KR200205126Y1 - A muffler of a suction for a compressor - Google Patents

Abstract

The present invention provides a compressor accumulator that can reduce the high frequency noise when the high frequency noise generated by the friction between the roller and the vane of the compressor is radiated into the accumulator.

To this end, the compressor accumulator of the present invention is a compressor accumulator which is installed vertically inside the accumulator and has a suction pipe communicating with a compression device installed inside the main body through an accumulator lower end, wherein Noise attenuating means installed in the compression device to attenuate the noise radiated from the compression apparatus to the accumulator, the noise attenuation means increasing the transmission length of the noise while changing the direction of the noise and reducing the transmission passage. A plurality of partition members for reducing the noise by reducing the frequency of the noise through, and characterized in that the configuration of the protrusion wall for narrowing the noise passage inlet and the noise passage exit of the noise transmitted through the suction pipe.

Description

Accumulator for compressors {A MUFFLER OF A SUCTION FOR A COMPRESSOR}

The present invention relates to an accumulator for a compressor. In particular, a noise damping device is provided on a suction pipe in an accumulator to reduce high frequency noise when high frequency noise generated by friction between a roller and a vane is radiated into the accumulator. It is about an accumulator.

Generally, a compressor is a device that pressurizes a fluid to change the pressure, temperature, and the like of the fluid to suit a predetermined purpose. The compressor is classified into a rotary type, a piston type, and a stroke type according to an operation type.

Here, the conventional compressor is, as shown in Figures 1 and 2, the outer body is made of a cylindrical case, the electric motor is installed inside the main body 10 is supplied with an external power supply to generate power transmission The device 20, the compression device 30 for compressing the fluid (refrigerant) sucked by the power received from the lower portion of the transmission 20, and the main body 10 in communication with one side of the outer peripheral surface of the main body 10 Accumulator 40, which is coupled to the liquid refrigerant when the portion of the refrigerant gas flowing from the evaporator (not shown) is changed into the liquid refrigerant due to the load change during the inflow process, allows only the refrigerant gas to flow into the compression device 30. Consists of

That is, the case forming the appearance of the main body 10 is composed of an upper cap 11 and a lower case 12, the lower end of the upper cap 11 is pressed into the upper end of the lower case 12 in a welded structure The discharge pipe 13 for discharging the compressed refrigerant is provided through the upper center portion of the upper cap 11.

The transmission device 20 is in close contact with the inner wall of the lower case 12 so as to form a magnetic field by receiving an external power source, the stator 21 is installed so that the cylindrical space is formed in the center and the stator 21 Rotor 22 is installed to the inner side of the rotor and rotated under the influence of the magnetic field formed in the stator 21, and coupled to the rotor 22 in the rotor 22 and interlocked with the eccentric cam on one side It consists of a rotating shaft 23 provided with (24).

The compression device 30 has a cylindrical ring-shaped roller 32 which is extrapolated to the outside of the eccentric cam 24 so as to rotate and slide as the eccentric cam 24 rotates, and the rotation shaft 23 And a cylindrical cylinder 31 having a space for compressing the refrigerant by accommodating the roller 32 at the lower end side of the roller 32 and a space for compressing the refrigerant, and being inserted into the inner wall of the cylinder 31 to form the roller 32. Plate-shaped vanes 33 which partition the inside of the cylinder 31 into the suction space and the compression space through the forward and backward reciprocating motion by the elastic force of the spring 34 provided at the rear end while slidingly contacting the outer circumferential surface of the The upper and lower flanges 35 and 36 are fixed to a plurality of bolts so as to face each other so as to fix the cylinder 31 on the upper and lower sides of the cylinder 31.

The accumulator 40 is installed to open the case member 41 and the upper end side of the case member 41 to form an appearance so that the refrigerant flowing from the evaporator flows into the case member 41 into the case member 41. Inlet pipe (42) for guiding the suction pipe connected to the main body 10 at the lower end of the case member 41 is installed to guide the flow of the refrigerant gas to supply the refrigerant gas to the compression device (20) (Stand Pipe; 43).

In addition, the lower portion of the internal inlet pipe 42 of the accumulator 40 filters the liquid refrigerant changed into the liquid phase due to the load change due to the suction of the refrigerant gas introduced from the evaporator to prevent the inflow into the suction pipe 43. ) And a baffle 46 are installed through the screen holder 47, and an inflow passage for guiding the flow of the refrigerant to suck the refrigerant into the cylinder 31 between the suction pipe 43 and the cylinder 31. 44).

As described above, the accumulator 40 is inserted into the inflow passage 44 by the suction pipe 43 at the lower end side of the case member 41, and then welded to the main body 10 and the main body. The bracket 50 welded to a predetermined point on the outer circumferential surface of the 10 and the strap 60 which wraps and holds the outer circumferential surface of the case member 41 are fastened and fixed by bolts, thereby being fixed to one side of the main body 10.

