KR20020037999A - Structure for feeding oil into cylinder of hermetic compressor - Google Patents

Abstract

PURPOSE: A structure for supplying oil of cylinder of hermetic type compressor is provided to smoothly supply oil into the cylinder by suction force generated as a piston reciprocates in the cylinder. CONSTITUTION: An oil discharge pipe(28) penetrates a bottom of a body(21) of a muffler(20), fluidically connected to a cylinder, in which refrigerant is compressed, to reduce noise and guide flow of refrigerant taken into the cylinder. Oil is discharged through the oil discharge pipe when the oil is collected in the bottom of the body of the muffler more than fixed amount. A part of the oil discharge pipe protrudes on an inside of the bottom of the body of the muffler at fixed height.

Description

STRUCTURE FOR FEEDING OIL INTO CYLINDER OF HERMETIC COMPRESSOR}

The present invention relates to a cylinder oil supply structure of a hermetic compressor, and in particular, the oil can be smoothly supplied into the cylinder during the refrigerant is sucked into the cylinder through the silencer by the suction force generated while the piston reciprocates in the cylinder. It relates to a cylinder oil supply structure of a hermetic compressor.

In general, the refrigeration cycle apparatus, as shown in Figure 1, a compressor 100 for compressing a working fluid such as a refrigerant to convert to a high temperature and high pressure state, and a working fluid in the high temperature and high pressure state compressed by the compressor 100 Condenser 200 for discharging the latent internal heat to the outside while converting to a liquid phase, expansion mechanism 300 for reducing the pressure of the working fluid converted to the liquid phase in the condenser 200, and expanded in the expansion mechanism 300 It comprises an evaporator 400 for absorbing external heat while evaporating the working fluid in the liquid state, each component is connected by a connection pipe (L).

Such a refrigeration cycle device is installed in a refrigerator or an air conditioner to store food in a fresh state using cold air generated by the evaporator 400 or indoors by using cold air or heat generated from the evaporator 400 or the condenser 200. To keep it comfortable.

Compressors constituting the refrigerating cycle apparatus are classified into a sealed rotary compressor, a sealed electric compressor, a scroll compressor, and the like according to a method of compressing a working fluid.

Figure 2 shows an example of the hermetic electric compressor, as shown in the hermetic electric compressor, the stator (STATOR) 2 is supported by the spring (3) in the inner lower portion of the hermetic container (1) The rotor 4 is inserted into the stator 2 so as to be rotatable. And the cylinder block (B) provided with a cylinder (5) for compressing gas and the shaft insertion hole (6) into which the shaft is inserted is located on the upper side of the stator (3) and the crank shaft provided with the eccentric (7a) ( 7) is inserted into the shaft insertion hole 6 of the cylinder block and pressed into the rotor 4. The crankshaft 7 has an oil passage 7b formed therein and an oil feeder 7c at its end. The piston (8) is inserted into the cylinder (5) to enable a linear movement and the piston (8) and the eccentric portion (7a) of the crankshaft by connecting the rotational movement of the crankshaft (7) by linear reciprocating motion A connecting rod 9 for linearly reciprocating the piston 8 inside the cylinder 5 is engaged. And a valve assembly 10 coupled to the end of the cylinder 5 to allow refrigerant gas to be sucked into the cylinder 5 and compressed by the linear reciprocating movement of the piston 8, and the compressed refrigerant gas is discharged. In addition, a head cover 11 covering the valve assembly 10 is coupled, and a silencer 12 is coupled to the head cover 11 to reduce noise.

In addition, the suction tube 13 into which the refrigerant gas is sucked is coupled to one side of the sealed container 1, and the inner end of the suction tube 13 is coupled to be positioned at the inlet side of the silencer 12, and to the sealed container 1. A discharge tube (not shown) through which the compressed refrigerant gas is discharged is coupled, and a predetermined amount of oil is filled on the bottom surface of the airtight container 1.

Reference numeral 14 is a connecting pin, and 15 is a sleeve (SLEEVE).

