CN112763657A - Internet of things monitoring automatic exhaust system and method - Google Patents

Abstract

The invention discloses an automatic exhaust system and method for monitoring Internet of things, which structurally comprises the following steps: the invention relates to a pneumatic transmission device, a support seat, a device shell, an exhaust pipe, a controller, a display screen and a control key, wherein the controller is positioned on the upper surface of the device shell and is of an integrated structure with the device shell, the support seat is positioned on the lower surface of the device shell and is welded with the device shell into an integrated structure, the pneumatic transmission device is positioned on the right side surface of the device shell and is fixedly connected with the device shell, the display screen is positioned at the upper end of the front surface of the controller and is mechanically connected with the controller, the control key is positioned below the display screen and is fixedly connected with the controller, and the exhaust pipe is fixedly arranged on the left side surface of the device shell. The energy conversion and utilization are realized through certain transmission, so that the device is more complete.

Description

Internet of things monitoring automatic exhaust system and method

The invention relates to a divisional application of an automatic exhaust device for monitoring air quality through the Internet of things, wherein the application date is 2017, 11, month and 4, and the application number is CN 201711072264.8.

Technical Field

The invention discloses an automatic exhaust system and method for monitoring of an internet of things, and belongs to the field of air quality detection.

Background

Air, a "life gas" that we breathe every day, is layered on the earth's surface, is transparent, colorless and odorless, is mainly composed of nitrogen and oxygen, and has an important influence on human survival and production, and air refers to a gas mixture in the earth's atmosphere. It is a mixture mainly composed of 78% of nitrogen, 21% of oxygen, 0.93% of rare gas (helium, neon, argon, krypton, xenon), 0.04% of carbon dioxide, and 0.03% of other substances (such as water vapor, impurities, etc.). The composition of the air is not fixed, and the composition ratio of the air changes along with the change of the height and the change of the air pressure. However, air has long been considered a single substance until the french scientist lavan has since first experimentally concluded that air is composed of oxygen and nitrogen. At the end of the 19 th century, scientists found that the air contained rare gases such as helium, argon and xenon through a large number of experiments.

Air detection in a broad sense refers to detection of the constituent components of air. In the narrow sense of air detection, mainly from the application point of view, indoor air detection is the focus of research. The air quality detection device is used for detecting air quality by means of decoration pollution caused by substances harmful to human bodies contained in indoor decoration materials, furniture and the like and released into home and office environments. The national 'civil construction engineering indoor environmental pollution control regulations' issued and implemented in 2006 lists five main pollutants, namely formaldehyde, benzene, ammonia gas, Total Volatile Organic Compounds (TVOC), radioactive radon and the like.

However, the prior art exhaust detection device cannot separate detection from exhaust and cannot effectively utilize the air pressure formed by the sucked gas, and the device cannot be more perfect because energy conversion and utilization are realized through certain transmission.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide an automatic exhaust system and method for monitoring of the internet of things, and the system and method are used for solving the problems that an exhaust device cannot be separated from exhaust during detection and cannot effectively utilize air pressure formed by sucked gas, energy conversion and utilization are realized through certain transmission, and the device cannot be more complete.

In order to achieve the purpose, the invention is realized by the following technical scheme: an Internet of things monitoring automatic exhaust system and method structurally comprise: pneumatic transmission device, supporting seat, device casing, blast pipe, controller, display screen, control button.

The controller is positioned on the upper surface of the device shell and is of an integrated structure with the device shell, the supporting seat is positioned on the lower surface of the device shell and is welded with the device shell into an integrated structure, the pneumatic transmission device is positioned on the right side surface of the device shell and is fixedly connected with the device shell, the display screen is positioned at the upper end of the front surface of the controller and is mechanically connected with the controller, the control key is positioned below the display screen and is fixedly connected with the controller, and the exhaust pipe is fixedly installed on the left side surface of the device shell;

the pneumatic transmission device is provided with an air outlet pipe, a sliding frame, a sliding block, a connecting frame rod, a transmission rod, a rotating disk, a driving wheel, a gear shaft, a bevel gear, a driven wheel, a core shaft rod, a shell, a speed reducer, a rotating motor, a generator, a pushing rod, a rubber block, a connecting flange, a connecting wire, a wire box, a wind wheel, an assembling plate, an air inlet pipe, a pneumatic channel, a wind wheel motor, an air outlet, a movable spring, a pipeline connector, a movable baffle, an air release valve body, a movable block and a pushing device;

