CN211737603U - Gas-liquid combined rotary motion structure - Google Patents

Abstract

The disclosure belongs to the technical field of nuclear power maintenance, and particularly relates to a gas-liquid combined rotary motion structure. According to the embodiment of the disclosure, the two groups of pressure cylinders are connected and disconnected with the air source, so that the rotary motion of the pulley within a certain range is realized, the device to be rotated, which is arranged on the pulley, is driven to move and rotate, the structure is compact, and the device can adapt to the limited working space.

Description

Gas-liquid combined rotary motion structure

Technical Field

The utility model belongs to the technical field of the nuclear power maintenance, concretely relates to gas-liquid combination rotary motion structure.

Background

In the mechanism design of the nuclear power station maintenance equipment, due to the special working environment, the working space which can be reached by the maintenance equipment limits the operation range of the equipment, and the operation range of the maintenance equipment is closely related to factors such as the structure, the running environment, the attitude constraint condition and the like of the maintenance equipment. These complications impose high demands on the configuration, weight and material of the service equipment, which are particularly pronounced in the rotary motion structure of the service equipment. Therefore, a rotational movement structure having a compact structure is required.

SUMMERY OF THE UTILITY MODEL

In order to overcome the problems in the related art, a gas-liquid combined rotary motion structure is provided.

According to an aspect of the embodiments of the present disclosure, there is provided a gas-liquid combined rotational motion structure including: the device comprises a control device, an air source, a first pressure cylinder, a second pressure cylinder, a first electromagnetic valve, a second electromagnetic valve, a first hydraulic pipe, a second hydraulic pipe, a pulley, a first rotating cylinder, a second rotating cylinder, a pulley, a bearing, a pull rope and a rotating platform;

the first pressurizing cylinder, the second pressurizing cylinder, the first rotating cylinder and the second rotating cylinder are respectively connected to the rotating platform;

the control device is respectively connected with the first electromagnetic valve and the second electromagnetic valve;

the first booster cylinder is connected with the air source through the first electromagnetic valve, and the second booster cylinder is connected with the origin through the second electromagnetic valve;

the first pressurizing cylinder is connected with the first rotating cylinder through the first hydraulic pipe, and the second pressurizing cylinder is connected with the second rotating cylinder through the second hydraulic pipe;

the piston of the first rotating cylinder and the piston of the second rotating cylinder are respectively connected with two ends of the pull rope, and the pull rope is sleeved on the periphery of the round wheel of the pulley;

a first through hole is formed in the rotating platform along the axial direction, the outer ring of the bearing is fixedly connected in the first through hole, the inner ring of the bearing is fixedly connected with the round wheel of the pulley, a second through hole is formed in the center of the pulley along the axial direction, and a device to be rotated is arranged in the second through hole;

the control device controls the first electromagnetic valve to be opened and controls the second electromagnetic valve to be closed, the first pressurizing cylinder is communicated with the air source, the second pressurizing cylinder is not communicated with the origin, the first pressurizing cylinder drives the piston of the first rotating cylinder to contract through the first hydraulic pipe, and the pulley is dragged to rotate around the axis of the pulley in a first direction through the pull rope, so that the device to be rotated is driven to rotate in the first direction;

the control device controls the first electromagnetic valve to be closed, controls the second electromagnetic valve to be opened, and under the condition that the first pressure cylinder is not communicated with the air source, the second pressure cylinder is communicated with the source, the second pressure cylinder drives the piston of the second rotating cylinder to contract through the second hydraulic pipe, and pulls the pulley to rotate around the axle center of the pulley in a second direction opposite to the first direction through the pull rope, so that the device to be rotated is driven to rotate in the second direction.

