KR200160409Y1 - Cylinder block of a reciprocating compressor - Google Patents

Abstract

The present invention relates to a cylinder block of a reciprocating compressor, and an object thereof is to improve a cylinder block in which a piston coupled to a connecting rod reciprocates and rotatably supports a rotating shaft, thereby reducing manufacturing cost and simultaneously connecting the connecting rod and the piston. To facilitate.

According to the cylinder block of the reciprocating compressor according to the present invention, the cylindrical support for rotatably supporting the rotating shaft 230 on the cylinder block 310 provided with the compression chamber 320 so that the piston 330 reciprocates Since the bearing part 250 is integrally formed, manufacturing cost is reduced. In addition, the compression chamber 320 forms an assembly guide groove 311 at the bottom of the cylinder block 310 corresponding to the inlet, and through this the fastening pins 334 so that the connecting rod 340 and the piston 330 are coupled. By fitting, it is possible to facilitate the assembly of the connecting rod 340 and the piston 330 while also integrally configuring the support bearing portion 250.

Description

Cylinder Block of Reciprocating Compressor

The present invention relates to a cylinder block of a reciprocating compressor, and more particularly, to a cylinder block of a reciprocating compressor rotatably supporting a rotating shaft is formed with a compression chamber in which the piston coupled to the connecting rod is moved forward and backward.

In general, a reciprocating compressor has a function of sucking refrigerant into a container and supplying it into a refrigeration cycle by compressing it into a high pressure and a high pressure in a refrigerating cycle such as a refrigerator that performs four processes of compression, condensation, expansion, and evaporation using a refrigerant as a medium. Perform.

As shown in FIG. 1, the conventional reciprocating compressor having such a function includes a driving unit 20 for generating power in the hermetically sealed container 10 by combining the upper container 11 and the lower container 12. A compression unit 30 is provided to receive and compress the refrigerant to receive power, and an oil for lubricating and cooling each sliding unit is stored at the bottom of the sealed container 10.

The driving unit 20 is installed on the top of the sealed container 10, the stator 21 for applying the power to form a magnetic field, the rotor 22 to rotate in interaction with the stator 21, the rotor 22 It is provided with a rotating shaft 23 is axially press-fitted in the center of the rotation and integrally provided at the lower end of the eccentric shaft 24. In addition, a support bearing 25 for supporting the rotor 22 and the rotating shaft 23 so as to rotate smoothly is installed under the rotor 22. The support bearing 25 is axially rotated in the center of the support shaft 25b is inserted into the center of the rotary shaft 23 is coupled, the lower end is fastened to the upper surface of the cylinder block 31 bolt 25a is connected to the rotary shaft ( 23 and the rotor 22 are supported to rotate.

In addition, the compression unit 30 supports the driving unit 20 from the lower side and the cylinder block 31 is formed with a compression chamber 32 in which the refrigerant is sucked and compressed therein, a suction network for guiding the suction and discharge of the refrigerant ( A valve plate having a cylinder head 35 provided with a discharge hole 35b and a suction hole 36a and a discharge hole 36b interposed between the cylinder head 35 and the cylinder 32 and selectively opened and closed ( 36).

On the other hand, a piston 33 for linearly reciprocating the compression chamber 32 is installed, which is connected to the eccentric shaft 24 through the connecting rod 34 so that the eccentric rotation of the rotary shaft 23 is a linear reciprocating motion. It is converted into and moves forward and backward in the cylinder (32).

Reference numerals 40 and 41 are refrigerant inlet tubes through which refrigerant enters the sealed container 10 from the outside, and refrigerant discharge tubes through which compressed refrigerant is discharged to the outside, and 50 denotes intake noise generated when refrigerant enters. It is a suction muffler.

In the conventional reciprocating compressor configured as described above, as the power is applied, rotational force is generated by the interaction of the stator 12 and the rotor 22, and the rotation shaft 23 is integrally rotated together with the rotor 22. The rotational movement of the rotary shaft 23 is converted into a linear reciprocating motion of the piston 33 through the connecting rod 34 coupled with the eccentric shaft 24.

