阅读说明：本技术 一种带紧急停止保护装置的气动阀门执行器 (Pneumatic valve actuator with emergency stop protection device ) 是由 邵曙 吕志翼 于 2021-05-22 设计创作，主要内容包括：本发明公开了一种带紧急停止保护装置的气动阀门执行器。本发明具有自动开启或关闭阀门的效果,备用电源上连接有电源,当电源断开时,备用电源会自动开启,备用电源连接有空气压缩机,空气压缩机输出端连接有导气管,导气管另一端连接有滑动筒,滑动筒内设置有滑块,滑块靠近导气管一端设置有活塞,活塞与滑块连接,滑块上设置有设置有链条连接块,链条连接块与链条连接,执行箱体内包括：滑动筒、复位筒与扭转箱,复位筒内装有复位弹簧,复位弹簧一端与滑块连接,扭转箱内设置有第一从动齿轮、第二从动齿轮与螺旋轴齿轮,螺旋轴齿轮上设置有螺旋轴,螺旋轴与滑动挡柱连接,阀门管上设置有阀门套,滑动挡柱挡块设置在阀门套内。(The invention discloses a pneumatic valve actuator with an emergency stop protection device. The automatic valve opening and closing device has the effect of automatically opening or closing a valve, a power supply is connected to a standby power supply, the standby power supply can be automatically opened when the power supply is disconnected, the standby power supply is connected with an air compressor, the output end of the air compressor is connected with an air guide pipe, the other end of the air guide pipe is connected with a sliding cylinder, a sliding block is arranged in the sliding cylinder, a piston is arranged at one end, close to the air guide pipe, of the sliding block, the piston is connected with the sliding block, a chain connecting block is arranged on the sliding block, the chain connecting block is connected with a chain, and the execution box body comprises: the valve tube is provided with a valve sleeve, and a sliding block of the sliding block is arranged in the valve tube.)

1. A pneumatic valve actuator with an emergency stop protection device is characterized in that: the actuator includes: stand-by power supply (1), air compressor (2), air duct (3), execution box (13), screw axis (10), slip bumping post (11), valve pipe (12), stand-by power supply (1) one end is connected with the power, stand-by power supply (1) output passes through the wire and is connected with air compressor (2), air compressor (2) output is provided with air duct (3), air compressor (2) one end is kept away from in air duct (3) and is connected with execution box (13), execution box (13) lower extreme is provided with screw axis (10), be provided with the screw thread on screw axis (10), screw axis (10) lower extreme is provided with activity bumping post (11), activity bumping post (11) imbeds in valve pipe (12).

2. A pneumatically actuated valve actuator with emergency stop protection as set forth in claim 1 wherein: the execution box body (13) comprises: the device comprises a sliding cylinder (13-1), a reset cylinder (13-2), a torsion box (13-3), a piston (4), a sliding block (5), a chain connecting block (5-1), a reset spring (6), a chain (7), a first driven gear (8), a second driven gear (9) and a screw shaft gear (10-1), wherein an execution box body (13) consists of the sliding cylinder (13-1), the reset cylinder (13-2) and the torsion box (13-3), the sliding cylinder (13-1) and one end, far away from an air compressor (2), of an air duct (3) are fixedly connected, the sliding cylinder (13-1) is internally provided with the piston (4), one side, far away from the air duct (3), of the piston (4) is provided with the sliding block (5), the piston (4) is fixedly connected with the sliding block (5), one side, far away from the piston (4), of the sliding block (5) is provided with the reset cylinder, a return spring (6) is arranged in the return cylinder (13-2), the return spring (6) is fixedly connected with the slide block (5), one end of the sliding block (5) far away from the piston (4) is arranged in the torsion box (13-3), the sliding block (5) is provided with a chain connecting block (5-1), the chain connecting block (5-1) is fixedly connected with a chain (7), the chain (7) is an annular chain, a first driven gear (8), a second driven gear (9) and a screw shaft gear (10-1) are arranged in the twisting box (13-3) and are arranged in the chain (7), the first driven gear (8) and the second driven gear (9) are meshed with the screw shaft gear (10-1), and the screw shaft gear (10-1) is fixedly connected with the screw shaft (10).

3. A pneumatically actuated valve actuator with emergency stop protection as set forth in claim 2 wherein: the reset spring (6) is a memory spring.