the wind wheel motor is positioned on the upper surface of the air pressure channel and fixedly connected with the air pressure channel, the wind wheel is positioned inside the air pressure channel and movably connected with the wind wheel motor by penetrating through the air pressure channel, the air inlet pipe is positioned on the right side surface of the air pressure channel and is of an integrated structure with the air pressure channel, the assembling plate is positioned on the right side of the air inlet pipe and is mechanically connected with the air inlet pipe, the wire box is positioned on the upper surface of the wind wheel motor and is electrically connected with the wind wheel motor, the generator is positioned on the right side of the inner side surface of the shell and is electrically connected with a connecting wire, the rotating motor is positioned on the left side surface of the generator and is movably matched with the generator, the speed reducer is positioned on the left side surface of the rotating motor and is movably connected with the rotating motor, the mandrel rod is positioned in the, the bevel gear is positioned on the lower surface of the driven wheel and is meshed with the driven wheel, the bevel gears are connected together through a gear shaft, the air release valve is positioned on the upper surface of an air pressure channel and is fixedly connected through a pipeline connector, the movable baffle is positioned on the right side surface of the air release valve body and is movably matched with the air release valve body, the movable spring is positioned on the rear side surface of the movable baffle and is fixedly connected with the movable baffle, the air outlet is positioned on the right side surface of the air release valve body and is in an integrated structure with the air release valve body, the pushing device is positioned on the upper surface of the air release valve body and is in threaded connection with the air release valve body, the movable block is positioned on the lower surface of the pushing device and is movably connected with the pushing device, the connecting flange is positioned on the left side surface of the air release valve body and, the utility model discloses a pneumatic cylinder, including pneumatic cylinder, catch bar, linking pole, actuating lever, the catch bar is located the front surface of rubber block and with rubber block fixed connection, the outlet duct is located the lower surface of pneumatic cylinder and is integrated structure with the pneumatic cylinder, the linking pole is located the front surface of catch bar and with catch bar swing joint, the linking pole is located the upper surface of sliding block and with sliding block fixed connection, the sliding block is located the lateral surface of carriage and adopts clearance fit with the carriage, the actuating lever is located the lateral surface of.

Furthermore, the pushing device is provided with a movable cover, a telescopic rod, a matching column and connecting threads.

Furthermore, the movable cover is located on the right side face of the telescopic rod and fixedly connected with the telescopic rod, the matching column is located on the left side face of the telescopic rod and mechanically connected with the telescopic rod, and the connecting thread is located on the outer side face of the matching column and is in an integrated structure with the matching column.

Furthermore, two bevel gears which are parallel to each other are arranged on the gear shaft from top to bottom.

Further, the rotating disc and the driving wheel are of concentric disc-shaped structures.

Further, the air pressure channel is communicated with the air release valve body.

Further, the device shell is made of a metal material.

Furthermore, a crystal joint capable of being communicated with a network is arranged on the controller.

Advantageous effects

The invention relates to an automatic exhaust system and method for monitoring Internet of things, which comprises the steps of powering on a device, starting up the device by using a display screen and a control button on a controller, enabling a wire box to enable a wind wheel motor to be powered on, enabling a wind wheel on the wind wheel motor to rotate to suck air from near future light, enabling air to enter the inside of an exhaust valve body through an air pressure channel, enabling a telescopic rod to be driven by rotation of a movable cover to enable a connecting thread to move backwards to drive a movable block to enable air pressure to push a rubber block forwards through the direction of a pipeline of the air pressure channel, enabling a push rod to move forwards to push a connecting rod to move the connecting rod backwards through a sliding block under the action of force, enabling the connecting rod to drive a transmission rod to move backwards, enabling the connecting rod to move forwards again at a critical point, the driving wheel drives the bevel gear to rotate, the bevel gear above the driving wheel rotates to drive the driven wheel to rotate through the transmission of the gear shaft, the driven wheel and a mandrel rod integrated with the driven wheel rotate simultaneously, the mandrel rod is decelerated through the reducer, the rotating motor physically rotates, the stator and the rotor rotate simultaneously, the generator generates electricity, current is applied to the wind wheel motor through a connecting wire again, after the rubber block is pushed to a certain position by air pressure, the air pressure is discharged from the air outlet pipe and conveyed to the controller, the controller is detected through the detector and displayed on the display screen, and when the detection is not needed and only the exhaust is needed, the pushing device can be used for pushing the movable block to close the air release valve body, so that the air pressure presses the movable baffle plate to compress the movable spring, the air is directly discharged from the air outlet, and the time operation time of the pipeline is, therefore, the purposes that the exhaust detection device can separate detection and exhaust and can effectively utilize the air pressure formed by the sucked gas and realize the conversion and utilization of energy sources through certain transmission can be achieved, and the device is more complete can be achieved.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

fig. 1 is a schematic structural diagram of an internet of things monitoring automatic exhaust system and method.