Therefore, the piston 33 reciprocates the inside of the compression chamber 32, so that suction and compression of the refrigerant are performed. That is, when the piston 33 operates at the bottom dead center and is in the suction process, the refrigerant gas of low pressure is sucked into the compression chamber 32 through the suction hole 36a, and the piston 33 operates at the top dead center to compress the gas. When in the discharging process, the refrigerant gas compressed to high pressure is guided to the discharge chamber 35b through the discharge hole 36b, and then supplied to the outside through the refrigerant discharge pipe 41. This operation is performed once per rotation of the rotary shaft (23).

However, such a compressor has a problem in that the manufacturing cost of these compressors is increased because the support shaft 25 supporting the rotating shaft 23 and the rotor 22 and the cylinder block 31 in which the compression chamber 32 is formed are separately formed. In addition, the connection between the eccentric shaft 24 and the connecting rod 34 is difficult, there is a problem that its assembly workability is lowered.

This will be described in detail with reference to FIG. 2 as follows. First, the coupling rod 34 has coupling holes 34a and 34b formed at both ends thereof, and the coupling hole 34a of one end and the coupling hole 33b of the piston 33 coincide with each other and the coupling pin 33a. In the coupled state by using the, the piston 33 is inserted into the compression chamber (32).

Then, the eccentric shaft 24 of the rotating shaft 23 inserted into the support bearing 25 is inserted into the coupling hole 34b of the other end of the connecting rod 34 located below the cylinder block 31, and then the support bearing 25 ) Is fixed to the upper surface of the cylinder block 31 by using a bolt 25a (see FIG. 1), so that the rotational movement of the rotary shaft 23 connects the eccentric shaft 24 and the piston 33. It converts into the linear reciprocating motion of the piston 33 by this.

However, since the support bearing 25 supporting the rotary shaft 23 and the cylinder block 31 in which the compression chamber 32 is formed are dualized, the support bearing 25 and the cylinder block 31 are die-cast separately. casting) increases the manufacturing cost.

In addition, since the support bearing 25 is mounted on the upper surface of the cylinder block 31 corresponding to the body part inside the compressor, the assembly work by performing the bolt (25a) to firmly fix the support bearing 25 There is a problem that the performance productivity is lowered.

The present invention is to solve this problem, the main purpose of the present invention is to unify the parts by constituting a support bearing unit to support the rotary shaft to rotate on the top of the cylinder block is provided with a compression chamber to reciprocate the piston It is to provide a cylinder block of the reciprocating compressor to reduce the manufacturing cost.

And the secondary purpose of the present invention is to form an assembly guide groove in the lower end of the cylinder block corresponding to the inlet of the compression chamber through the coupling rod and the piston through this, while assembling the support rod and the assembly of the support rod integrally It is to provide a cylinder block of a reciprocating compressor that can be easily.

1 is a cross-sectional view showing the overall configuration of a conventional reciprocating compressor.

2 is a cross-sectional exploded view showing a conventional coupling structure of the connecting rod.

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

4 is an exploded cross-sectional view schematically showing a connecting rod coupling structure in the cylinder block to which the present invention is applied.

<Description of the symbols for the main parts of the drawings>

100 ‥ Airtight Container 200 ‥ Drive

250 ‥ Support Bearing 300 ‥ Compression

310 ‥ Cylinder Block 311 ‥ Assembly Guide Groove

320 ‥ Compression Chamber 300 ‥ Piston

331 ‥ Fastener 332 ‥ Joining Space

334 ‥ fastening pin 336 ‥ fastening pin

340 ‥ connection rod 341, 342 ‥ coupling hole

The present invention for achieving the above object is a sealed container, a rotating shaft installed in the sealed container and provided with an eccentric shaft that rotates eccentrically, a cylinder block having a compression chamber in which the refrigerant is sucked and discharged inside the sealed container, and the compression chamber is formed therein. Reciprocating motion of the piston with a fastening hole formed at the rear end, and coupling holes are formed at both ends so that the piston is linearly reciprocated by the rotational movement of the eccentric shaft. In the compressor, a cylindrical support bearing part is integrally formed on the upper part of the cylinder block so as to be rotatably supported therethrough, and one end of the connecting rod is coupled to the piston at the lower part of the cylinder block corresponding to the inlet of the compression chamber. Assembly guide groove, which guides the compression chamber to be located at the entrance of the connection chamber It is a configuration characterized in that the fastening pin is coupled to one end of the coupling hole and the fastening hole is coupled to fasten one end of the piston and the connecting rod.

