KR20030064164A - Apparatus for discharging gas small type reciprocating compressor - Google Patents

Abstract

PURPOSE: A gas discharge apparatus of a small reciprocating compressor is provided to exactly open and shut a discharge passage to which gas is discharged and to secure excellent response property. CONSTITUTION: A gas discharge apparatus of a small reciprocating compressor includes a discharge passage having a slant stepped-sealing face(66) on a side of a frame(60) with a cylinder-through hole(61) in which gas is compressed; an inertial-cone valve(110) having a sealing face coming in contact with the slant stepped-sealing face of the discharge passage; a leaf spring(130) disposed inside the discharge passage to have predetermined intervals with the inertial-cone valve in suction stroke of pistons(40,50); and a discharge tube(120) forming a discharge hole(122) inside. The inertial-cone valve is inserted into the discharge passage and moved by pressure difference. The discharge tube is inserted into the discharge passage and the discharge tube fixes the leaf spring. Thus, wear of the discharge passage and the inertial-cone valve is suppressed and exact securing is performed. Accordingly, the life span of parts is lengthened and sealing performance is improved. Also, the response property of the inertial-cone valve is improved.

Description

Gas discharge device for small reciprocating compressors {APPARATUS FOR DISCHARGING GAS SMALL TYPE RECIPROCATING COMPRESSOR}

The present invention relates to a gas discharge device of a small reciprocating compressor, and more particularly, to a gas discharge device of a small reciprocating compressor that can accurately open and close the discharge flow path through which gas is discharged, as well as excellent response. .

1 illustrates an example of a small reciprocating compressor currently under development, and as illustrated therein, the small reciprocating compressor may include first and second reciprocating motors 20 mounted on both sides of the container 10, respectively. When the 30 is operated, the first and second pistons 40 are connected with the linear reciprocating driving force of the first and second reciprocating motors 20 and 30 to the first and second reciprocating motors 20 and 30, respectively. Frame 60 mounted within the vessel 10 such that the first and second pistons 40 and 50 are positioned between the first and second reciprocating motors 20 and 30. Are linearly reciprocated in the cylinder through-holes 61). At this time, the compression space P is formed by the end surfaces of the first and second pistons 40 and 50 and the cylinder through-hole 61. As the first and second pistons 40 and 50 linearly reciprocate in the cylinder through-holes 61 of the frame, respectively, the pressure difference between the cylinder through-holes 61 and the operation of the valves allow the container 10 to be moved. The suction pipe 11 is coupled to the both sides of the suction through the inside of the cylinder through-hole 61 is compressed and discharged through the discharge flow path (F) formed on one side of the frame 60, the same process is repeated Done.

Reference numerals 70 and 71 denote resonant spring units.

On the other hand, the gas discharge structure in which the compressed gas is sucked into the cylinder through-hole 61 of the frame is discharged in accordance with the linear reciprocating motion of the first and second pistons 40 and 50 in the process, as shown in FIG. As described above, the discharge passage F is formed at one side of the frame 60 so as to communicate with the cylinder through hole 61. The discharge passage F has a predetermined depth in the shape of a cone so as to be extended after the first hole 62 and the first hole 62 formed to have a predetermined inner diameter and depth on the inner wall of the cylinder through hole 61. Second hole 64 formed to have a larger inner diameter of the conical hole 63 so as to communicate with the through hole 12 formed in the container 10 after the formed conical hole 63 and the conical hole 63. )

And a conical valve 80 having a spring insertion portion 82 protruding to have a predetermined outer diameter and a height on a long diameter surface of the cone portion 81 formed in a cone shape so as to correspond to the cone hole 63 of the discharge passage F. FIG. ) Is inserted into the conical hole 63 of the discharge passage F, and the discharge tube 90 is coupled to the second hole 64 of the discharge passage F. The discharge tube 90 is formed to have an outer diameter and a length corresponding to the inner diameter of the second hole 64, and a discharge hole 91 penetrated therein is formed to protrude to have a predetermined outer diameter and a height at an end thereof. A spring insert 92 is provided. In this case, the discharge tube 90 is disposed in the second discharge path F so that the spring insertion part 92 of the discharge pipe 90 and the spring insertion part 82 of the conical valve 80 have a predetermined interval. It is fixedly coupled to the hole 64.

The valve spring 100 is coupled between the conical valve 80 and the discharge tube 90 to elastically support the conical valve 80. The valve spring 100 is formed of a circular coil spring, one side of which is coupled to the valve inserting portion 92 of the discharge pipe 90 and the other side of the valve spring 100 is inserted into and coupled to the valve inserting portion 82 of the conical valve.

The operation of the gas discharge structure as described above is as follows.

First, as shown in FIG. 3, when the driving force of the first and second reciprocating motors 20 and 30 is received, the first and second pistons 40 and 50 simultaneously move to the bottom dead center. Due to the pressure difference between the frame cylinder through holes, the outer peripheral surface of the conical portion 81 of the conical valve and the inner peripheral surface of the cone hole 63 of the discharge passage F are brought into close contact with each other, so that the discharge passage F is blocked, and the gas passes through the cylinder through hole. That is, it is sucked into the compression space (P).

