without receiving heat transfer. ), The compression efficiency is increased.

That is, the noise generated during suction and the backflow noise are shielded separately from the resonance room 511 and the suction guide room 521, respectively, so that the noise generated during operation of the compressor is reduced, and the suction guide room 521 is temporarily suspended. Since the refrigerant gas is stored in the compression chamber 320 without receiving heat transfer, its compression efficiency is increased.

As described in detail above, the reciprocating compressor according to the present invention consists of an inner case having a suction muffler, an outer case in which a resonance room is formed inside, a separate compartment inside the resonance room, and a suction guide room to temporarily store refrigerant. Therefore, most of the refrigerant gas is smoothly supplied to the compression chamber of the cylinder block through the suction guide room and the suction pipe without heat transfer, and the compression efficiency thereof is increased. The noise is shielded in the suction guide room, there is an advantage that the noise generated during its operation is greatly reduced.

Claims (3)

The sealed container 100, the cylinder block 310 installed in the sealed container 100 and having a compression chamber 320 formed therein, and a refrigerant flowing into the compression chamber 320 from the outside of the sealed container 100. In the reciprocating compressor having a suction muffler 500 for shielding the generated noise, a suction pipe 600 interposed between the suction muffler 500 and the compression chamber 320 to guide the refrigerant to the compression chamber 320. The suction muffler 500 has an outer case 510 having a resonance room 511 formed therein, and an inner case 520 having a suction guide room 521 formed therein so as to temporarily store a refrigerant therein. Reciprocating compressor comprising a). According to claim 1, wherein the outer case 510 is formed with an inlet 512 through which the refrigerant flows from the outside, the inner case 520 to guide the inflow of the refrigerant to the suction guide room 521 Guide port 522 is formed in a portion adjacent to the inlet 512, the coupling portion 523 is provided at the bottom of the inner case 520 is coupled to communicate with one end of the suction pipe 600. Reciprocating compressor. The reciprocating compressor of claim 2, wherein the inner case has a plurality of protrusions 524 protruding outward.