CN112628113A - Gas supercharging mechanism for piston movement mechanism - Google Patents

Abstract

The invention discloses a gas supercharging mechanism for a piston movement mechanism, which comprises a main hollow shell, wherein a compression space is arranged in one end face of the main hollow shell, a movable piston is arranged in the compression space, and a telescopic rod is arranged in the center of one end face of the piston. The invention can perform pressurization effect on the back of the piston used for compression, perform air type pressurization on the piston, directly act on the piston, release pressurized gas when the piston is compressed, only perform pressurization effect when the piston is compressed, and generate no reaction force when the piston is reset, so that the pressurization effect is obvious, the negative effect is low, and the compression capability of the piston is improved.

Description

Gas supercharging mechanism for piston movement mechanism

Technical Field

The invention relates to the technical field of pressurizing mechanisms, in particular to a gas pressurizing mechanism for a piston movement mechanism.

Background

At present, when air and liquid are compressed and power is output by a crank rod, piston motion is needed, but the traditional supercharging mechanism is turbo supercharging, and in actual operation, the supercharging mechanism supercharges the piston at an air compression part, but the back surface of the piston has no supercharging effect.

Disclosure of Invention

The present invention has been made to solve the above-mentioned problems occurring in the prior art, and an object of the present invention is to provide a gas pressurizing mechanism for a piston movement mechanism.

In order to achieve the purpose, the invention provides the following technical scheme: a gas booster mechanism for a piston movement mechanism comprises a main hollow shell, wherein a compression space is arranged in one end face of the main hollow shell, a movable piston is arranged in the compression space, a telescopic rod is arranged at the center of one end face of the piston, a rod body of the telescopic rod penetrates through the center of one end face of the main hollow shell, a main sealing ring is arranged at a penetrating position of the main hollow shell and the main hollow shell, a plurality of annular array auxiliary component mounting holes are formed in one end face of the compression space of the main hollow shell, a spiral spring type conflict driving mechanism is arranged in each auxiliary component mounting hole, an auxiliary sealing ring is arranged on the outer side of each spiral spring type conflict driving mechanism, a liquid flow hole is formed in one side of each spiral spring type conflict driving mechanism, the end parts of the liquid flow holes are gathered at one end, and the end parts of the liquid flow holes are provided with main component mounting holes, the spiral spring type driving mechanism comprises a main part mounting hole, a spiral spring valve rod type liquid driven control mechanism, a main hollow shell, a main air inlet hole, a valve core mounting hole, a main air inlet valve and a spiral spring type driving mechanism, wherein the spiral spring valve rod type liquid driven control mechanism is mounted inside the main part mounting hole, a plurality of annular array main exhaust holes are formed in the edge of one end, located in a compression space, of the main hollow shell, the end portion of each main exhaust hole is communicated with an annular channel arranged inside the main hollow shell, the main air inlet hole communicated with the external space and the annular channel is formed in the main hollow shell, the main air inlet hole penetrates through the main part mounting hole, a valve core mounting hole is formed in the end portion of the main air inlet hole, a main air inlet valve is mounted inside the valve core mounting hole, a main air inlet valve is arranged inside the valve core mounting hole, a main air vent communicated with the, The sealed area between the fluid flow bore and the helical spring valve stem fluid slave control mechanism is filled with hydraulic fluid.

Further, the coil spring type collision driving mechanism comprises a hollow shell for the coil spring type collision driving mechanism, a hollow structure for the coil spring type collision driving mechanism, a liquid discharge hole for the coil spring type collision driving mechanism, a moving plate for the coil spring type collision driving mechanism, a push rod for the coil spring type collision driving mechanism and a coil spring for the coil spring type collision driving mechanism; the hollow shell for the coil spring type conflict driving mechanism is internally provided with a hollow structure for the coil spring type conflict driving mechanism at the center, a liquid discharge hole for the coil spring type conflict driving mechanism is arranged at the center of one end surface of the hollow shell for the coil spring type conflict driving mechanism, a movable moving plate for the coil spring type conflict driving mechanism is arranged in the hollow structure for the coil spring type conflict driving mechanism, one end surface of the moving plate for the coil spring type abutting driving mechanism is provided with a coil spring for the coil spring type abutting driving mechanism in a compressed state, the other end surface of the moving plate for the coil spring type conflict driving mechanism is provided with a push rod for the coil spring type conflict driving mechanism, and the rod body of the push rod for the coil spring type conflict driving mechanism penetrates through the center of the other end face of the hollow shell for the coil spring type conflict driving mechanism.