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 showing the overall structure of the reciprocating compressor according to the present invention, Figure 4 is a schematic view showing a coupling structure of the connecting rod in the cylinder block to which the present invention is applied.

As shown in FIG. 3, the reciprocating compressor according to the present invention receives a driving unit 200 for generating power and a power in the sealed container 100 in which oil is stored, and a compression unit 300 for sucking and discharging the refrigerant. It is provided.

The driving unit 200 is installed above the sealed container 100, the stator 210 to form an electric field when the power is applied, the rotor 200 installed inside the stator 210 to rotate in interaction with the electric field, the rotor ( An end portion is pressed in the axial direction in the center of the 220 and integrally rotates, and includes a rotation shaft 230 having an eccentric shaft 240 formed at its lower end.

The compression unit 300 interlocked by receiving the power of the driving unit 200 is installed in the lower portion of the sealed container 100, which is a cylinder block 310 in which a compression chamber 320 is formed to compress and discharge refrigerant. The cylinder head 350 includes a suction chamber 351 for guiding refrigerant suction and discharge, a discharge chamber 352, and a piston 330 reciprocating the compression chamber 320. A valve plate 360 having a suction hole 361 and a discharge hole 362 is interposed between the front end of the cylinder block 310 and the cylinder head 350, which are selectively opened and closed according to the reciprocating motion of the piston 330. do. In addition, the suction muffler 500 is installed above the cylinder head 350 to shield the suction noise generated when the refrigerant is introduced through the refrigerant suction pipe 400.

Reference numeral 410 is a refrigerant discharge tube for guiding the refrigerant discharged through the discharge hole 362 to the outside.

In addition, the upper portion of the cylinder block 310 is provided with a cylindrical support bearing part 250 for supporting the rotation shaft 230 and the rotor 220 to rotate smoothly. The support bearing part 250 is manufactured integrally with the cylinder block 310, and a rotation support hole 251 is formed in the axial direction through the cutting process. Therefore, the rotary shaft 230 is inserted through the rotary support hole 251, and the upper surface of the support bearing part 250 supports the lower surface of the rotor 220 to contact the rotor 220 and the rotary shaft 230. This unit is rotatably supported.

In addition, the eccentric shaft 240 and the piston 330 at the lower end of the rotation shaft 230 rotatably supported are connected via a connecting rod 340. That is, the connecting rods 340 for operating the piston 330 are provided with coupling holes 341 and 342 at both ends thereof, so that one end of the connecting rod 340 corresponds to the inlet of the compression chamber 320. Located in the inlet of the compression chamber 320 through the assembly guide groove 311 formed in the lower portion of the block 310, the other end of the connecting rod 340 to the eccentric shaft 240 through the coupling hole 342 Fitted and combined. Accordingly, the eccentric rotation of the eccentric shaft 240 is converted into a linear reciprocating motion of the piston 330, so that the refrigerant is sucked into the compression chamber 320 and discharged to the outside. At this time, one end of the connecting rod 340 is coupled to the piston 330 through the fastening pin 334, the end of the fastening pin 334 to prevent the separation of the fastening pin 334 during driving the piston 330 The fixing pin 336 is coupled to the) is provided.

Thus, the configuration and coupling structure of the connecting rod 340 for driving the piston 330 will be described in more detail with reference to FIG. 4 as follows.