4. A pneumatically actuated valve actuator with emergency stop protection as set forth in claim 2 wherein: the circle centers of the first driven gear (8), the second driven gear (9) and the screw shaft gear (10-1) are on the same straight line, the radiuses of the first driven gear (8), the second driven gear (9) and the screw shaft gear (10-1) are the same, and the tooth numbers of the first driven gear (8), the second driven gear (9) and the screw shaft gear (10-1) are the same.

5. A pneumatically actuated valve actuator with emergency stop protection as set forth in claim 2 wherein: two right-angle plates are arranged on the sliding block (5), and the right-angle plates are symmetrical about the longitudinal section plane of the sliding block (5).

6. A pneumatically actuated valve actuator with emergency stop protection as set forth in claim 1 wherein: the movable stop pillar is characterized in that a movable stop pillar convex groove (11-1) is formed in the movable stop pillar (11), the movable stop pillar convex groove (11-1) is symmetrical about the longitudinal section of the movable stop pillar (11), the diameter of the movable stop pillar (11) is equal to the inner diameter of the valve pipe (12), internal threads are formed in the movable stop pillar (11), the movable stop pillar (11) is in threaded connection with the screw shaft (10), balls are arranged among the threads, and the threads of the movable screw shaft (10) are connected with the internal threads on the movable stop pillar (11) through the balls.

7. A pneumatically actuated valve actuator with emergency stop protection as set forth in claim 1 wherein: the valve tube (12) comprises: the valve sleeve comprises a valve pipe cavity (12-3), a valve sleeve (12-1) and a valve sleeve groove (12-2), wherein the valve pipe cavity (12-3) is fixedly connected with the valve sleeve (12-1), the valve sleeve (12-1) is perpendicular to the valve pipe cavity (12-3), the valve sleeve groove (12-2) is arranged on the valve sleeve (12-1), the valve sleeve groove (12-2) is symmetrical about the longitudinal section of the valve sleeve (12-1), the movable catch column convex groove (11-1) corresponds to the valve sleeve groove (12-2), and the movable catch column convex groove (11-1) is in sliding connection with the valve sleeve groove (12-2).

8. A pneumatically actuated valve actuator with emergency stop protection as set forth in claim 1 wherein: the actuating box body (13) is connected with the valve pipe (12) through a support, and the distance between the actuating box body (13) and the valve pipe (12) does not exceed the maximum extension of the movable retaining column (11).

Technical Field

The invention relates to the technical field of valve actuators, in particular to a pneumatic valve actuator with an emergency stop protection device.

Background

The actuators are divided into three types, namely pneumatic, electric and hydraulic, according to energy forms, and each type has various characteristics and can be suitable for different working occasions, one type of the pneumatic actuators is executed during the pneumatic actuators, the pneumatic actuators can also be divided into two types, namely single-action pneumatic actuators and double-action pneumatic actuators, the opening and closing actions of the actuators are all driven and executed by an air source, and the pneumatic valve actuators use compressed air as power and are driving devices for opening and closing pneumatic series angular travel valves, such as pneumatic ball valves, pneumatic butterfly valves, pneumatic gate valves, pneumatic stop valves, pneumatic diaphragm valves, pneumatic regulating valves and the like. The device is an ideal device for realizing the remote centralized control or the independent control of the industrial automatic pipeline. According to the requirements of users, an electromagnetic valve, a positioning valve, a feedback device, a filter, a pressure reducing valve, various limit switches and a manual operation device can be arranged on the pneumatic actuator.

However, as people slowly find, the single-acting pneumatic actuator and the double-acting pneumatic actuator have shortcomings, and in the double-acting pneumatic actuator, according to the requirements of users, the pneumatic actuator can be arranged in a transmission principle opposite to a standard type, namely, a rotating shaft rotates clockwise to open a valve and rotates anticlockwise to close the valve, but the shortcomings are still obvious, the control precision is low, the valve is easy to close loosely, and the valve cannot return to a preset position after an air supply is cut off, while the single-acting pneumatic actuator can return to the preset position by a spring after the air supply is cut off, but the torque force is insufficient, so that the air compressor is often damaged. According to the patent specification of the Chinese utility model: CN 202020401780.1A pneumatic valve sensor, which comprises a valve, a bracket and a body, wherein an air compressor is arranged in the middle of the top in the main body, exhaust ports are arranged on the bottom, the left side and the right side of the air compressor, a cylinder is transversely arranged in the middle of the main body, air inlets are arranged on the top, the left side and the right side of the cylinder, the exhaust ports are connected with the air inlets through air pipes, a controller and a capacitor are respectively arranged on the left side and the right side below the body, a movable groove is longitudinally arranged in the bracket, an output shaft is longitudinally inserted in the movable groove, a gear, a piston rod and a piston are sequentially arranged in the cylinder from inside to outside, a shaft groove is longitudinally arranged on the bottom of the cylinder, the top of the output shaft penetrates through the shaft groove to be connected with the bottom of the gear, the capacitor is electrically connected with the controller and the air compressor, the capacitor can be controlled by a circuit in the controller under the power-off state to ensure the normal operation of the air compressor, thereby ensuring the normal opening and closing of the valve, such a double-acting controller has a disadvantage in that the capacitor operating state may not satisfy the operating state of the cylinder and the reset operation may not be performed.