Further, coil spring formula conflict hollow shell for actuating mechanism installs in the inside of main hollow shell, just coil spring formula conflict hollow shell for actuating mechanism's overall structure inlays completely in the structure of main hollow shell inside.

Further, the coil spring type abutting driving mechanism is communicated with one end of the liquid flowing hole through a liquid discharging hole.

Further, the helical spring valve rod type liquid driven control mechanism comprises a hollow shell for the helical spring valve rod type liquid driven control mechanism, a moving space for the helical spring valve rod type liquid driven control mechanism, a spring compression space for the helical spring valve rod type liquid driven control mechanism, a first vent hole for the helical spring valve rod type liquid driven control mechanism, a second vent hole for the helical spring valve rod type liquid driven control mechanism, a valve rod for the helical spring valve rod type liquid driven control mechanism, a third vent hole for the helical spring valve rod type liquid driven control mechanism, a moving plate for the helical spring valve rod type liquid driven control mechanism, a helical spring for the helical spring valve rod type liquid driven control mechanism and a liquid vent hole for the helical spring valve rod type liquid driven control mechanism; a moving space for the spiral spring valve rod type liquid driven control mechanism is arranged at one end inside the hollow shell for the spiral spring valve rod type liquid driven control mechanism, a spring compression space for the spiral spring valve rod type liquid driven control mechanism is arranged at the center of one end of the moving space for the spiral spring valve rod type liquid driven control mechanism, a first vent hole for the spiral spring valve rod type liquid driven control mechanism and a second vent hole for the spiral spring valve rod type liquid driven control mechanism which are communicated with the external space and the spring compression space for the spiral spring valve rod type liquid driven control mechanism are arranged inside the hollow shell for the spiral spring valve rod type liquid driven control mechanism, the first vent hole for the spiral spring valve rod type liquid driven control mechanism and the second vent hole for the spiral spring valve rod type liquid driven control mechanism are symmetrically arranged relative to the central line of the spring compression space for the spiral spring valve rod type liquid driven control mechanism, a movable valve rod for the spiral spring valve rod type liquid driven control mechanism is arranged in the spring compression space for the spiral spring valve rod type liquid driven control mechanism, a third vent hole for the spiral spring valve rod type liquid driven control mechanism is arranged in the middle of the rod body of the valve rod for the spiral spring valve rod type liquid driven control mechanism and communicated with the two sides of the rod body, a spiral spring for the spiral spring valve rod type liquid driven control mechanism in a compressed state is arranged at one end of the valve rod for the spiral spring valve rod type liquid driven control mechanism in the spring compression space for the spiral spring valve rod type liquid driven control mechanism, a movable plate for the spiral spring valve rod type liquid driven control mechanism is arranged at one end of the valve rod for the spiral spring valve rod type liquid driven control mechanism in the moving space for the spiral spring valve rod type liquid driven control mechanism, and a liquid through hole for the spiral spring valve rod type liquid driven control mechanism, which is communicated with the external space and one end surface of the moving space for the spiral spring valve rod type liquid driven control mechanism, is formed in the center of one end surface of the hollow shell for the spiral spring valve rod type liquid driven control mechanism.