First, the support bearing portion 250 is integrally formed on the upper portion of the cylinder block 310, the rotation support hole 251 is supported on the support bearing portion 250, and the compression chamber 320 is cut on the cylinder block 310. It is prepared by. Therefore, the assembly operator inserts an end of the rotary shaft 230 provided with the eccentric shaft 240 from the lower side to the upper side of the rotary support hole 251, and at the upper end of the rotary shaft 230 exposed to the upper side of the rotary support hole 251. After pressing the rotor 220, the eccentric shaft 240 is positioned in the left direction (a position corresponding to the bottom dead center position of the piston 330). In addition, the lower portion of the cylinder block 310 corresponding to the inlet portion of the compression chamber 320 (the lower portion of the cylinder block 310 in contact with the bottom dead center position of the piston 330) is assembled to be associated with the compression chamber 320. The guide groove 311 is processed. Accordingly, one end of the connection rod 340 is positioned at the inlet of the compression chamber 320 through the assembly guide groove 311, and the other end of the connection rod 340 is coupled with the eccentric shaft 240.

The piston 330 has the same inner diameter as the coupling space 332 at which one end of the connecting rod 340 is inserted and the coupling hole 341 at one end of the connecting rod 340 and communicates with the coupling space 332 in the vertical direction. The fastening hole 331 is formed to be. Accordingly, one end of the connecting rod 340 is inserted into the coupling space 332 to push the piston 330 from the outlet side of the compression chamber 320 so that the coupling hole 341 and the fastening hole 331 coincide in the vertical direction. Inserting and fastening the fastening pin 334 into the fastening hole 331 and the coupling hole 341 at the same time through the assembly guide groove 311 in this state, one end of the connecting rod 340 is coupled to the piston 330 do. In addition, the fixing pin 336 is inserted into the piston 330 through the fixing hole 333 formed in the axial direction and inserted to penetrate the linking hole 335 formed at the upper end of the fastening pin 334. The upper end is fixed to the piston 330, thereby preventing separation of the connecting rod 340 and the piston 330 during driving.

As a result, by integrally manufacturing the support bearing portion 250 for rotatably supporting the rotating shaft 230 on the upper portion of the cylinder block 310, the compression chamber 320 is formed, the parts are united to reduce manufacturing costs and improve productivity. One end of the connection rod 340 and the piston 330 may be easily assembled through the assembly guide groove 311 provided at the bottom of the cylinder block 310.

As described in detail above, according to the cylinder block of the reciprocating compressor according to the present invention, a cylindrical support bearing part for rotatably supporting a rotating shaft on an upper portion of the cylinder block provided with a compression chamber so that the piston reciprocates is integrally formed. Since the manufacturing cost is reduced. In addition, by forming an assembly guide groove in the lower end of the cylinder block corresponding to the inlet of the compression chamber and inserting the fastening pin to couple the connecting rod and the piston through it, it is easy to assemble the connecting rod and the piston while forming a support bearing unit integrally. It can be done.

Claims (1)

The airtight container 100, the rotary shaft 230 installed in the airtight container 100 and provided with an eccentric shaft 240 that rotates eccentrically, and a compression chamber in which the refrigerant is sucked and discharged inside the airtight container 100. A cylinder block 310 having a 320 formed thereon, a piston 330 reciprocating the compression chamber 320 and a fastening hole 331 formed at a rear end thereof, and the piston 330 rotating the eccentric shaft 240. Coupling holes 341 and 342 are formed at both ends so as to linearly reciprocate by movement, and one end is coupled to the piston 330 and the other end is coupled to the eccentric shaft 240. In the same type compressor, a cylindrical support bearing part 250 is integrally formed on the cylinder block 310 so that the rotary shaft 230 can be rotatably supported therein, and the inlet of the compression chamber 320 is provided. One portion of the connecting rod 340 is disposed below the cylinder block 310 corresponding to the portion. Assembling hole of one end of the connecting rod 340 through the assembly guide groove 311, the assembly guide groove 311 for guiding the end is located in the inlet of the compression chamber 320 to be coupled to the piston 330 341 and the cylinder block of the reciprocating compressor, characterized in that the coupling pin 334 is fitted to be coupled to the fastening hole 331 to fasten one end of the piston 330 and the connecting rod 340.