In the conventional compressor configured as described above, when the refrigerant circulates along a known refrigerant cycle, the refrigerant gas evaporated from the evaporator is passed through the inlet pipe 42 provided above the case member 41 of the accumulator 40. In this case, when some of the refrigerant gas introduced into the inlet pipe 42 is changed into the liquid refrigerant due to the load fluctuations during the inflow process, the liquid refrigerant is filtered by the screen 45 and the baffle 46 The inner wall of the case member 41 is collected toward the inner bottom surface of the case member 41 so that the liquid refrigerant does not directly flow into the compression device 30.

Then, the refrigerant gas separated from the liquid refrigerant as described above is introduced into the suction pipe 43 installed in the inner central portion of the case member 41 is introduced into the cylinder 31 through the inflow passage 44.

On the other hand, while the power is applied to the transmission device 20 while the process occurs, the magnetic field is formed on the stator 21, the rotor 22 is rotated by the magnetic field formed in the stator 21.

Accordingly, by rotating the rotary shaft 23 integrally coupled with the rotor 22, the eccentric cam 24 provided on one side of the rotary shaft 23 is also linked to rotate at high speed.

The roller 32 extrapolated to the eccentric cam 24 is rotated in the cylinder 31 by the rotation of the eccentric cam 24, and the cylinder 31 is rotated according to the rotation of the roller 32. The vane 33 inserted into the inner wall is slidably contacted with the outer circumferential surface of the roller 32 while reciprocating forward and backward by the elastic force of the spring 34 provided at the rear end to move the inside of the cylinder 31. The suction space and the compression space are partitioned, and at the same time, the roller 32 compresses the refrigerant sucked through the inflow passage 44 formed at one end of the cylinder 31 to a high temperature and high pressure.

The refrigerant compressed at high temperature and high pressure is discharged to the outside of the upper flange 35 through the discharge hole 37 formed at one side of the cylinder 31 shown in FIG. 2, and discharged to the outside of the upper flange 35. The refrigerant is moved upward along the guide passage (not shown) and discharged to the outside of the compressor through a discharge tube 13 installed to penetrate the upper center portion of the upper cap 11 to be sent to the condenser (not shown), thereby providing a refrigerant cycle. It will run smoothly.

At this time, when the compressor starts the compression action as described above, the vibration and noise are generated by friction between the parts while contacting the vanes 33 by the rotation of the rotary shaft 23 and the rotation of the roller 32 inside the cylinder 31. This vibration and noise is radiated and transmitted to the accumulator 40 through the suction pipe 43.

The vibration and noise emitted are mainly in the form of high frequency high frequency bars, some of which are radiated to the accumulator 40 and converted into thermal energy, but a large amount of high frequency generates high frequency noise through the accumulator 40.

However, the conventional compressor has a problem of reducing the reliability of the product because the countermeasures against the high frequency noise emitted by being transmitted to the accumulator 40 through the suction pipe 43 is weak.

Therefore, the present invention has been devised to solve the above problems, and an object of the present invention is to provide a noise damping device on a suction pipe in an accumulator so that high frequency noise generated by friction between a roller and a vane is radiated into the accumulator. It is to provide an accumulator for a compressor that can reduce the high frequency noise.

In order to achieve the above object, the present invention is installed in the accumulator vertically, and in the accumulator for compressor having a suction pipe communicating with the compression device installed inside the main body through the accumulator lower portion, the suction pipe with respect to the interior of the accumulator Noise attenuating means installed in the upper portion of the attenuator to attenuate the noise radiated to the accumulator through the inlet passage from the compression device, the noise attenuation means, while increasing the transmission length of the noise while changing the direction of the noise passage passage A plurality of partition members for reducing the noise by reducing the frequency of the noise through the reduction of, and characterized in that the configuration of the protrusion wall for narrowing the noise passage inlet and noise passage exit of the noise transmitted through the suction pipe.

1 is a longitudinal sectional view showing a configuration of a conventional compressor;

2 is a plan sectional view showing a configuration of a compression apparatus of a conventional compressor.

Figure 3 is a longitudinal sectional view of the compressor showing a state in which the noise damping device is provided in the accumulator according to the present invention

Figure 4 is an enlarged cross-sectional view showing a state in which the noise damping device according to the present invention is installed on the suction pipe.

Explanation of symbols on the main parts of the drawings

10; Main body 20; Transmission

30; Compression apparatus 31; cylinder

32; Roller 33; Bain

40; Accumulator 41; Case member

42; Inlet pipe 43; suction

44; Inlet passage 100; Noise reduction means

101; Noise passage inlet 102; Noise passage exit

103,106; Protruding wall 104; Bulkhead member

105; Protruding jaw

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

Figure 3 is a longitudinal sectional view of the compressor showing a state in which the noise damping device is provided in the accumulator according to the present invention, Figure 4 is an enlarged cross-sectional view showing a state in which the noise damping device according to the present invention is installed on the suction pipe.