Further, the hollow housing for the helical spring valve rod type liquid driven control mechanism is installed inside the main component installation space, the first vent hole for the helical spring valve rod type liquid driven control mechanism and the second vent hole for the helical spring valve rod type liquid driven control mechanism are respectively communicated with two opposite ends of the main air inlet hole, and the third vent hole for the helical spring valve rod type liquid driven control mechanism is respectively communicated with one end of the liquid flow hole.

Further, the distance between the center of the third vent hole for the helical spring valve rod type liquid driven control mechanism and the moving plate for the helical spring valve rod type liquid driven control mechanism is the same as the distance between the center of the first vent hole for the helical spring valve rod type liquid driven control mechanism and the first vent hole for the helical spring valve rod type liquid driven control mechanism.

Compared with the prior art, the invention has the beneficial effects that: the invention can perform pressurization effect on the back of the piston used for compression, perform air type pressurization on the piston, directly act on the piston, release pressurized gas when the piston is compressed, only perform pressurization effect when the piston is compressed, and generate no reaction force when the piston is reset, so that the pressurization effect is obvious, the negative effect is low, and the compression capability of the piston is improved.

Drawings

FIG. 1 is a schematic view of a gas pressurizing mechanism for a piston movement mechanism according to the present invention;

FIG. 2 is a schematic structural diagram of a coil spring type interference driving mechanism in a gas pressurizing mechanism for a piston moving mechanism according to the present invention;

FIG. 3 is a schematic structural diagram of a spiral spring valve lever type liquid driven control mechanism in a gas pressurization mechanism for a piston movement mechanism according to the present invention;

in the figure: 1, a main hollow housing, 2, a compression space, 4, a piston, 5, a telescopic rod, 6, a main seal ring, 7, a main vent hole, 8, an auxiliary seal ring, 9, a coil spring type abutting driving mechanism, 91, a hollow housing for a coil spring type abutting driving mechanism, 92, a hollow structure for a coil spring type abutting driving mechanism, 93, a liquid discharge hole for a coil spring type abutting driving mechanism, 94, a moving plate for a coil spring type abutting driving mechanism, 95, a push rod for a coil spring type abutting driving mechanism, a coil spring for a coil spring type abutting driving mechanism, 10, an auxiliary member mounting hole, 12, a liquid flow hole, 13, a main member mounting hole, 14, a valve element mounting hole, 15, a coil spring valve rod type liquid driven control mechanism, 151, a hollow housing for a coil spring valve rod type liquid driven control mechanism, 152, a moving space for a coil spring valve rod type liquid driven control mechanism, 153, spring compression space for coil spring valve stem type liquid driven control mechanism, 154, first vent hole for coil spring valve stem type liquid driven control mechanism, 155, second vent hole for coil spring valve stem type liquid driven control mechanism, 156, valve stem for coil spring valve stem type liquid driven control mechanism, 157, third vent hole for coil spring valve stem type liquid driven control mechanism, 158, moving plate for coil spring valve stem type liquid driven control mechanism, 159, coil spring for coil spring valve stem type liquid driven control mechanism, 1510, liquid vent hole for coil spring valve stem type liquid driven control mechanism, 16, main intake hole, 17, main intake valve, 18, annular channel, 19, main exhaust hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an embodiment of the present invention: including main cavity shell 1, main cavity shell 1 terminal surface inside is equipped with compression space 2, a mobilizable piston 4 of internally mounted of compression space 2, a terminal surface central point installation telescopic link 5 of piston 4, the body of rod of telescopic link 5 runs through a terminal surface center of main cavity shell 1, and both install main sealing washer 6 at the position of running through, main cavity shell 1 has installed a plurality of ring array's accessory mounting hole 10 at a terminal surface that is located compression space 2, every a coil spring formula conflict actuating mechanism 9 is all installed to the inside of accessory mounting hole 10, every sealing washer 8 is all installed in the outside of coil spring formula conflict actuating mechanism 9, every one side of coil spring formula conflict actuating mechanism 9 all is equipped with a liquid flow hole 12, and is a plurality of the tip of liquid flow hole 12 is gathered in one end, A main part mounting hole 13 is formed in the end part of the main part mounting hole 13, a spiral spring valve rod type liquid driven control mechanism 15 is mounted in the main part mounting hole 13, a plurality of main exhaust holes 19 in annular array are formed in the edge of one end, located in the compression space 2, of the main hollow shell 1, the end part of each main exhaust hole 19 is communicated with an annular channel 18 formed in the main hollow shell 1, a main air inlet hole 16 communicated with the external space and the annular channel 18 is formed in the main hollow shell 1, the main air inlet hole 16 penetrates through the main part mounting hole 13, a valve core mounting hole 14 is formed in the end part of the main air inlet hole 16, a main air inlet valve 17 is mounted in the valve core mounting hole 14, a main vent hole 7 communicated with the external space and the side surface of the compression space 2 is formed in one side of the main hollow shell 1, and the distance between the main vent hole 7 and the compression space 2 and one end surface of the main sealing ring 6 is the same as the distance between the middle part And the sealing area between the spiral spring type interference driving mechanism 9, the liquid flow hole 12 and the spiral spring valve rod type liquid driven control mechanism 15 is filled with hydraulic oil.