In one possible implementation, the first pressure cylinder includes: a pneumatic chamber, a hydraulic chamber and a piston structure;

the piston structure includes: a first piston, a piston connecting rod and a second piston;

the air pressure cavity is arranged at one end in the first pressure cylinder, and one end of the air pressure cavity is connected with the air source through an air transmission port;

the hydraulic cavity is arranged in the first pressurizing cylinder, one end of the hydraulic cavity is communicated with the other end of the air pressure cavity, and the other end of the hydraulic cavity is connected with the first hydraulic pipe through a transfusion port;

the cross-sectional area of the hydraulic cavity is smaller than that of the pneumatic cavity;

a piston rod is connected between the first piston and the second piston, the first piston is arranged in the air pressure cavity, the second piston is arranged in the hydraulic cavity, and liquid is filled in a space from the second piston to the other end of the hydraulic cavity and the first hydraulic pipe in the hydraulic cavity;

under the condition that the first pressurizing cylinder is communicated with the air source, the air source inflates air into a space from one end of the air pressure cavity to the first piston to push the first piston, so that the piston structure moves towards the other end of the hydraulic cavity, and the second piston pushes liquid in the hydraulic cavity to the first hydraulic pipe.

In a possible implementation manner, the first piston outer ring is provided with a lip-shaped sealing ring.

In a possible implementation, the second piston outer ring is provided with a sealing ring.

In one possible implementation, the second outer piston ring is provided with a piston bush.

In one possible implementation, the first pressure cylinder further includes a guide rod, and the guide rod is a linear type;

the other end of the first pressure cylinder is provided with a third through hole penetrating through the air pressure cavity, one end of the guide rod is perpendicular to the surface of the first piston, the guide rod penetrates through the third through hole, and the guide rod can move relative to the third through hole.

In one possible implementation, the first pressure cylinder further includes: a displacement sensor;

the displacement sensor is connected with the piston structure and used for detecting the displacement of the piston structure.

In one possible implementation, the second pressure cylinder is identical in structure to the first pressure cylinder.

The beneficial effects of the utility model reside in that: according to the embodiment of the disclosure, the two groups of pressure cylinders are connected and disconnected with the air source, so that the rotary motion of the pulley within a certain range is realized, the device to be rotated, which is arranged on the pulley, is driven to move and rotate, the structure is compact, and the device can adapt to the limited working space.

Drawings

Fig. 1 is a perspective view illustrating a gas-liquid combined rotational motion structure according to an exemplary embodiment.

Fig. 2 is an axial sectional view of a first booster cylinder of a gas-liquid combined rotary motion structure shown according to an exemplary embodiment.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a perspective view illustrating a gas-liquid combined rotational motion structure according to an exemplary embodiment. As shown in fig. 1, the gas-liquid combined rotational movement structure may include: a control device (not shown in the figure), an air source (not shown in the figure), a first pressurizing cylinder 16, a second pressurizing cylinder 17, a first electromagnetic valve, a second electromagnetic valve, a first hydraulic pipe 10, a second hydraulic pipe 11, a pulley 15, a first rotating cylinder 12, a second rotating cylinder 13, a pulley 15, a bearing, a pull rope 14 and a rotating platform 18;

in the embodiment of the present disclosure, the control device may be, for example, a single chip microcomputer or a programmable logic controller, as long as the control device can control on/off of the electromagnetic valve, and the type of the control device is not limited in the embodiment of the present disclosure. The booster cylinder may be represented as a cylindrical metal work that guides a piston to perform a linear reciprocating motion in the cylinder by gas-liquid hybrid driving.

The first pressure cylinder 16, the second pressure cylinder 17, the first rotating cylinder 12 and the second rotating cylinder 13 are respectively connected to the rotating platform 18, for example, the first pressure cylinder 16 and the second pressure cylinder 17 may be connected to the lower surface of the rotating platform 18 through a connecting frame, the first pressure cylinder 16 may be connected to a gas source through a first solenoid valve, and the second pressure cylinder 17 may be connected to a source through a second solenoid valve; a control device (not shown in the figure) may be connected to the first solenoid valve and the second solenoid valve, respectively;

the first rotating cylinder 12 and the second rotating cylinder 13 may be connected to the upper end of the rotating platform 18, two connection holes may be opened on the rotating platform 18, for example, along the axial direction, the infusion port of the first pressurizing cylinder 16 may be connected to one end of the first hydraulic pipe 10, and the other end of the first hydraulic pipe 10 may pass through one connection hole and be connected to the first rotating cylinder 12; the fluid delivery port of the second pressurizing cylinder 17 may be connected to both ends of the second hydraulic pipe 11, and the other end of the second hydraulic pipe 11 may pass through both the connection holes and be connected to the second rotating cylinder 13.