In the drawings, the same parts as in the conventional construction are denoted by the same reference numerals and detailed description thereof will be omitted.

As shown, the accumulator 40 is fixed to one side of the main body 10 by the fastening of the bracket 50 and the strap 60, and a compressed material such as refrigerant sucked into the accumulator 40 is stored in a cylinder. The suction pipe 43 leading to the 31 extends from the lower end of the screen 45 installed in the accumulator 40 to the lower end of the accumulator 40, and the main body 10 at the lower end of the accumulator 40. Is vertically bent in the direction of the lower case 12 of the lower case 11 has a structure in communication with the compression device 30 and the inflow passage 44 inside.

Here, the noise attenuation means 100 is provided on the suction pipe 43 to attenuate the high frequency noise emitted from the compression device 30 to the accumulator 40 through the inflow passage 44.

The noise attenuation means 100 is a high frequency reduction silencer formed with a plurality of partition members 104 formed therein, and is installed in the suction pipe 43 so that the plurality of partition members 104 move in the direction of high frequency noise. It is designed to reduce the frequency of high frequency noise by increasing the transmission length of high frequency noise and reducing the frequency of the high frequency noise by changing the transmission passage.

In addition, the noise attenuation means 100 is formed with protruding walls 103 and 106 through which the high frequency noise transmitted through the suction pipe 43 narrows the noise passage inlet 101 and the noise passage outlet 102.

In addition, the installation position of the noise attenuation means 100 may be anywhere on the suction pipe 43.

On the other hand, the plurality of partition member 104 by dividing the interior of the noise attenuation means 100 into a plurality of spaces so as to reduce the cross-sectional area of the passage through which the high frequency noise is transmitted while increasing the overall transmission length, According to Equation (1) below, a result of attenuating high frequency noise is obtained.

----- (One)

ν: frequency

a: sound speed

f: cross section of the pipe

V: volume

L: length of pipe

Here, the cross-sectional area f of the pipe represents the cross-sectional area of each of the spaces partitioned by the partition member 104, the length L of the pipe represents the length of the entire passage through which the high frequency noise passes, and the volume V represents the noise attenuation means (100). Represents the volume of the whole inside.

In other words, the above formula is to determine the frequency of the frequency according to the change in the cross-sectional area, volume and length of the tube when the sound velocity is constant.

On the other hand, reference numeral 105 denotes a protruding jaw protruding from the partition member 104 to guide the reflection and transmission of high frequency noise.

Therefore, the following describes the operation and effects of the present invention configured as described above.

When the compressor starts the compression action, vibration and noise are generated by friction between the parts while contacting the vanes 33 by the rotation of the rotary shaft 23 and the rotation of the roller 32 inside the cylinder 31.

The vibration and noise are radiated and transmitted to the accumulator 40 through the suction pipe 43, and the high frequency noise thus transmitted is introduced into the noise attenuation means 100 along the suction pipe 43 to the partition member 104. It is guided by the passage through the noise attenuation means (100).

That is, high frequency noise is introduced into the noise passage inlet 101 of the noise attenuation means 100, and is reflected and guided by the partition member 104 and exits toward the noise passage outlet 102 of the noise attenuation means 100.

At this time, the high frequency noise is reflected and guided to the partition member 104, the wavelength of the high frequency noise cancel each other due to the phase difference, the noise itself is attenuated, the volume of the noise damping means 100 through which the high frequency noise passes And the length of the tube is increased more when passing through the suction pipe 43 and the cross-sectional area of the pipe partitioned by the partition member 104 is reduced, according to the frequency of high frequency is reduced according to the above formula (1) The level of noise that people hear is very low.

According to the accumulator for a compressor of the present invention as described above, by providing a noise attenuation means on the suction pipe to attenuate the high frequency noise generated in the compression process and radiated to the accumulator, the noise attenuation means reduces the frequency of high frequency to attenuate the noise. It is possible to improve the reliability of the product.

Claims (1)

In the accumulator for compressor having a suction pipe which is installed vertically inside the accumulator and communicates with the compression device installed inside the main body through the accumulator bottom, As the noise attenuation means is installed on the upper portion of the suction pipe with respect to the interior of the accumulator to attenuate the noise emitted to the accumulator through the inlet passage in the compression device, The noise damping means, A large number of partition members for reducing noise by increasing the transmission length of the noise while changing the direction of the noise and reducing the frequency of the noise by reducing the transmission passage; Accumulator for the compressor, characterized in that the projecting wall configured to narrow the noise passage inlet and the noise passage exit of the noise transmitted through the suction pipe.