Referring to fig. 2, the coil spring type abutting driving mechanism 9 includes a hollow case 91 for the coil spring type abutting driving mechanism, a hollow structure 92 for the coil spring type abutting driving mechanism, a liquid discharge hole 93 for the coil spring type abutting driving mechanism, a moving plate 94 for the coil spring type abutting driving mechanism, a push rod 95 for the coil spring type abutting driving mechanism, and a coil spring 96 for the coil spring type abutting driving mechanism; the hollow shell 91 for the coil spring type conflict driving mechanism is internally provided with a hollow structure 92 for the coil spring type conflict driving mechanism at the center, a liquid discharge hole 93 for the coil spring type collision driving mechanism is arranged at the center of one end face of the hollow shell 91 for the coil spring type collision driving mechanism, a movable coil spring type moving plate 94 for the interference drive mechanism is installed inside the hollow structure 92 for the coil spring type interference drive mechanism, one end surface of the coil spring type abutting driving mechanism moving plate 94 is provided with a coil spring 96 for abutting driving mechanism in a compressed state, the other end surface of the coil spring type abutting driving mechanism moving plate 94 is provided with a coil spring type abutting driving mechanism push rod 95, and the rod body of the push rod 95 for the coil spring type collision driving mechanism penetrates the center of the other end face of the hollow shell 91 for the coil spring type collision driving mechanism; the hollow shell 91 for the coil spring type collision driving mechanism is arranged inside the main hollow shell 1, and the whole structure of the hollow shell 91 for the coil spring type collision driving mechanism is completely embedded in the structure inside the main hollow shell 1; the coil spring type abutting driving mechanism drain hole 93 communicates with one end of the liquid flow hole 12.