When the first and second pistons 40 and 50 move to the top dead center at the same time, the gas sucked into the cylinder through-hole 61 of the frame is gradually compressed and the compressed pressure is compressed above a predetermined pressure. As the conical valve 80 elastically supported by the valve spring 100 is pushed, the discharge flow path F is opened, and the compressed gas is discharged, and the discharged compressed gas is discharged through the discharge hole 91 of the discharge pipe. It will exit to the condenser side.

However, as described above, the conical valve 80 that opens and closes the discharge flow path opens and closes the discharge flow path while being always elastically supported by the valve spring 100 which is a coil spring. During the opening and closing movement, the movement of the conical valve 80 is not made in a straight line shape, so that abrasion occurs between the conical portion 81 and the conical hole 63 of the conical valve, as well as the conical portion of the conical valve ( 81) the contact between the conical hole 63 is not made accurately, there is a problem that not only the leakage of the compressed gas occurs, but also shorten the life of the parts.

SUMMARY OF THE INVENTION An object of the present invention devised in view of the above problems is to provide a gas discharge device for a compact reciprocating compressor that enables not only accurate opening and closing of a discharge flow path through which gas is discharged, but also excellent response. .

1 is a cross-sectional view showing a compact reciprocating compressor currently in development;

2 is a cross-sectional view showing a gas discharge structure of a conventional compact reciprocating compressor;

3 is a cross-sectional view showing an operating state of the compact reciprocating compressor gas discharge structure;

4 is a cross-sectional view of a small reciprocating compressor gas discharge device of the present invention;

5 and 6 are cross-sectional views each showing an operating state of a small reciprocating compressor gas discharge device of the present invention.

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

40,50; Piston 60; frame

61; Cylinder through hole 66; Inclined step sealing surface

110; Inertia cone valve 120; Discharge tube

122; Discharge hole 130; Leaf spring

F '; Discharge flow path

In order to achieve the object of the present invention as described above, a discharge passage having an inclined step sealing surface on one side of a frame having a cylinder through-hole in which gas is compressed, and a sealing surface which is in contact with the inclined step sealing surface of the discharge flow path. And an inertial cone valve inserted into the discharge passage and moved by a pressure difference, a leaf spring positioned inside the discharge passage so as to form a predetermined interval with the inertia cone valve during the suction stroke of the piston, and the discharge inside the discharge passage. Provided is a gas discharge device for a small reciprocating compressor, comprising a discharge pipe through which a hole is penetrated to be inserted into the discharge passage and fixes the leaf spring.

Hereinafter, the gas discharge device of the compact reciprocating compressor of the present invention will be described according to the embodiment shown in the accompanying drawings.

Figure 4 shows an example of a small reciprocating compressor gas discharge device of the present invention, as shown, the gas discharge device of the small reciprocating compressor is first formed in a predetermined shape in the interior of the container 10 ( 60 is fixedly coupled to form a through-cylinder cylinder through-hole 61 of the frame and the first piston 40 and the second piston 50 is inserted into both sides of the cylinder through-hole 61, respectively.

A discharge flow path F 'is formed on one side of the frame 60 so as to communicate with the cylinder through hole 61 formed therein, and the discharge flow path F' has a predetermined inner diameter on the inner wall of the cylinder through hole 61. To the first hole 65 formed to have a depth and the first hole 65 and the slope step sealing surface 66 and the slope step sealing surface 66 formed to have a predetermined depth in a conical shape so as to be expanded after the first hole 65. Subsequently, the second hole 67 is formed to have an inner diameter larger than the long diameter of the inclined step sealing surface 66 so as to communicate with the through hole 12 formed in the container 10, and the first hole 65. And the discharge flow path F 'including the inclined stepped sealing surface 66 and the second hole 67 are formed radially in the cylinder through hole 61 of the frame.

In addition, an inertial cone valve 110 is inserted into the discharge passage F ′. The inertial cone valve 110 has a predetermined outer diameter and height in the center of the cone portion 111 and the long diameter surface of the cone portion 111 formed in the conical shape corresponding to the inclined step sealing surface 67 of the discharge passage. Protruding support portion 112 is provided and the outer circumferential surface of the cone portion 111 forms a sealing surface.

The discharge pipe 120 having the discharge hole 122 therein is inserted into and coupled to the second hole 67 in the discharge flow path of the frame. The discharge pipe 120 has a body 121 having an outer diameter and a predetermined length inserted into and fixed to the discharge flow path F ', and a discharge hole 122 formed through the inside of the body 121. The discharge hole 122 is provided in the first inner diameter portion 122a and the first inner diameter portion 122a which are formed to have a predetermined depth and an inner diameter at an end surface located inside the discharge passage F ′. Subsequently, the second inner diameter portion 122b penetrates to have an inner diameter smaller than that of the first inner diameter portion 122a.