The piston of the first rotating cylinder 12 and the piston of the second rotating cylinder 13 are respectively connected with two ends of a pull rope 14, and the pull rope 14 can be sleeved on the periphery of a round wheel of the pulley 15; for example, the circumferential surface of the round wheel of the pulley 15 may have a groove, the pull rope 14 may be wound or sleeved in the groove, the rotating platform 18 may have a first through hole along the axial direction, the outer ring of the bearing may be fixedly connected in the first through hole, the inner ring of the bearing may be fixedly connected with the round wheel of the pulley 15, the center of the pulley 15 may have a second through hole along the axial direction, and the second through hole is provided with a device to be rotated (for example, a rotating shaft of an overhaul device, etc.);

under the condition that the control device controls the first electromagnetic valve to be opened and controls the second electromagnetic valve to be closed, the first pressure cylinder 16 can be communicated with an air source, the second pressure cylinder 17 is not communicated with the source, the first pressure cylinder 16 can drive the piston of the first rotating cylinder 12 to contract through the first hydraulic pipe 10, and the pulley 15 is dragged to rotate around the axis of the pulley 15 in a first direction (for example, in a clockwise direction) through the pull rope 14, so that the device to be rotated is driven to rotate in the first direction;

under the condition that the control device controls the first electromagnetic valve to be closed and controls the second electromagnetic valve to be opened, the first pressurizing cylinder 16 is not communicated with the air source, the second pressurizing cylinder 17 is communicated with the source, the second pressurizing cylinder 17 drives the piston of the second rotating cylinder 13 to contract through the second hydraulic pipe 11, the pulley 15 is dragged to rotate around the axis of the pulley 15 in a second direction (for example, in a counterclockwise direction) opposite to the first direction through the pull rope 14, and the device to be rotated is driven to rotate in the second direction.

According to the embodiment of the disclosure, the two groups of pressure cylinders are connected and disconnected with the air source, so that the rotary motion of the pulley within a certain range is realized, the device to be rotated, which is arranged on the pulley, is driven to move and rotate, the structure is compact, and the device can adapt to the limited working space.

Generally, a nuclear power plant can provide a gas source and a power source, and the pneumatic transmission is a power driving mode which is suitable for maintenance equipment in the nuclear power plant in consideration of the complexity of electrical control. However, the system pressure provided by the nuclear power plant is limited due to safety considerations, and is generally in the range of 0-0.7Mpa, which results in a large transmission force for the rotational movement of the maintenance equipment, and the volume of the maintenance equipment needs to be increased. However, the detection space of each device in the nuclear island of the nuclear power plant is limited, and the overhaul device is required to have smaller volume so as to move flexibly in the limited space, and in this case, a method for increasing the volume of the overhaul device is not generally taken. Therefore, how to make the limited-volume maintenance equipment have larger driving force becomes a problem to be solved urgently.

Fig. 2 is an axial sectional view of a first booster cylinder of a gas-liquid combined rotary motion structure shown according to an exemplary embodiment. As shown in fig. 2, the first booster cylinder 16 may include: a pneumatic chamber 20, a hydraulic chamber 21 and a piston structure; the piston structure may include: a first piston 22, a piston rod 30, and a second piston 23; the pneumatic chamber 20 and the hydraulic chamber 21 may be cylindrical, and the shape of the pneumatic chamber 20 and the shape of the hydraulic chamber 21 are not limited in the embodiment of the present disclosure.

The pneumatic chamber 20 may be disposed at one end of the first pressure cylinder 16, and one end of the pneumatic chamber 20 may be connected to a gas source through a gas transmission port 27, wherein the gas transmission port 27 may penetrate from a housing at one end of the pneumatic first pressure cylinder to the pneumatic chamber 20; the hydraulic chamber 21 may also be disposed in the first pressurizing cylinder 16, one end of the hydraulic chamber 21 may be communicated with the other end of the pneumatic chamber 20, and the other end of the hydraulic chamber 21 may be connected to the first hydraulic pipe 10 through an infusion port 28, wherein the infusion port 28 may be communicated to the hydraulic chamber 21 from a housing at the other end of the pneumatic first pressurizing cylinder; the cross-sectional area of the hydraulic chamber 21 may be smaller than that of the pneumatic chamber 20.