Referring to fig. 3, the helical spring valve-stem type liquid driven control mechanism 15 includes a hollow housing 151 for the helical spring valve-stem type liquid driven control mechanism, a movement space 152 for the helical spring valve-stem type liquid driven control mechanism, a spring compression space 153 for the helical spring valve-stem type liquid driven control mechanism, a first vent 154 for the helical spring valve-stem type liquid driven control mechanism, a second vent 155 for the helical spring valve-stem type liquid driven control mechanism, a valve stem 156 for the helical spring valve-stem type liquid driven control mechanism, a third vent 157 for the helical spring valve-stem type liquid driven control mechanism, a moving plate 158 for the helical spring valve-stem type liquid driven control mechanism, a helical spring 159 for the helical spring valve-stem type liquid driven control mechanism, and a vent 1510 for the helical spring valve-stem type liquid driven control mechanism; a moving space 152 for the coil spring valve rod type liquid driven control mechanism is provided at one end inside the hollow housing 151 for the coil spring valve rod type liquid driven control mechanism, a spring compression space 153 for the coil spring valve rod type liquid driven control mechanism is provided at one end center of the moving space 152 for the coil spring valve rod type liquid driven control mechanism, a first vent hole 154 for the coil spring valve rod type liquid driven control mechanism and a second vent hole 155 for the coil spring valve rod type liquid driven control mechanism for communicating the external space and the spring compression space 153 for the coil spring valve rod type liquid driven control mechanism are provided inside the hollow housing 151 for the coil spring valve rod type liquid driven control mechanism, and the first vent hole 154 for the coil spring valve rod type liquid driven control mechanism and the second vent hole 155 for the coil spring valve rod type liquid driven control mechanism are provided with respect to the center of the spring compression space 153 for the coil spring valve rod type liquid driven control mechanism The spiral spring valve rod type liquid driven control mechanism is arranged in a line symmetry manner, a movable spiral spring valve rod type liquid driven control mechanism valve rod 156 is arranged in the spiral spring valve rod type liquid driven control mechanism spring compression space 153, a third spiral spring valve rod type liquid driven control mechanism air vent 157 communicated with the two sides of the middle part of the rod body of the spiral spring valve rod type liquid driven control mechanism valve rod 156 is arranged in one end of the spiral spring valve rod type liquid driven control mechanism spring compression space 153, a spiral spring 159 in a compressed state is arranged at one end of the spiral spring valve rod type liquid driven control mechanism valve rod 156 in the spiral spring valve rod type liquid driven control mechanism spring compression space, a spiral spring valve rod type liquid driven control mechanism 158 is arranged at one end of the movable plate in the spiral spring valve rod type liquid driven control mechanism moving space 152, a fluid passage hole 1510 for the helical spring valve rod type fluid driven control mechanism communicating the external space with one end surface of the displacement space 152 for the helical spring valve rod type fluid driven control mechanism is formed in the center of one end surface of the hollow housing 151 for the helical spring valve rod type fluid driven control mechanism; the hollow housing 151 for the helical spring valve lever type liquid driven control mechanism is installed inside the main part installation space 13, the first vent hole 154 for the helical spring valve lever type liquid driven control mechanism and the second vent hole 155 for the helical spring valve lever type liquid driven control mechanism are respectively communicated with two opposite ends of the main air intake hole 16, and the third vent hole 157 for the helical spring valve lever type liquid driven control mechanism is respectively communicated with one end of the liquid flow hole 12; the distance between the center of the third vent hole 157 for the helical spring valve lever type liquid driven control mechanism and the moving plate 158 for the helical spring valve lever type liquid driven control mechanism is the same as the distance between the center of the first vent hole 154 for the helical spring valve lever type liquid driven control mechanism and the first vent hole 154 for the helical spring valve lever type liquid driven control mechanism.

First, the primary intake valve 17 is connected to the exhaust line of a device capable of discharging high-pressure air.

The specific use mode is as follows: in the work of the invention, when the piston 4 is compressed, the connecting device needs to reset the piston 4 to the right end (relative to the attached drawing 1), when the end surface of the piston 4 extrudes the spiral spring type abutting driving mechanism 9, liquid in the spiral spring type abutting driving mechanism 9 can directly act into the spiral spring valve rod type liquid driven control mechanism 15 under the flowing action, so that a through hole in the spiral spring valve rod type liquid driven control mechanism 15 is communicated, high-pressure air is injected into the compression space 2 from outside air, the high-pressure air 2 can generate a trend of pushing the piston 4 leftwards, the pressurization work is realized, and when the piston 4 moves to the left side of the main vent hole 7, the internally pressurized high-pressure air can be released, so that the reset of the piston 4 cannot be influenced.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (7)