Fig. 2 is a schematic structural view of the pneumatic actuator of the present invention.

FIG. 3 is a first schematic view of the pneumatic actuator of the present invention.

Fig. 4 is a schematic diagram of a pneumatic actuator according to a second embodiment of the present invention.

FIG. 5 is a schematic view of the pushing device of the present invention.

In the figure: an air pressure transmission device-1, a support seat-2, a device shell-3, an exhaust pipe-4, a controller-5, a display screen-6, a control button-7, an air outlet pipe-101, a sliding frame-102, a sliding block-103, a connecting frame rod-104, a transmission rod-105, a rotating disc-106, a driving wheel-107, a gear shaft-108, a bevel gear-109, a driven wheel-110, a core shaft rod-111, a shell-112, a speed reducer-113, a rotating motor-114, a generator-115, a push rod-116, a rubber block-117, a connecting flange-118, a connecting wire-119, a wire box-120, a wind wheel-121, an assembly plate-122, an air inlet pipe-123, an air pressure channel-124, a wind wheel motor-125, Air outlet-126, movable spring-127, pipeline connector-128, movable baffle-129, air relief valve-130, movable block-131, pushing device-132, movable cover-13201, telescopic rod-13202, matching column-13203 and connecting screw-13204.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Referring to fig. 1-5, the invention provides an internet of things monitoring automatic exhaust system and method, and the technical scheme is as follows: the structure includes: the device comprises a pneumatic transmission device 1, a supporting seat 2, a device shell 3, an exhaust pipe 4, a controller 5, a display screen 6 and a control key 7.

The controller 5 is positioned on the upper surface of the device shell 3 and is of an integrated structure with the device shell 3, the supporting seat 2 is positioned on the lower surface of the device shell 3 and is welded with the device shell 3 into an integrated structure, the pneumatic transmission device 1 is positioned on the right side surface of the device shell 3 and is fixedly connected with the device shell 3, the display screen 6 is positioned at the upper end of the front surface of the controller 5 and is mechanically connected with the controller 5, the control keys 7 are positioned below the display screen 6 and are fixedly connected with the controller 5, and the exhaust pipe 4 is fixedly installed on the left side surface of the device shell 3;

the pneumatic transmission device 1 is provided with an air outlet pipe 101, a sliding frame 102, a sliding block 103, a connecting frame rod 104, a transmission rod 105, a rotating disk 106, a driving wheel 107, a gear shaft 108, a bevel gear 109, a driven wheel 110, a core shaft rod 111, a shell 112, a speed reducer 113, a rotating motor 114, a generator 115, a pushing rod 116, a rubber block 117, a connecting flange 118, a connecting wire 119, a wire box 120, a wind wheel 121, an assembly plate 122, an air inlet pipe 123, a pneumatic channel 124, a wind wheel motor 125, an air outlet 126, a movable spring 127, a pipeline connector 128, a movable baffle 129, a deflation valve body 130, a movable block 131 and a pushing device 132;