Disclosure of Invention

The present invention is directed to a pneumatic valve actuator with an emergency stop protection device to solve the problems set forth in the background art.

In order to solve the technical problems, the invention provides the following technical scheme: a pneumatic valve actuator with an emergency stop protection device is characterized in that: the actuator includes: the emergency power supply is connected with a power supply at one end, the emergency power supply can detect whether current passes through the power supply, the emergency power supply does not discharge when the current exists, the power supply does not have the current and discharges, the emergency power supply is connected with the air compressor through a lead and provides electric energy for the air compressor, the air guide pipe is arranged at the output end of the air compressor, one end of the air guide pipe, far away from the air compressor, is connected with the execution box, the air compressor continuously outputs air pressure into the execution box through the air guide pipe, the screw shaft is arranged at the lower end of the execution box and provides a supporting effect of the screw shaft, threads are arranged on the screw shaft, the movable retaining column is arranged at the lower end of the screw shaft and can move up and down along with the rotation of the screw shaft, and the movable retaining column is embedded into the valve pipe, the valve pipe limits the moving direction and distance for the movable stop pillar.

The execution box body comprises: the execution box body comprises a sliding cylinder, a reset cylinder, a twisting box, a piston, a slide block, a chain connecting block, a reset spring, a chain, a first driven gear, a second driven gear and a spiral shaft gear, the division of labor of each execution box body is different, the sliding cylinder and one end, far away from the air compressor, of an air guide pipe are fixedly connected, the air compressor pumps air into the sliding cylinder, the piston is arranged in the sliding cylinder and is matched with the air compressor for use, the slide block is arranged on one side, far away from the air guide pipe, of the piston and is fixedly connected, the slide block moves along with the piston when the piston moves, the reset cylinder is arranged on one side, far away from the piston, of the slide block, the reset spring is arranged in the reset cylinder, the slide block moves towards the reset cylinder, the reset spring is fixedly connected with the slide block and is extruded and contracted, and when the air compressor stops working, the reset spring pushes the slide block to be restored to the original state, the end, far away from the piston, of the sliding block is arranged in the twisting box, the sliding block is connected with the twisting box and the sliding barrel, a chain connecting block is arranged on the sliding block, the chain connecting block is located in the twisting box and fixedly connected with a chain, the chain connecting block is connected with a section, closest to the chain connecting block and a second driven gear, of the chain, and movement of the chain cannot be affected, the chain is a ring-mounted chain, a first driven gear is arranged in the twisting box, the second driven gear and a spiral shaft gear are arranged in the chain, when the chain is movable, the first driven gear, the second driven gear and the spiral shaft gear can rotate along with the chain, the first driven gear, the second driven gear and the spiral shaft gear are meshed, the spiral shaft gear is fixedly connected with the spiral shaft, and when the spiral shaft gear rotates, the spiral shaft can rotate along with the chain.

The reset spring is a memory spring which can effectively restore the sliding block to the initial position, and because most pneumatic valve actuators are located at positions which are inconvenient for operators to touch, the operators cannot interfere in the external environment where the reset spring is located, so that the memory spring plays a great role here.

The centers of circles of the first driven gear, the second driven gear and the spiral shaft gear are on the same straight line, the radiuses of the first driven gear, the second driven gear and the spiral shaft gear are the same, the spiral shaft gear can be subjected to double-acting force due to the structural design and the position relation, the movement of the sliding block cannot be influenced, the number of teeth of the first driven gear, the second driven gear and the spiral shaft gear is the same, and the first driven gear, the second driven gear and the spiral shaft gear can keep the same linear speed due to the structural design that the radiuses are the same and the number of teeth are the same.