And the leaf spring 130 is coupled to the inside of the discharge passage (F ') so as to form a predetermined interval with the inertial valve 110 during the suction stroke of the piston. The leaf spring 130 is formed of a plurality of arms by forming a plurality of through grooves in the thin circular thin plate in the form of a general leaf spring 130. The inertial cone valve 110 is elastically supported by the leaf spring 130 after moving a predetermined distance during the discharge stroke of the piston.

The leaf spring 130 has a step portion 68 formed on an inner circumferential surface of the discharge passage F ′, that is, an inner circumferential surface of the second hole 67 of the discharge passage, and is discharged in a state where the leaf spring 130 is located at the step portion 68. It is preferable to be fixedly coupled by the end surface of the discharge pipe 120 is inserted into the flow path (F ').

Hereinafter, the operation and effect of the gas discharge device of the compact reciprocating compressor of the present invention will be described.

First, as shown in FIG. 5, when the first and second pistons 40 and 50 simultaneously move to the bottom dead center, the inertial cone valve ( The outer circumferential surface of the conical portion 111 of 110 and the inclined step sealing surface 66 of the discharge passage F 'are in close contact with each other, and the discharge passage F' is blocked, so that gas is sucked into the cylinder through hole 61.

When the first and second pistons 40 and 50 simultaneously move to the top dead center, as shown in FIG. 6, the gas sucked into the cylinder through-hole 61 of the frame is gradually compressed and the first The inertial cone valve 110 is moved while the inertial cone valve 110 is moved by the pressure difference between the end surface of the two pistons 40 and 50 and the compression space P formed by the cylinder through hole 61 and the discharge side. A gap is generated between the sealing surface of 110 and the inclined step sealing surface 66 of the discharge passage F '. In this case, when the inertial cone valve 110 is moved for the first time, the inertia cone valve 110 is opened while not supported by the leaf spring 130, and is moved elastically by the leaf spring 130 when moved over a predetermined distance. When a gap is generated between the sealing surface of the inertial cone valve 110 and the inclined step sealing surface 66 of the discharge passage F ′, the compressed gas is discharged from the compression space P through the gap. It is discharged to the condenser side through the discharge hole 122 of the discharge tube.

When the first and second pistons 40 and 50 move to the bottom dead center again, the inertial cone valve 110 is moved by the pressure difference of the compression space P, and the inertial cone valve 110 is moved. ) And the inclined step sealing surface 66 of the discharge passage (F ') is in close contact with the discharge passage (F') while the gas is sucked into the compression space (P). At this time, the inertial cone valve 110 is moved while receiving the elastic force in a state that is elastically supported by the leaf spring (130).

In the present invention, the leaf spring 130 is mounted at regular intervals with the inertia cone valve 110, which is a discharge valve, so that the inertia cone valve 110 is closed, that is, the sealing of the inertia cone valve 110. At the time when the inclined step sealing surface 66 of the surface and the discharge passage is seated, the inertia cone valve 110 is not affected by the leaf spring 130 and the inertia cone valve 110 is opened. That is, even when the sealing surface of the inertial cone valve 110 and the inclined stepped sealing surface 66 of the discharge passage fall, the inertial cone valve 110 is not affected by the leaf spring 130 and thus the discharge passage The opening and closing of (F ') is not only accurate, but also the wear between parts is suppressed.

In addition, the plate spring 130 positioned at a predetermined distance from the inertial cone valve 110 may not only open to some extent when the inertial cone valve 110 is opened, but also the inertial cone valve 110. ) Is closed when the restoring force of the leaf spring 130 is increased and the inertia cone valve 110 is not affected by the leaf spring 130 at the time when the discharge flow path F 'is opened and closed. This makes the valve responsive.

As described above, the gas discharge device of the compact reciprocating compressor according to the present invention is suppressed between the discharge passage in which gas is discharged and the inertial cone valve for opening and closing the discharge passage, and the accurate seating is achieved. In addition to extending the service life, the sealing performance is increased, and the inertial valve of the discharge valve is responsive, thereby improving the opening and closing performance of the discharge channel and improving the reliability.

Claims (2)

A discharge passage having an inclined step sealing surface on one side of the frame having the cylinder through hole through which gas is compressed is provided, and a sealing surface which is in contact with the inclined step sealing surface of the discharge flow path, and inserted into the discharge flow path to insert a pressure difference. An inertial cone valve moving by the valve, a leaf spring positioned inside the discharge passage so as to form a predetermined interval with the inertia cone valve during the intake stroke of the piston, and a discharge hole penetrated therein and inserted into the discharge passage; In addition, the gas discharge device of the compact reciprocating compressor comprising a discharge pipe for fixing the leaf spring. According to claim 1, wherein the inner circumferential surface of the discharge flow path is provided with a stepped spring plate is located in the stepped portion and the leaf spring located in the stepped portion is fixedly coupled by the end surface of the discharge pipe is inserted into the discharge flow path Gas discharge device of a small reciprocating compressor, characterized in that.