the wind wheel motor 125 is located on the upper surface of the air duct 124 and fixedly connected with the air duct 124, the wind wheel 121 is located inside the air duct 124 and movably connected with the wind wheel motor 125 through the air duct 124, the air inlet pipe 123 is located on the right side of the air duct 124 and is of an integrated structure with the air duct 124, the assembly plate 122 is located on the right side of the air inlet pipe 123 and is mechanically connected with the air inlet pipe 123, the wire box 120 is located on the upper surface of the wind wheel motor 125 and is electrically connected with the wind wheel motor 125, the generator 115 is located on the right side of the inner side of the housing 112 and is electrically connected with the connecting wire 119, the rotating motor 114 is located on the left side of the generator 115 and is movably matched with the generator 115, the speed reducer 113 is located on the left side of the rotating motor 114 and is movably connected with the rotating motor 114, the core shaft 111 is located in the center of the left side of the speed reducer 113 and 111 is an integrated structure, the bevel gear 109 is positioned on the lower surface of the driven wheel 110 and meshed with the driven wheel 110, the bevel gears 109 are connected together through a gear shaft 108, the vent valve body 130 is positioned on the upper surface of the air pressure passage 124 and fixedly connected through a pipeline connector 128, the movable baffle 129 is positioned on the right side surface of the vent valve body 130 and movably matched with the vent valve body 130, the movable spring 127 is positioned on the rear side surface of the movable baffle 129 and fixedly connected with the movable baffle 129, the air outlet 126 is positioned on the right side surface of the vent valve body 130 and integrated with the vent valve body 130, the pushing device 132 is positioned on the upper surface of the vent valve body 130 and threadedly connected with the vent valve body 130, the movable block 131 is positioned on the lower surface of the pushing device 132 and movably connected with the pushing device 132, the connecting flange 118 is positioned on the left side surface of the vent valve body 130 and fixedly connected with the vent valve, the rubber block 117 is positioned inside the pneumatic cylinder and movably matched with the pneumatic cylinder, the push rod 116 is positioned on the front surface of the rubber block 117 and fixedly connected with the rubber block 117, the air outlet pipe 101 is positioned on the lower surface of the pneumatic cylinder and is of an integrated structure with the pneumatic cylinder, the side link 104 is positioned on the front surface of the push rod 116 and is movably connected with the push rod 116, the side link 104 is positioned on the upper surface of the sliding block 103 and is fixedly connected with the sliding block 103, the sliding block 103 is positioned on the outer side surface of the sliding frame 102 and is in clearance fit with the sliding frame 102, the transmission rod 105 is positioned on the outer side surface of the rotating disc 106 and is fixedly connected with the rotating disc 106, the driving wheel 107 is positioned on the inner side surface of the rotating disc 106 and is of an integrated structure with the rotating disc 106, the driving wheel 107 is engaged, The device comprises a matching column 13203 and a connecting thread 13204, wherein the movable cover 13201 is positioned on the right side surface of the telescopic rod 13202 and is fixedly connected with the telescopic rod 13202, the matching column 13203 is positioned on the left side surface of the telescopic rod 13202 and is mechanically connected with the telescopic rod 13202, the connecting thread 13203 is positioned on the outer side surface of the matching column 13203 and is integrated with the matching column 13202, two bevel gears 109 which are parallel to each other are arranged on the gear shaft 108, the rotating disc 106 and the driving wheel 107 are of concentric disc structures, the air pressure channel 124 is communicated with the air release valve body 130, the device shell 3 is made of a metal material, and a crystal joint capable of being communicated with a network is arranged on the controller 5.

The pushing device 132 of the present invention is a device for extending and retracting the telescopic instrument of the telescopic rod by using a screw displacement manner.

When the device is used, the device is powered on, then the display screen 6 and the control keys 7 on the controller 5 are utilized to start the device, then the wire box 120 enables the wind wheel motor 125 to be powered on, then the wind wheel 121 on the wind wheel motor 125 rotates to suck air from the near-term light 123, the air enters the inside of the air discharge valve body 130 through the air pressure channel 124, the movable cover 13201 rotates to drive the telescopic rod 13202 to enable the connecting thread 13204 to move backwards to drive the movable block 131 to enable the air pressure to push the rubber block 117 forwards through the trend of the pipeline of the air pressure channel 124, so that the pushing rod 116 moves forwards to push the connecting rod 104 to move backwards on the sliding frame 102 through the sliding block 103 under the action of force, so that the connecting rod 104 drives the transmission rod 105 backwards, the connecting rod 104 moves forwards again at a critical point reaching the sliding frame 102 and pushes the transmission rod 105 to enable the rotary disc, so that the driving wheel 107 drives the bevel gear 109 to rotate, the bevel gear 109 above the driving wheel is driven by the transmission of the gear shaft 108 to drive the driven wheel 110 to rotate, the driven wheel 110 rotates with the spindle rod 111 integrated with the driven wheel, the spindle rod 111 is decelerated by the decelerator 112, the rotating motor 114 physically rotates, the stator and the rotor rotate, the generator 115 generates electricity, and the current is acted on the wind wheel motor 125 through the connecting wire again, meanwhile, after the rubber block 116 is pushed to a certain position by the air pressure, the air pressure is discharged from the air outlet pipe 101 and conveyed to the controller 5, detected by the detector and displayed on the display screen 6, and when the detection is not needed, the pushing device 132 can be utilized to push the movable block 131 to close the air discharge valve body 130 so that the air pressure presses the movable baffle 129 to compress the movable spring 127, so that the air is directly discharged from the air outlet 126, saving the time running time of the pipeline.