1. The utility model provides a gas booster mechanism for piston motion, includes main cavity shell (1), its characterized in that: a compression space (2) is arranged in one end face of the main hollow shell (1), a movable piston (4) is arranged in the compression space (2), a telescopic rod (5) is arranged at the center of one end face of the piston (4), a rod body of the telescopic rod (5) penetrates through the center of one end face of the main hollow shell (1), a main sealing ring (6) is arranged at the penetrating position of the piston and the end face, a plurality of annular array auxiliary part mounting holes (10) are arranged on one end face of the compression space (2) of the main hollow shell (1), a coil spring type conflict driving mechanism (9) is arranged in each auxiliary part mounting hole (10), a pair of sealing rings (8) is arranged on the outer side of each coil spring type conflict driving mechanism (9), a liquid flowing hole (12) is arranged on one side of each coil spring type conflict driving mechanism (9), the end parts of the liquid flowing holes (12) are gathered at one end, a main part mounting hole (13) is formed in the end part, a spiral spring valve rod type liquid driven control mechanism (15) is mounted inside the main part mounting hole (13), a plurality of main exhaust holes (19) in an annular array are formed in the edge of one end, located in the compression space (2), of the main hollow shell (1), the end parts of the main exhaust holes (19) are communicated with an annular channel (18) arranged inside the main hollow shell (1), a main air inlet hole (16) communicated with the external space and the annular channel (18) is formed in the main hollow shell (1), the main air inlet hole (16) penetrates through the main part mounting hole (13), a valve core mounting hole (14) is formed in the end part of the main air inlet hole (16), and a main air inlet valve (17) is mounted inside the valve core mounting hole (14), one side of main cavity shell (1) is equipped with main air vent (7) of intercommunication external space and compression space (2) side, just main air vent (17) are the same with the distance between compression space (2) the distance between main sealing washer (6) terminal surface and piston (4) side middle part and piston (4) tip, the sealed region between coil spring formula conflict actuating mechanism (9), liquid flow hole (12) and coil spring valve rod formula liquid driven control mechanism (15) is filled with hydraulic oil.

2. A gas booster mechanism for a piston movement mechanism according to claim 1, characterized in that: the coil spring type conflict driving mechanism (9) comprises a hollow shell (91) for the coil spring type conflict driving mechanism, a hollow structure (92) for the coil spring type conflict driving mechanism, a liquid discharge hole (93) for the coil spring type conflict driving mechanism, a moving plate (94) for the coil spring type conflict driving mechanism, a push rod (95) for the coil spring type conflict driving mechanism and a coil spring (96) for the coil spring type conflict driving mechanism; coil spring conflict hollow shell (91) for actuating mechanism inside center is equipped with coil spring conflict hollow structure (92) for actuating mechanism, a terminal surface center of coil spring conflict hollow shell (91) for actuating mechanism is equipped with coil spring conflict drain hole (93) for actuating mechanism, coil spring conflict actuating mechanism is with a mobilizable coil spring conflict actuating mechanism for motion plate (94) of internally mounted of hollow structure (92), a coil spring conflict coil spring (96) for actuating mechanism of a terminal surface mounting compression state of coil spring conflict motion plate (94) for actuating mechanism, another terminal surface mounting coil spring conflict push rod (95) for actuating mechanism of coil spring conflict motion plate (94), just the body of rod of coil spring conflict push rod (95) for actuating mechanism runs through coil spring conflict hollow shell (91) for actuating mechanism Is centered on the other end face.

3. A gas booster mechanism for a piston movement mechanism according to claim 2, characterized in that: the coil spring type hollow shell (91) for the conflict driving mechanism is arranged in the main hollow shell (1), and the whole structure of the coil spring type hollow shell (91) for the conflict driving mechanism is completely embedded in the structure in the main hollow shell (1).

4. A gas booster mechanism for a piston movement mechanism according to claim 2, characterized in that: the coil spring type liquid discharge hole (93) for the interference driving mechanism is communicated with one end of the liquid flowing hole (12).

