JP2559084Z - - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a valve device of a hermetic reciprocating compressor, and more particularly, to a hermetic reciprocating compressor for compressing a low-pressure refrigerant gas or the like. The present invention relates to a valve device of a machine. 2. Description of the Related Art Conventionally, a valve device for a hermetic reciprocating compressor as shown in FIG. 4 has been proposed. In the figure, a cylinder head 1 'having a discharge port 2' and a suction chamber (not shown) is provided above a cylinder 3 'in which a piston 4' is provided. A valve plate 10 'having a discharge port 14' and a suction port (not shown) is provided between the valve plate 10 'and the valve plate 10'. A discharge valve 23 ', which is opened and closed so as to discharge the compressed high-pressure refrigerant gas when the piston 4' moves forward (ascends), is disposed above the valve plate 10 '. A bending valve 2 for limiting the open / close area of the discharge valve 23 'is provided in the space above the discharge valve 23'.
2 'is provided. Above the bending valve 22', a keeper space member 21 'for regulating the operation range of the discharge valve 23' and the bending valve 22 'to a predetermined position is provided. Here, the discharge valve 23 ′, the bending valve 22 ′, and the keeper member 21 ′ are supported on a valve plate 10 ′ by a guide pin 30 ′ which is mounted on the valve plate 10 ′. For fixing the pin 30 ', the valve plate 10' needs to have an appropriate thickness. In addition, the diameter of the discharge port 14 'is set to an appropriate size in order to secure conductance. That is, in such a configuration, the capacity of the discharge port 14 'is restricted to the above-described condition. A suction valve 6 ′ is provided between the valve plate 10 ′ and the cylinder 3 ′, and the piston 4 ′ is moved from the top dead center to the bottom dead center, that is, during the suction stroke. ,
The discharge valve 23 'is opened while the inner space of the cylinder 3' is kept in a vacuum state while the discharge valve 23 'is closed. In the valve device of the hermetic reciprocating compressor as described above, the piston 4 ′ is moved to the bottom dead center during the above-described suction stroke, that is, with the discharge valve 23 ′ closed. At this time, an excessive amount of the high-pressure refrigerant gas remains in the discharge port 14 '. Due to this residual gas, the transition to the vacuum state inside the cylinder 3 'is delayed, so that the suction valve 6' cannot operate smoothly and a sufficient amount of low-pressure refrigerant gas is supplied to the cylinder 3 '.
There is a problem in that it is not sucked into the inside and the compression efficiency is reduced. SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and during a suction stroke, a low-pressure refrigerant gas is smoothly sucked to greatly improve a compression effect. It is an object of the present invention to provide a valve device for a hermetic reciprocating compressor that can be operated. [0007] In order to achieve the above object, a valve device for a hermetic reciprocating compressor according to the present invention includes a valve plate having a discharge port, and the discharge port. Higher pressure refrigerant gas is realized
A discharge valve that is opened and closed as much as possible, and the delivery valve that limits the opening and closing area of the discharge valve.
The bending valve disposed above and the operating range of these discharge valve and bending valve
Valve device for hermetic reciprocating compressor comprising a keeper member for regulating the enclosure to a predetermined position
In the first, the keeper member is accommodated in an upper surface portion of the valve plate.
An accommodating space, and the bending valve and the discharge valve below the first accommodating space.
And a second housing space for housing the discharge valve below the second housing space.
And a support space provided to promote smooth opening and closing, wherein the discharge port is
A cylindrical protrusion is formed in a substantially middle portion of the support space in a fluid outlet direction,
The tip of the cylindrical protrusion is formed at the same height as the second housing space,
Both ends of the keeper member are formed in the first housing space by the bottom of the cylinder head.
It is characterized in that it is accommodated and held. Further, the discharge valve and the bending valve each have a projecting portion at one end, and a supporting portion which is supported while the projecting portion is pressed by a keeper member. A first housing space, a second housing space, and a support space are provided below the upper surface of the valve plate in order, and even if these housing spaces are provided, a suitable strength is maintained. The operation range of the discharge valve and the bending valve is restricted to a predetermined position at the peripheral portion of the obtained valve plate, that is, the keeper member that supports these valves can be securely fixed, and is formed at a substantially intermediate portion of the support space. The height of the discharge port is lower than the upper surface of the valve plate and the same height as the height of the second accommodating space, so that the volume of the discharge port is minimized while the discharge valve is smoothly opened and closed. Can be Due to the decrease in the volume of the discharge port, the amount of the residual high-pressure refrigerant gas at the discharge port when the piston reaches the top dead center and the discharge valve is closed can be minimized. When moving from the bottom dead center to the bottom dead center (that is, during the suction stroke), the internal space of the cylinder quickly shifts to a vacuum state, the suction valve opens and closes smoothly, and a larger amount of low-pressure refrigerant gas is sucked. Therefore, the compression efficiency can be improved. Further, the operating range of the discharge valve and the bending valve is reliably regulated by the support portion. An embodiment of the present invention will be described below with reference to the accompanying drawings. FIG. 1 is a sectional view showing a valve device of the hermetic reciprocating compressor of the present invention, FIG. 2 is an exploded perspective view of the valve device, and FIG. 3 is a perspective view showing a back surface of a cylinder head. is there. In FIG. 1 to FIG. 3, a discharge chamber 2 and a suction chamber 5 are formed on the back surface of the cylinder head 1. A cylinder 3 is provided below the cylinder head 1, and a piston 4 that reciprocates and sucks and compresses a low-pressure refrigerant gas is provided inside the cylinder 3. A valve plate 10 having a suction port 15 is inserted between the cylinder head 1 and the cylinder 3. Further, a first housing space 11 is formed in the upper surface of the valve plate 10 for housing a keeper member 21 for restricting an operation range of a discharge valve 23 and a bending valve 22 described below to a predetermined position. In the lower space of the first storage space 11, a discharge valve 23 that opens and closes to discharge high-pressure refrigerant gas, and a second storage space in which a bending valve 22 that limits the opening and closing area of the discharge valve 23 are stored. 12 are provided. As shown in FIG. 2, projecting portions 25 and 24 are provided at one end of the discharge valve 23 and the bending valve 22, respectively, and these projecting portions 25 and 24 are easily fitted and accommodated and held down by a keeper member. A support portion 16 that can be supported while being formed is formed. That is, since the projecting portions 25 and 24 of the discharge valve 23 and the bending valve 22 are supported by the support portion 16 while being pressed by the keeper member 21, the discharge valve 23 and the bending valve 22 The operation range is such that the operation is restricted to a predetermined position in the second accommodation space 12. When the piston 4 moves from the bottom dead center to the top dead center in the lower part of the second accommodation space 12, the discharge valve 23
A support space 13 is formed so as to open and close smoothly. In addition, this support space 1
A discharge port 14 is formed in a substantially middle portion of the nozzle 3 so that high-pressure refrigerant gas is discharged when the piston 4 is moved from bottom dead center to top dead center. The discharge port 14 is formed with a cylindrical projection in the direction of the fluid outlet substantially in the middle of the support space, and the tip of the cylindrical projection is flush with the second housing space. Is formed,
The discharge valve 23 can smoothly open and close the discharge port 14, and can ensure a sealing effect during a suction stroke. Reference numeral 6 denotes a suction valve that is opened when the space inside the cylinder 3 is in a vacuum state when the piston 4 moves from the top dead center to the bottom dead center. Next, the operation and effect of the present invention configured as described above will be described. As shown in FIGS. 1 to 3, the height of a discharge port 14 formed at a substantially intermediate portion of the support space 13 of the valve plate 10 is lower than the upper surface of the valve plate 10 and the height of the second accommodation space 12. As a result, the volume of the discharge port 14 can be minimized while the discharge valve 23 smoothly opens and closes the discharge port 14. When the piston 4 reaches the top dead center and the discharge valve 23 is closed due to the decrease in the volume of the discharge port 14, the amount of the residual high-pressure refrigerant gas at the discharge port 14 can be minimized. When the piston 4 is moved from the top dead center to the bottom dead center (that is, at the time of the suction stroke), the internal space of the cylinder 3 quickly shifts to a vacuum state, the suction valve 6 is smoothly opened and closed, and a larger Since the low-pressure refrigerant gas can be sucked, the compression efficiency can be improved. Further, with this configuration, the tip of the cylindrical projection of the discharge port 14 is strongly pressed against the discharge valve 23 during the suction stroke, preventing the high-pressure refrigerant gas from flowing back, and ensuring the sealing effect during the suction stroke. Can be. As described above, the valve device of the hermetic reciprocating compressor of the present invention minimizes the volume of the discharge port formed in the valve plate to minimize the high-pressure refrigerant gas remaining in the discharge port. When the piston in the cylinder is moved from the top dead center to the bottom dead center by this gas minimization, the suction valve is smoothly opened and closed so that the internal space of the cylinder is quickly shifted to a vacuum state. In addition to being able to suck a larger amount of low-pressure refrigerant gas, the cylindrical projection of the discharge port is in close contact with the bending valve, ensuring the sealing effect during the suction stroke, and greatly improving the efficiency of the compressor. You can do it.