The invention solves the problems that the detection exhaust device can not be separated from the exhaust and can not effectively utilize the air pressure formed by the sucked gas, the conversion and utilization of energy can be realized through certain transmission, and the device can not be more perfect.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics 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.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (6)

1. The utility model provides an automatic exhaust apparatus of monitoring air quality through thing networking, its structure includes: pneumatic transmission device (1), supporting seat (2), device casing (3), blast pipe (4), controller (5), display screen (6), control button (7), its characterized in that:

the controller (5) is located on the upper surface of the device shell (3) and is of an integrated structure with the device shell (3), the supporting seat (2) is located on the lower surface of the device shell (3) and is welded with the device shell (3) to form an integrated structure, the pneumatic transmission device (1) is located on the right side surface of the device shell (3) and is fixedly connected with the device shell (3), the display screen (6) is located at the upper end of the front surface of the controller (5) and is mechanically connected with the controller (5), the control key (7) is located below the display screen (6) and is fixedly connected with the controller (5), and the exhaust pipe (4) is fixedly installed on the left side surface of the device shell (3);

the pneumatic transmission device (1) is provided with an air outlet pipe (101), a sliding frame (102), a sliding block (103), a connecting frame rod (104), a transmission rod (105), a rotating disk (106), a driving wheel (107), a gear shaft (108), a bevel gear (109), a driven wheel (110), a mandrel rod (111), a shell (112), a speed reducer (113), a rotating motor (114), a generator (115), a push rod (116), a rubber block (117), a connecting flange (118), a connecting wire (119), a wire box (120), a wind wheel (121), an assembling plate (122), an air inlet pipe (123), an air pressure channel (124), a wind wheel motor (125), an air outlet (126), a movable spring (127), a pipeline connector (128), a movable baffle (129), a deflation valve body (130), a movable block (131) and a pushing device (132;

the wind wheel motor (125) is positioned on the upper surface of the air pressure channel (124) and fixedly connected with the air pressure channel (124), the wind wheel (121) is positioned inside the air pressure channel (124) and penetrates through the air pressure channel (124) to be movably connected with the wind wheel motor (125), the air inlet pipe (123) is positioned on the right side surface of the air pressure channel (124) and is of an integrated structure with the air pressure channel (124), the assembly plate (122) is positioned on the right side of the air inlet pipe (123) and is mechanically connected with the air inlet pipe (123), the wire box (120) is positioned on the upper surface of the wind wheel motor (125) and is electrically connected with the wind wheel motor (125), the generator (115) is positioned on the right side of the inner side surface of the shell (112) and is electrically connected with the connecting wire (119), the rotating motor (114) is positioned on the left side surface of the generator (115) and is movably matched with the generator (115), the speed reducer (113) is positioned on the left side surface of the, the mandrel rod (111) is positioned at the center of the left side surface of the speed reducer (113) and embedded in the speed reducer (113), the driven wheel (110) is positioned on the outer side surface of the shell (112) and is of an integrated structure with the mandrel rod (111), the bevel gear (109) is positioned on the lower surface of the driven wheel (110) and is meshed with the driven wheel (110), the bevel gears (109) are connected together through a gear shaft (108), the air release valve body (130) is positioned on the upper surface of the air pressure passage (124) and is fixedly connected through a pipeline connector (128), the movable baffle (129) is positioned on the right side surface of the air release valve body (130) and is movably matched with the air release valve body (130), the movable spring (127) is positioned on the rear side surface of the movable baffle (129) and is fixedly connected with the movable baffle (129), the air outlet (126) is positioned on the right side surface of the air release valve body (130) and is of an integrated structure with the, the pushing device (132) is positioned on the upper surface of the air release valve body (130) and is in threaded connection with the air release valve body (130), the movable block (131) is positioned on the lower surface of the pushing device (132) and is movably connected with the pushing device (132), the connecting flange (118) is positioned on the left side surface of the air release valve body (130) and is fixedly connected with the air release valve body (130), the rubber block (117) is positioned inside the pneumatic cylinder and is movably matched with the pneumatic cylinder, the pushing rod (116) is positioned on the front surface of the rubber block (117) and is fixedly connected with the rubber block (117), the air outlet pipe (101) is positioned on the lower surface of the pneumatic cylinder and is in an integrated structure with the pneumatic cylinder, the connecting rod (104) is positioned on the front surface of the pushing rod (116) and is movably connected with the pushing rod (116), the connecting rod (104) is positioned on the upper surface of the sliding block (103) and is fixedly connected with the sliding, the sliding block (103) is positioned on the outer side face of the sliding frame (102) and is in clearance fit with the sliding frame (102), the transmission rod (105) is positioned on the outer side face of the rotating disk (106) and is fixedly connected with the rotating disk (106), the driving wheel (107) is positioned on the inner side face of the rotating disk (106) and is of an integrated structure with the rotating disk (106), and the driving wheel (107) is meshed with the bevel gear (109);