Be provided with two right-angle boards on the slider, the right-angle board is symmetrical about the slider longitudinal section, and the slider wholly demonstrates "U" shape slider, and the case of turning round is kept apart through the slider with the slip section of thick bamboo, and such structural design can make the slider keep unanimous in the motion of turning round case and slip section of thick bamboo, can not cause the error.

The movable bumping post is provided with a movable bumping post convex groove which is symmetrical about the longitudinal section plane of the movable bumping post, the movable bumping post convex groove limits the moving direction and the moving posture of the movable bumping post, the diameter of the movable bumping post is equal to the diameter in the cavity of the valve pipe, the structure design can lead the movable blocking column to block the valve pipe cavity, lead the valve pipe cavity to stop running, lead the movable blocking column to be provided with internal threads, lead the movable blocking column to be connected with the screw shaft through threads, when the screw shaft rotates, the movable stop post moves downwards and completes the closing action of the pneumatic valve, a ball is arranged between the threads, the threads of the movable screw shaft are connected with the internal threads on the movable stop post through the ball, the structure design reduces the friction between the screw shaft and the movable catch column, enhances the moving smoothness of the movable catch column and prolongs the service life of the screw shaft and the movable catch column.

The valve tube includes: valve tube cavity, valve sleeve recess, valve tube cavity and valve sleeve fixed connection, the valve sleeve is perpendicular with valve tube cavity, such structural design can make more smooth and easy entering into valve tube cavity of activity bumping post, be provided with valve sleeve recess on the valve sleeve, valve sleeve recess is symmetrical about valve sleeve vertical section, activity bumping post tongue corresponds with valve sleeve recess position, valve sleeve recess provides the supporting role of position restriction for activity bumping post tongue, activity bumping post tongue and valve sleeve recess sliding connection.

The execution box body is connected with the valve pipe through the support, the distance between the execution box body and the valve pipe does not exceed the maximum extension amount of the movable retaining column, and the screw shaft and the movable retaining column can not be separated through the structural design, so that a continuous working state is achieved.

Compared with the prior art, the invention has the following beneficial effects: the invention has the following effects:

1. compared with the prior art, the invention has longer-term power supply performance, replaces a capacitor in the prior art through the timely reaction of the standby power supply, so that the air compressor can operate more durably, the insufficient air supply of the air compressor caused by the stop of the capacitor can be avoided, and the pneumatic valve can be closed more stably;

2. compared with the prior art, the invention adopts the principle of single action of the air compressor to realize the bidirectional stress of the screw shaft gear, and simultaneously adds the return spring, after the circuit is provided or the fault is repaired, the air compressor stops working, so that the return spring is restored to the original state, the slide block is driven, the screw shaft drives the movable stop post, the pneumatic valve is opened, and the normal operation can be realized, thereby solving the technical problem that the screw shaft cannot be reset in the prior art;

3. compared with the prior art, through the lead screw principle, replace the rotary valve among the conventional art, open and close the effect and all be superior to the conventional art, compare with prior art, such structural design has increased the stability of opening the valve and closing the valve.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic elevation view of the present invention;

FIG. 3 is a cross-sectional structural schematic view of an implement housing of the present invention;

FIG. 4 is a schematic view of the structure A of the present invention;

FIG. 5 is a longitudinal cross-sectional structural schematic view of the sliding fender of the present invention;

FIG. 6 is a schematic top view of the sliding stop post of the present invention;

FIG. 7 is a schematic top view of the valve tube of the present invention;

FIG. 8 is a schematic view of the workflow architecture of the present invention;

in the figure: 1. a standby power supply; 2. an air compressor; 3. an air duct; 4. a piston; 5. a slider; 5-1, a chain connecting block; 6. a return spring; 7. a chain; 8. a first driven gear; 9. a second driven gear; 10. a screw shaft; 10-1, a helical shaft gear; 11. a movable bumping post; 11-1, a movable bumping post convex groove; 12. a valve tube; 12-1, a valve sleeve; 12-2, a valve sleeve groove; 12-3, a valve pipe cavity; 13. an execution box body; 13-1, a sliding cylinder; 13-2, a reset cylinder; 13-3, and a torsion box.