A piston rod may be connected between the first piston 22 and the second piston 23, the first piston 22 may be disposed in the pneumatic chamber 20, the second piston 23 may be disposed in the hydraulic chamber 21, and a space from the second piston 23 to the other end of the hydraulic chamber 21 in the hydraulic chamber 21 and the first hydraulic pipe 10 may be filled with a liquid (the liquid may be, for example, water or liquid oil); sealing measures can be taken for the first piston 22 and the second piston 23, for example, a lip-shaped sealing ring 24 can be arranged on the outer ring of the first piston 22, and a sealing ring 25 can also be arranged on the outer ring of the second piston 23, so that a space from one end of the pneumatic chamber 20 to the first piston 22, a space from the first piston 22 to the second piston 23, and a space from the second piston 23 to the other end of the hydraulic chamber 21 can form mutually independent closed spaces, thereby forming gas-liquid isolation.

In the case where the first pressurizing cylinder 16 is connected to the air source, the air source inflates the space from one end of the pneumatic chamber 20 to the first piston 22, pushing the first piston 22, so that the piston structure moves toward the other end of the hydraulic chamber 21, and the second piston 23 pushes the liquid of the hydraulic chamber 21 to the first hydraulic pipe 10. Because the cross-sectional area of the hydraulic pressure cavity 21 is smaller than the cross-sectional area of the air pressure cavity 20, the first pressure cylinder 16 can effectively conduct the input air pressure into hydraulic pressure with higher pressure, and the air pressure cavity 20 and the hydraulic pressure cavity 21 in the first pressure cylinder 16 are linearly arranged, so that the structure is compact, and the maintenance equipment with limited volume can have larger driving force. In addition, hydraulic drive is more moderate than pneumatic drive, and the disclosed embodiment can effectively reduce the probability of device damage of the driven equipment due to over-violent action.

In one possible implementation, a piston bushing 26 is provided around the second piston 23. For example, the material of the second piston 23 may include a metal material such as stainless steel, and the material of the piston bushing 26 may include a material such as copper or nylon having a hardness lower than that of stainless steel, which effectively reduces the friction between the second piston 23 and the hydraulic chamber 21 during the movement.

In one possible implementation, the first pressure cylinder 16 may further include a guide rod 29; the guide bar 29 may be linear. The other end of the first booster cylinder 16 is provided with a third through hole penetrating to the pneumatic chamber 20, one end of a guide rod may be vertically connected to the surface of the first piston 22, a guide rod 29 may pass through the third through hole, and the guide rod 29 may be movable relative to the third through hole. In this way, during the reciprocating motion of the piston structure, the guide rod 29 can limit the motion track of the piston structure to a straight line, so as to effectively prevent the motion track of the piston structure from deviating, further to too high the supercharging efficiency of the first supercharging cylinder 16 and the second supercharging cylinder 17, and to effectively prevent the inner wall of the supercharging cylinder from being damaged.

Furthermore, when the first pressurizing cylinder 16 is out of order, the service man can push the guide rod 29 to see whether the guide rod 29 can be pushed or not, so as to test whether the failure of the first pressurizing cylinder 16 is caused by the jamming of the piston structure.

In one possible implementation, the first pressure cylinder 16 may further include: a displacement sensor 31; a displacement sensor 31 may be connected to the piston structure, which displacement sensor 31 may be used to detect the amount of displacement of the piston structure. An upper computer may be provided in connection with the displacement sensor to display the movement state of the piston of the first booster cylinder 16 in real time.

In one possible implementation, the first and second pressure cylinders 16, 17 may be identical in structure.