the pushing device (132) is provided with a movable cover (13201), a telescopic rod (13202), a matching column (13203) and a connecting thread (13204).

2. The automatic exhaust device for monitoring the air quality through the Internet of things according to claim 1, is characterized in that: the movable cover (13201) is located on the right side face of the telescopic rod (13202) and fixedly connected with the telescopic rod (13202), the matching column (13203) is located on the left side face of the telescopic rod (13202) and mechanically connected with the telescopic rod (13202), and the connecting thread (13203) is located on the outer side face of the matching column (13203) and is of an integrated structure with the matching column (13202).

3. The automatic exhaust device for monitoring the air quality through the Internet of things according to claim 1, is characterized in that: two bevel gears (109) which are parallel to each other are arranged on the gear shaft (108) up and down.

4. The automatic exhaust device for monitoring the air quality through the Internet of things according to claim 1, is characterized in that: the rotating disc (106) and the driving wheel (107) are in concentric disc-shaped structures.

5. The automatic exhaust device for monitoring the air quality through the Internet of things according to claim 1 is characterized in that: the air pressure channel (124) is communicated with the air release valve body (130).

6. The Internet of things monitoring automatic exhaust system and method according to any one of claims 1-5, wherein:

when the device is used, the device is powered on, then the device is started up by using a display screen (6) on a controller (5) and a control key (7), then a wire box (120) enables a wind wheel motor (125) to be powered on, and then a wind wheel (121) on the wind wheel motor (125) rotates to suck air from a near-term light (123);

the air enters the interior of the air release valve body (130) through the air pressure channel (124), the movable cover (13201) is rotated to drive the telescopic rod (13202) to enable the connecting thread (13204) to move backwards to drive the movable block (131) to enable the air pressure to push the rubber block (117) forwards through the pipeline of the air pressure channel (124), so that the push rod (116) moves forwards to push the connecting rod (104) to move backwards on the sliding frame (102) through the sliding block (103) under the action of force to enable the connecting rod (104) to drive the transmission rod (105) to move backwards;

when reaching a critical point of the sliding frame (102), the side link (104) moves forwards again and pushes the transmission rod (105) to enable the rotary disk (106) to move back and forth on the transmission rod (105) to enable the rotary disk (106) to rotate and drive the main driving wheel (107) to rotate, so that the driving wheel (107) drives the bevel gear (109) to rotate, the upper bevel gear (109) rotates through the transmission of the gear shaft (108) to drive the driven wheel (110) to rotate, the driven wheel (110) rotates simultaneously with the core shaft rod (111) which is integrated with the driven wheel, and the core shaft rod (111) is decelerated through the reducer (112) to enable the rotating motor (114) to rotate physically;

meanwhile, the stator and the rotor are rotated, the generator (115) generates electricity, current is acted on the wind wheel motor (125) through a connecting wire again, meanwhile, after the rubber block (116) is pushed to a certain position by air pressure, the air pressure can be discharged from the air outlet pipe (101) and conveyed to the controller 5 to be detected through the detector and displayed on the display screen (6), and when the air is only discharged without detection, the pushing device (132) can be utilized to push the movable block (131) to seal the air discharge valve body (130) so that the movable baffle (129) is pressed by the air pressure to compress the movable spring (127), the air is directly discharged from the air outlet (126), and the time running time of a pipeline is saved.

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