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. 1-8, the present invention provides the following technical solutions: a pneumatic valve actuator with an emergency stop protection device is characterized in that: the actuator includes: the device comprises a standby power supply 1, an air compressor 2, an air duct 3, an execution box body 13, a screw shaft 10, a sliding barrier column 11 and a valve pipe 12, wherein one end of the standby power supply 1 is connected with a power supply, the standby power supply 1 can detect whether current passes through the power supply, when current exists, the standby power supply 1 does not discharge, no current passes through the power supply, the standby power supply 1 discharges, the output end of the standby power supply 1 is connected with the air compressor 2 through a lead and provides electric energy for the air compressor 2, the output end of the air compressor 2 is provided with the air duct 3, one end, far away from the air compressor 2, of the air duct 3 is connected with the execution box body 13, the air compressor 2 continuously outputs air pressure into the execution box body 13 through the air duct 3, the lower end of the execution box body 13 is provided with the screw shaft 10 for supporting the screw shaft 10, the screw shaft 10 is provided with threads, the lower end of the screw shaft 10 is provided with the movable barrier column 11, the movable bumping post 11 can move up and down along with the rotation of the screw shaft 10, the movable bumping post 11 is embedded into the valve tube 12, and the valve tube 12 limits the moving direction and distance of the movable bumping post 11.

The execution box body 13 includes therein: the device comprises a sliding cylinder 13-1, a reset cylinder 13-2, a torsion box 13-3, a piston 4, a slide block 5, a chain connecting block 5-1, a reset spring 6, a chain 7, a first driven gear 8, a second driven gear 9 and a screw shaft gear 10-1, wherein an execution box body 13 comprises the sliding cylinder 13-1, the reset cylinder 13-2 and the torsion box 13-3, the division of the box bodies is different, the sliding cylinder 13-1 and one end of an air duct 3, which is far away from an air compressor 2, are fixedly connected, the air compressor 2 pumps air into the sliding cylinder 13-1, the sliding cylinder 13-1 is internally provided with the piston 4, the piston 4 is matched with the air compressor 2 for use, one side of the piston 4, which is far away from the air duct 3, is provided with the slide block 5, the piston 4 is fixedly connected with the slide block 5, and when the piston 4 moves, the slide block 5 moves together with the piston 4, a reset cylinder 13-2 is arranged on one side of the sliding block 5 far away from the piston 4, a reset spring 6 is arranged in the reset cylinder 13-2, the sliding block 5 moves towards the reset cylinder 13-2, the reset spring 6 is fixedly connected with the sliding block 5, the reset spring 6 is extruded and contracted, when the air compressor 2 stops working, the reset spring 6 can push the sliding block 5 to restore to the original state, one end of the sliding block 5 far away from the piston 4 is arranged in a torsion box 13-3, the sliding block 5 is connected with the torsion box 13-3 and the sliding cylinder 13-1, a chain connecting block 5-1 is arranged on the sliding block 5, the chain connecting block 5-1 is positioned in the torsion box 13-3, the chain connecting block 5-1 is fixedly connected with the chain 7, the chain connecting block 5-1 is connected with one section of the chain 7, which is closest to the chain connecting block 5-1 and a second driven gear 9, the chain 7 is an annular chain, a first driven gear 8, a second driven gear 9 and a spiral shaft gear 10-1 are arranged in the chain 7 in the torsion box 13-3, the first driven gear 8 and the second driven gear 9 play a role in supporting the chain 7, when the chain 7 moves, the first driven gear 8, the second driven gear 9 and the spiral shaft gear 10 rotate along with the chain, the first driven gear 8, the second driven gear 9 and the spiral shaft gear 10-1 are meshed, the spiral shaft gear 10-1 is fixedly connected with the spiral shaft 10, and when the spiral shaft gear 10-1 rotates, the spiral shaft 10 rotates along with the chain.

The return spring 6 is a memory spring which can effectively restore the sliding block 5 to the original position, and because most pneumatic valve actuators are located at positions which are inconvenient for operators to touch, the operators cannot interfere with the external environment where the return spring 6 is located, so that the memory spring plays a great role here.

The centers of the first driven gear 8, the second driven gear 9 and the screw shaft gear 10-1 are on the same straight line, the radiuses of the first driven gear 8, the second driven gear 9 and the screw shaft gear 10-1 are the same, the structural design and the position relation can enable the screw shaft gear to be subjected to double-acting force without influencing the movement of the sliding block 5, the numbers of teeth of the first driven gear 8, the second driven gear 9 and the screw shaft gear 10-1 are the same, and the structural design with the same radiuses and the same numbers of teeth can enable the first driven gear 8, the second driven gear 9 and the screw shaft gear 10-1 to keep the same linear speed.