[Brief description of the drawings]     FIG.   FIG. 4 is a sectional view showing the valve device of the hermetic reciprocating compressor according to the present invention.     FIG. 2   FIG. 3 is an exploded perspective view of the valve device of the hermetic reciprocating compressor according to the present invention.     FIG. 3   FIG. 3 is a perspective view showing a back surface of the cylinder head applied to the present invention.     FIG. 4   It is sectional drawing which shows the valve apparatus of the conventional hermetic reciprocating compressor.     [Explanation of symbols]   1 cylinder head   3 cylinder   4 piston   6 Suction valve   10 Valve plate   11 1st accommodation space   12 Second accommodation space   13 Support space   14 Discharge port   16 Support   21 Keeper material   22 Bending valve   23 Discharge valve   24 Projection   25 Projection

Claims (1)

[Claim 1] A valve plate having a discharge port, a discharge valve that is opened and closed so that high-pressure refrigerant gas is discharged from the discharge port, and an opening and closing area of the discharge valve is limited. The valve device for a hermetic reciprocating compressor, comprising: a bending valve disposed above the discharge valve to perform the operation, and a keeper member for restricting an operation range of the discharge valve and the bending valve to a predetermined position. A first accommodating space for accommodating the keeper member at an upper surface of the second housing space; a second accommodating space for accommodating the bending valve and the discharge valve below the first accommodating space; And a support space provided to promote smooth opening and closing of the discharge valve. The discharge port has a cylindrical projection in a fluid outlet direction at a substantially intermediate portion of the support space. Formed becomes, the leading end of the tubular projecting portion is formed at the same height as the second housing space
Both ends of the keeper member are connected to the first portion by the bottom surface of the cylinder head.
A valve device for a hermetic reciprocating compressor, wherein the valve device is accommodated and held in an accommodation space .