In the operation of the hermetic electric compressor, first, when power is applied, the rotor 4 is rotated by the interaction of the stator 2 and the rotor 4, and the rotor is rotated by the rotation of the rotor 4. The crankshaft 7 pressed into (4) rotates. The connecting rod 9 coupled to the eccentric portion 7a of the crankshaft by the rotation of the crankshaft 7 converts the rotational movement into a linear reciprocating motion to cause the piston 8 to reciprocate in the cylinder 5. do. The refrigerant gas sucked into the suction pipe 13 by the operation of the valve assembly 10 together with the linear reciprocating motion of the piston 8 passes through the silencer 12 to the cylinder 5 and the piston 8. It is sucked into the compression space formed by the compressed space, and is discharged at a high temperature and high pressure, and the discharged refrigerant gas is discharged through the discharge pipe.

In addition, the oil filled in the bottom surface of the sealed container 1 is sucked up through the oil passage 7b by the oil feeder 7c coupled to the end of the crankshaft 7 together with the rotation of the crankshaft 7. It is fed to the part where relative motion takes place as it is scattered through the end of the shaft 7.

The refrigerant gas discharged to the discharge tube passes through the condenser 200, the expansion mechanism 300, and the evaporator 400 constituting the refrigeration cycle device, and then passes through the suction pipe 13 of the compressor to a low temperature and low pressure. Inhaled and repeat this cycle.

In addition, the refrigerant gas discharged from the compressor 100 at high temperature and high pressure state is mixed with a part of oil scattered in the sealed container 1 and discharged together, and the oil discharged together with the refrigerant passes through the cycle together with the refrigerant. Is introduced into the cylinder (5) of the compressor not only serves as a lubrication between the cylinder (5) and the piston (8) but also serves as a sealing between the cylinder (5) and the piston (8) It will increase the compression performance. On the other hand, when the oil discharged by being mixed with the refrigerant gas in the compressor 100 is excessive, the oil accumulates inside the refrigeration cycle apparatus to reduce the efficiency of the cycle as well as the relative movement due to the lack of oil in the compressor. The parts are not supplied with oil properly, which reduces the reliability.

On the other hand, the conventional structure of the silencer 12 mounted to communicate with the cylinder 5 to reduce the noise, as shown in Figs. 3 and 4, one side of the body portion 12a formed to have a predetermined internal space A coupling portion 12b protruding and extending in the form of a hollow tube having a predetermined length is formed at one side thereof, and an inlet 12c through which gas is introduced is formed at one side of the body portion 12a, and at one side of the coupling portion 12b. An outlet 12d through which gas is discharged is formed, and an oil discharge hole 12e through which oil is discharged is formed at the bottom of the body portion 12a. The inner space of the body portion 12a and the coupling portion 12b is formed in a resonance space shape to prevent noise generated from the cylinder 5 from being radiated to the outside, and the resonance space is introduced into the inlet 12c. It serves as a gas flow path for allowing the refrigerant gas to flow out to the outlet 12d.

The silencer 12 as described above guides the refrigerant passing through the suction pipe 13 to the inlet 12c and flows out through the outlet 12d while passing through the internal space to be sucked into the cylinder 5. At the same time, noise generated while compressing the refrigerant gas in the cylinder 5 is reduced to prevent radiation to the outside. In addition, the oil mixed with the refrigerant is filtered in the process of passing through the silencer 12, and the oil filled in the body portion 12a of the silencer is filled in the body portion 12a of the body portion 12a. It discharges through the oil discharge hole 12e formed in the bottom surface, and returns to the bottom surface of the airtight container 1. If the oil filled in the muffler 12 is not discharged, the oil filled in the muffler 12 does not maintain the resonance volume inherent in the muffler 12. Oil will be insufficient.

However, in the conventional silencer structure as described above, the oil mixed in the refrigerant is filtered while the refrigerant flows into the inlet 12c and passes through the internal space to the outlet 12d, and the filtered oil is discharged from the oil outlet hole ( 12e), the oil is supplied together with the refrigerant sucked into the cylinder 5 through the silencer 12, so that the oil is not enough to reduce the airtightness between the cylinder 5 and the piston 8, and smooth lubrication. By not doing so, there is a problem in that the compression performance is lowered and the wear is promoted.

The object of the present invention devised in view of the above point is that the oil can be smoothly supplied into the cylinder during the refrigerant is sucked into the cylinder through the silencer by the suction force generated while the piston reciprocates in the cylinder. To provide a cylinder oil supply structure of a hermetic compressor.