The slider 5 is provided with two right-angle plates which are symmetrical about the longitudinal section of the slider 5, the slider 5 integrally presents a U-shaped slider 5, the torsion box 13-3 is isolated from the sliding cylinder 13-1 through the slider 5, and the slider 5 can keep consistent in movement in the torsion box 13-3 and the sliding cylinder 13-1 through the structural design, so that errors cannot be caused.

The movable bumping post 11 is provided with a movable bumping post convex groove 11-1, the movable bumping post convex groove 11-1 is symmetrical about the longitudinal section of the movable bumping post 11, the movable bumping post convex groove 11-1 limits the moving direction and moving posture of the movable bumping post 11, the diameter of the movable bumping post 11 is equal to the inner diameter of the valve pipe cavity 12-3, the structure design can lead the movable bumping post 11 to block the valve pipe cavity 12-3, the valve pipe cavity 12-3 stops the running state, the movable bumping post 11 is provided with inner threads, the movable bumping post 11 is connected with the screw shaft 10 by threads, when the screw shaft 10 rotates, the movable bumping post 11 will move downwards and complete the closing action of the pneumatic valve, balls are arranged between the threads, the threads of the movable screw shaft 10 are connected with the inner threads on the movable bumping post 11 by the balls, the structure design reduces the friction between the screw shaft 10 and the movable bumping post 11, the moving smoothness of the movable bumping post 11 is enhanced, and the service life of the screw shaft 10 and the movable bumping post 11 is prolonged.

The valve tube 12 includes: the valve sleeve 12-1 is provided with the valve sleeve groove 12-2, the valve sleeve groove 12-2 is symmetrical about the longitudinal section of the valve sleeve 12-1, the movable barrier column convex groove 11-1 corresponds to the valve sleeve groove 12-2 in position, the valve sleeve groove 12-2 provides a supporting function of position limitation for the movable barrier column convex groove 11-1, and the movable barrier column convex groove 11-1 is connected with the valve sleeve groove 12-2 in a sliding mode.

The execution box body 13 is connected with the valve pipe 12 through a support, the distance between the execution box body 13 and the valve pipe 12 does not exceed the maximum extension amount of the movable retaining column 11, and the structure design can ensure that the screw shaft 10 cannot be separated from the movable retaining column 11, so that a continuous working state is achieved.

The working principle of the invention is as follows: the last power that is connected with of stand-by power supply 1, when the power disconnection, stand-by power supply 1 can open automatically, stand-by power supply 1 is connected with air compressor 2, 2 output of air compressor are connected with air duct 3, the air duct 3 other end is connected with slide cartridge 13-1, be provided with slider 5 in the slide cartridge 13-1, slider 5 is close to 3 one ends of air duct and is provided with piston 4, piston 4 is connected with slider 5, be provided with on slider 5 and be provided with chain connecting block 5-1, chain connecting block 5-1 is connected with chain 7, include in the execution box 13: a sliding cylinder 13-1, a reset cylinder 13-2 and a twisting box 13-3, wherein a reset spring 6 is arranged in the reset cylinder 13-2, one end of the reset spring 6 is connected with a sliding block 5, a first driven gear 8, a second driven gear 9 and a screw shaft gear 10-1 are arranged in the twisting box 13-3, a screw shaft 10 is arranged on the screw shaft gear 10-1, the screw shaft 10 is connected with a movable catch column 11, a valve sleeve 12-1 is arranged on a valve pipe cavity 12-3, the movable catch column 11 is arranged in the valve sleeve 12-1, when no current flows in a power supply, a standby power supply 1 is started to control the air compressor 2 to work and pump air into the sliding cylinder 13-1, the piston 4 drives the sliding block 5 to move towards the reset cylinder 13-2, the reset spring 6 in the reset cylinder 13-2 contracts, a chain connecting block 5-1 on the sliding block 5 drives a chain 7 to move, the chain 7 drives the first driven gear 8, the second driven gear 9 and the screw shaft gear 10-1 to rotate, the screw shaft gear 10-1 drives the screw shaft 10 to rotate, so that the movable stop pillar 11 moves downwards and enters the valve pipe cavity 12-3, the pneumatic valve is closed, after the power supply recovers current transportation, the standby power supply 1 stops working, the reset spring 6 is released, the sliding block 5 recovers to an initial state, the chain 7 is driven, the screw shaft 10 is enabled to reverse, the movable stop pillar 11 moves upwards, and the opening operation of the pneumatic valve is completed.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.