It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. It is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

Claims (8)

1. A gas-liquid combined rotational motion structure, characterized by comprising: the device comprises a control device, an air source, a first pressure cylinder, a second pressure cylinder, a first electromagnetic valve, a second electromagnetic valve, a first hydraulic pipe, a second hydraulic pipe, a pulley, a first rotating cylinder, a second rotating cylinder, a pulley, a bearing, a pull rope and a rotating platform;

the first pressurizing cylinder, the second pressurizing cylinder, the first rotating cylinder and the second rotating cylinder are respectively connected to the rotating platform;

the control device is respectively connected with the first electromagnetic valve and the second electromagnetic valve;

the first pressure cylinder is connected with the air source through the first electromagnetic valve, and the second pressure cylinder is connected with the air source through the second electromagnetic valve;

the first pressurizing cylinder is connected with the first rotating cylinder through the first hydraulic pipe, and the second pressurizing cylinder is connected with the second rotating cylinder through the second hydraulic pipe;

the piston of the first rotating cylinder and the piston of the second rotating cylinder are respectively connected with two ends of the pull rope, and the pull rope is sleeved on the periphery of the round wheel of the pulley;

a first through hole is formed in the rotating platform along the axial direction, the outer ring of the bearing is fixedly connected in the first through hole, the inner ring of the bearing is fixedly connected with the round wheel of the pulley, a second through hole is formed in the center of the pulley along the axial direction, and a device to be rotated is arranged in the second through hole;

the control device controls the first electromagnetic valve to be opened and controls the second electromagnetic valve to be closed, the first pressure cylinder is communicated with the air source, the second pressure cylinder is not communicated with the air source, the first pressure cylinder drives the piston of the first rotating cylinder to contract through the first hydraulic pipe, and the pulley is dragged to rotate around the axle center of the pulley in a first direction through the pull rope, so that the device to be rotated is driven to rotate in the first direction;

the control device controls the first electromagnetic valve to be closed, controls the second electromagnetic valve to be opened, and under the condition that the first electromagnetic valve is not communicated with the air source, the second pressure cylinder is communicated with the air source, drives the piston of the second rotary cylinder to contract through the second hydraulic pipe, and pulls the pulley to rotate around the axle center of the pulley in a second direction opposite to the first direction through the pull rope, so that the device to be rotated is driven to rotate in the second direction.

2. The gas-liquid combined rotary motion structure according to claim 1, wherein the first pressurizing cylinder includes: a pneumatic chamber, a hydraulic chamber and a piston structure;

the piston structure includes: a first piston, a piston connecting rod and a second piston;

the air pressure cavity is arranged at one end in the first pressure cylinder, and one end of the air pressure cavity is connected with the air source through an air transmission port;

the hydraulic cavity is arranged in the first pressurizing cylinder, one end of the hydraulic cavity is communicated with the other end of the air pressure cavity, and the other end of the hydraulic cavity is connected with the first hydraulic pipe through a transfusion port;

the cross-sectional area of the hydraulic cavity is smaller than that of the pneumatic cavity;

a piston rod is connected between the first piston and the second piston, the first piston is arranged in the air pressure cavity, the second piston is arranged in the hydraulic cavity, and liquid is filled in a space from the second piston to the other end of the hydraulic cavity and the first hydraulic pipe in the hydraulic cavity;

under the condition that the first pressurizing cylinder is communicated with the air source, the air source inflates air into a space from one end of the air pressure cavity to the first piston to push the first piston, so that the piston structure moves towards the other end of the hydraulic cavity, and the second piston pushes liquid in the hydraulic cavity to the first hydraulic pipe.

3. The gas-liquid combined rotational motion structure according to claim 2, wherein a lip seal is provided on the first piston outer ring.

4. The gas-liquid combined rotational motion structure according to claim 2, wherein a seal ring is provided on the second piston outer ring.

5. A gas-liquid combined rotary motion structure according to claim 2, wherein the second piston outer ring is provided with a piston bush.

6. The gas-liquid combined rotary motion structure according to claim 2, wherein the first booster cylinder further includes a guide rod, the guide rod being linear;

the other end of the first pressure cylinder is provided with a third through hole penetrating through the air pressure cavity, one end of the guide rod is perpendicular to the surface of the first piston, the guide rod penetrates through the third through hole, and the guide rod can move relative to the third through hole.

7. The gas-liquid combined rotary motion structure according to claim 2, wherein the first booster cylinder further comprises: a displacement sensor;

the displacement sensor is connected with the piston structure and used for detecting the displacement of the piston structure.

8. The gas-liquid combined rotary motion structure according to any one of claims 2 to 7, wherein the second pressurizing cylinder has the same structure as the first pressurizing cylinder.

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