1 is a piping diagram showing a typical refrigeration cycle device,

2 is a cross-sectional view showing an example of a general hermetic electric compressor;

3 and 4 is a front sectional view and a side sectional view showing a silencer structure of a conventional hermetic electric compressor, respectively;

5 is a cross-sectional view of a hermetic compressor equipped with a cylinder oil supply structure of the present invention;

6 is a front sectional view of the silencer provided with a closed compressor cylinder oil supply structure of the present invention;

(Explanation of symbols for the main parts of the drawing)

5; Cylinder 20; silencer

21; Silencer body 28; Oil discharge pipe

In order to achieve the object of the present invention as described above, the refrigerant is coupled to communicate with the compressed cylinder to reduce noise as well as a certain amount of oil is accumulated on the bottom of the body portion of the silencer for guiding the flow of the refrigerant sucked into the cylinder. A cylinder oil supply structure of a hermetic compressor is provided, wherein an oil discharge pipe having a predetermined length to be discharged is formed through the bottom of the body portion.

Hereinafter, the cylinder oil supply structure of the hermetic compressor of the present invention will be described according to the embodiment shown in the accompanying drawings.

Figure 5 shows a hermetic compressor equipped with an example of the cylinder oil supply structure of the present invention, when described with reference to the first, the hermetic compressor is a hermetically sealed container (1) and a hermetically sealed container (1) having a predetermined hermetically sealed space. The stator 3 supported by the spring 2 at the bottom of the rotor and the rotor 4 inserted into the stator 3, the cylinder 5 and the shaft is formed in a predetermined shape and the gas is compressed on one side thereof The shaft insertion hole 6 is inserted into the cylinder block B positioned above the stator 3, and an eccentric portion 7a is provided at the upper end thereof, and an oil passage 7b is formed therein. A crank shaft (7) inserted into the shaft insertion hole (6) of the cylinder block (B) and pressed into the rotor (4), an oil feeder (7c) coupled to an end of the crank shaft (7), and A piston 8 inserted into the cylinder 5 so as to be linearly movable, and the piston 8 and the crankshaft 7 A connecting rod 9 for connecting the eccentric portion 7a of the crankshaft 7 to a linear reciprocating motion to convert the piston 8 into a linear reciprocating motion inside the cylinder 5, and the cylinder ( 5) a valve assembly 10 coupled to the end of the head assembly, a head cover 11 covering the valve assembly 10, and a silencer coupled to the head cover 11 side to communicate with the inside of the cylinder to reduce noise; 20 is configured to include.

In addition, the suction pipe 13 through which the refrigerant gas is sucked is coupled to one side of the sealed container 1, and the suction pipe 13 is connected to the evaporator 400. In addition, a discharge tube (not shown) in which the refrigerant gas is discharged is coupled to the sealed container 1, and the discharge tube is connected to the condenser 200 side.

The bottom surface of the sealed container 1 is filled with a certain amount of oil.

The silencer, as shown in Figure 6, is formed on one side of the body portion 21 formed to have a resonance space therein is formed with a coupling portion 22 protruding and extending in the form of a hollow tube so as to communicate with the resonance space and the body An inlet 23 through which the refrigerant gas flows into the resonance space is formed at one side of the unit 21, and an outlet 24 through which the refrigerant gas passed through the resonance space is formed at one side of the coupling part 22.

The resonance space has a diaphragm 25 formed inside the body portion 21 and is divided into a first resonance chamber (a) and a second resonance chamber (b), and the first resonance chamber (a) and the first resonance chamber are formed inside the body portion 21. 2 The first connecting pipe 26 having a predetermined length is formed in the diaphragm 25 so that the resonance chamber b communicates therewith, and passes through the first resonance chamber a and the diaphragm 25 and at the end thereof. The second connecting pipe 27 having a predetermined length is formed to communicate with the coupling portion 22 such that the second resonance tube b is positioned in the second resonance chamber b. The outlet 24 is formed to communicate with the first resonance chamber (a) and the end of the second connecting pipe 27 is located on the bottom side of the body portion 21.

The oil discharge pipe 28 has a predetermined length and is positioned so as to protrude at a predetermined height into the bottom surface of the body portion 21 as a tube through which the inside thereof is penetrated, and to a predetermined height outside the bottom surface of the body portion 21. It is positioned to protrude.

The silencer 20 has an engaging portion 22 fixedly coupled to the head cover 11 side so that the outlet 24 communicates with the cylinder 5 and an end of the suction pipe 13 on the inlet 23 side. Will be located.