5. A gas booster mechanism for a piston movement mechanism according to claim 1, characterized in that: the spiral spring valve rod type liquid driven control mechanism (15) comprises a hollow shell (151) for the spiral spring valve rod type liquid driven control mechanism, a moving space (152) for the spiral spring valve rod type liquid driven control mechanism, a spring compression space (153) for the spiral spring valve rod type liquid driven control mechanism, a first vent hole (154) for the spiral spring valve rod type liquid driven control mechanism and a second vent hole (155) for the spiral spring valve rod type liquid driven control mechanism, a valve rod (156) for a helical spring valve rod type liquid driven control mechanism, a third vent hole (157) for the helical spring valve rod type liquid driven control mechanism, a moving plate (158) for the helical spring valve rod type liquid driven control mechanism, a helical spring (159) for the helical spring valve rod type liquid driven control mechanism and a liquid through hole (1510) for the helical spring valve rod type liquid driven control mechanism; the spiral spring valve rod type liquid driven control mechanism is characterized in that a moving space (152) for the spiral spring valve rod type liquid driven control mechanism is arranged at one end inside a hollow shell (151) for the spiral spring valve rod type liquid driven control mechanism, a spring compression space (153) for the spiral spring valve rod type liquid driven control mechanism is arranged at the center of one end of the moving space (152) for the spiral spring valve rod type liquid driven control mechanism, a first vent hole (154) for the spiral spring valve rod type liquid driven control mechanism and a second vent hole (155) for the spiral spring valve rod type liquid driven control mechanism, which are used for communicating an external space and the spring compression space (153) for the spiral spring valve rod type liquid driven control mechanism, are arranged inside the hollow shell (151) for the spiral spring valve rod type liquid driven control mechanism, and the first vent hole (154) for the spiral spring valve rod type liquid driven control mechanism and the second vent hole (155) for the spiral spring valve rod type liquid driven control mechanism The central line of a spring compression space (153) for the spiral spring valve rod type liquid driven control mechanism is symmetrically arranged, a movable valve rod (156) for the spiral spring valve rod type liquid driven control mechanism is arranged in the spring compression space (153) for the spiral spring valve rod type liquid driven control mechanism, a third vent hole (157) for the spiral spring valve rod type liquid driven control mechanism communicated with two sides of the valve rod (156) for the spiral spring valve rod type liquid driven control mechanism is arranged in the middle of the rod body of the valve rod (156) for the spiral spring valve rod type liquid driven control mechanism, a spiral spring (159) in a compression state is arranged at one end in the spring compression space (153) for the spiral spring valve rod type liquid driven control mechanism, and the valve rod (156) for the spiral spring valve rod type liquid driven control mechanism is arranged in the moving space (152) for the spiral spring valve rod type liquid driven control mechanism ) A moving plate (158) for the helical spring valve rod type liquid driven control mechanism is arranged at one end of the interior, and a liquid through hole (1510) for the helical spring valve rod type liquid driven control mechanism, which communicates the external space and one end surface of the moving space (152) for the helical spring valve rod type liquid driven control mechanism, is arranged at the center of one end surface of the hollow shell (151) for the helical spring valve rod type liquid driven control mechanism.

6. A gas booster mechanism for a piston movement mechanism according to claim 5, characterized in that: the hollow shell (151) for the spiral spring valve rod type liquid driven control mechanism is arranged in the main component mounting space (13), the first vent hole (154) for the spiral spring valve rod type liquid driven control mechanism and the second vent hole (155) for the spiral spring valve rod type liquid driven control mechanism are respectively communicated with two opposite ends of the main air inlet hole (16), and the third vent hole (157) for the spiral spring valve rod type liquid driven control mechanism is respectively communicated with one end of the liquid flowing hole (12).

7. A gas booster mechanism for a piston movement mechanism according to claim 5, characterized in that: the distance between the center of the third vent hole (157) for the helical spring valve rod type liquid driven control mechanism and the moving plate (158) for the helical spring valve rod type liquid driven control mechanism is the same as the distance between the center of the first vent hole (154) for the helical spring valve rod type liquid driven control mechanism and the first vent hole (154) for the helical spring valve rod type liquid driven control mechanism.

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