Reference numeral 14 is a connecting pin, and 15 is a sleeve (SLEEVE).

Hereinafter, the operation and effect of the cylinder oil supply structure of the hermetic compressor of the present invention will be described.

First, the operation of the hermetic compressor will be described. First, when power is applied and the rotor 4 rotates due to the interaction of the stator 3 and the rotor 4, the rotor 4 rotates. The crankshaft 7 pressed into the rotor 4 is rotated. The connecting rod 9 coupled to the eccentric portion 7a of the crankshaft by the rotation of the crankshaft 7 converts the rotational movement into a linear reciprocating motion to cause the piston 8 to reciprocate in the cylinder 5. do. The refrigerant gas sucked into the suction pipe 13 by the operation of the valve assembly 10 together with the linear reciprocating motion of the piston 8 passes through the silencer 20 to the cylinder 5 and the piston 8. It is sucked into the compression space formed by the compressed space, and is discharged at a high temperature and high pressure, and the discharged refrigerant gas is discharged through the discharge pipe.

In addition, the oil filled in the bottom surface of the sealed container 1 by the oil feeder 7c coupled to the end of the crankshaft 7 together with the rotation of the crankshaft 7 is sucked up through the oil passage 7b. Scattered through the end of the crankshaft 7 is supplied to the component in which the relative motion occurs.

On the other hand, the refrigerant gas discharged to the discharge tube of the compressor is mixed with the oil passes through the condenser 200 and expansion mechanism 300 and the evaporator 400 constituting the refrigeration cycle device together with the oil and then back to the compressor 100 The incoming cycle is repeated. In such a process, the refrigerant gas flowing into the compressor 100 is sucked into the cylinder 5 through the suction pipe 13 and the silencer 20 of the compressor, and the refrigerant gas passing through the suction pipe 13 is silencer 20. The suction through the cylinder (5) through the following is as follows. That is, the refrigerant gas passing through the suction pipe 13 flows into the inlet 23 of the silencer, passes through the first resonance chamber a, and then flows through the first connection pipe 26 to the second resonance chamber b. The refrigerant gas passing through the second resonance chamber (b) flows out to the outlet (24) through the inner passage of the second connecting pipe (27) and the coupling portion (22) and is sucked into the cylinder (5).

In the above process, the oil is filtered while the refrigerant gas mixed with the oil flowing into the inlet 23 of the silencer passes through the resonance space, and is accumulated on the bottom surface of the silencer body 21. As the same process is repeated, the oil accumulated on the bottom surface of the silencer body portion 21 becomes a predetermined amount or more, and when the oil discharge pipe 28 becomes higher than the height of the oil discharge tube 28, the silencer body portion 21 is discharged. There is always a certain amount of oil at the bottom.

In this way, since the oil is always accumulated on the bottom of the silencer body 21, the refrigerant gas flowing into the silencer 20 is filtered while the oil mixed therein is filtered to separate oil and the oil accumulated on the bottom of the body 21. It comes in contact with the oil and flows out through the outlet 24 and is sucked into the cylinder 5, so that an appropriate amount of oil is supplied to the cylinder 5 together with the suction of the refrigerant gas.

On the other hand, the oil discharged to the oil discharge pipe 28 is returned to the bottom surface of the sealed container (1).

As described above, the cylinder oil supply structure of the hermetic compressor according to the present invention is coupled to communicate with the cylinder in which the refrigerant gas is compressed to reduce noise and always inside the silencer for guiding the suction of the refrigerant gas into the cylinder. As a certain amount of oil accumulates, oil is contained in the refrigerant gas sucked into the cylinder through the silencer, and oil is supplied to the cylinder to increase the airtightness between the cylinder and the piston, thereby improving the compression performance as well as the cylinder and the piston. Deterioration of wear between the effect is to increase the reliability.

Claims (2)

The oil discharge pipe having a certain length is coupled to communicate with the cylinder in which the refrigerant is compressed to reduce noise and discharged when a certain amount of oil is accumulated on the bottom of the body portion of the silencer for guiding the flow of the refrigerant sucked into the cylinder. Cylinder oil supply structure of a hermetic compressor, characterized in that formed through the bottom. The cylinder oil supply structure of a hermetic compressor of claim 1, wherein a part of the oil discharge pipe is positioned at a predetermined height inside the bottom surface of the body portion.