CN212959020U - Intelligent air pump regulator - Google Patents

Abstract

The utility model discloses an intelligent air pump regulator, including the regulator box, the regulator box is the cuboid, and its left surface middle part is provided with the air supply entry, corresponds on the right flank to be provided with the tuber pipe connector, is provided with air regulation knob on the top surface, is provided with the barometer group on the leading flank, and the top of air supply entry is provided with the switch, and the below is provided with the power connector, and the below of tuber pipe connector is provided with the silencer; a vacuum valve is arranged in the regulator box body; one end of the vacuum valve is provided with an air inlet, the other end of the vacuum valve is provided with an air pipe connector, one end of the vacuum valve is communicated with the air source inlet through the air inlet, and the other end of the vacuum valve is connected with the air source type flight reach through the air pipe connector. The utility model discloses not only replaced traditional motor formula carbon piece air pump, practiced thrift the energy, reduced manufacturing cost, reduced the noise, avoided moreover to produce adverse effect to the healthy and operational environment of staff, improved the operational environment in workshop.

Description

Intelligent air pump regulator

Technical Field

The utility model relates to a regulator especially relates to an intelligence air pump regulator.

Background

The automatic production efficiency is high, the speed is high, more than 90% of the used production machinery is full-automatic intelligent equipment, such as a full-automatic or semi-automatic stamping machine, a full-automatic or semi-automatic screen printing machine, a full-automatic or semi-automatic die cutting machine and the like in the printing industry. The automatic paper conveying device of the full-automatic or semi-automatic machine is provided with a traditional motor type carbon sheet air pump to provide positive and negative pressure air flow for the paper conveying flight, so that the paper conveying flight can automatically convey paper at high speed.

The traditional motor type carbon sheet air pump is driven by a motor, and the power is generally 3000-. The traditional motor type carbon sheet air pump used in the production scene in the market at present can generate larger noise when in operation, and the noise can reach more than 80-90 decibels. Traditional motor formula carbon piece air pump can produce the high heat when the operation, and the long-time back of operation, motor temperature can reach more than 100 degrees centigrade, and long-time use in succession can burn out the motor because high temperature operation, and the heat that gives off also can influence the control of workshop humiture.

The traditional motor type carbon sheet air pump can also wear the carbon sheet when in operation, the carbon sheet needs to be replaced for 2-3 times every year, and the waste residue of the carbon sheet can drift out to pollute the working environment of a workshop and influence the body health of an operator. Therefore, there is a need in the market for an air pump regulator capable of improving the workshop environment and reducing energy and noise to replace the conventional motor-type carbon sheet air pump.

SUMMERY OF THE UTILITY MODEL

In order to solve the defects of the prior art, the utility model provides an intelligent air pump regulator.

In order to solve the technical problem, the utility model discloses a technical scheme is: an intelligent air pump regulator comprises a regulator box body, wherein the regulator box body is a cuboid, an air source inlet is formed in the middle of the left side face of the regulator box body, an air pipe connecting port is correspondingly formed in the right side face of the regulator box body, an air quantity adjusting knob is arranged on the top face of the regulator box body, an air pressure gauge group is arranged on the front side face of the regulator box body, a switch is arranged above the air source inlet, a power supply connecting port is formed below the air source inlet, and a silencer is; a vacuum valve is arranged in the regulator box body;

one end of the vacuum valve is provided with an air inlet, the other end of the vacuum valve is provided with an air pipe connector, one end of the vacuum valve is communicated with an air source inlet through the air inlet, and the other end of the vacuum valve is connected with the air source type flight reach through the air pipe connector; an adjusting mechanism is arranged between the vacuum valve and the air source inlet, and the vacuum valve is communicated with the air source inlet through the adjusting mechanism; an air blowing channel and a shunt pipeline are arranged in the vacuum valve in parallel, one end of the air blowing channel and one end of the shunt pipeline are communicated with the air inlet, the other end of the air blowing channel and the other end of the shunt pipeline are communicated with the air pipe connecting opening, the shunt pipeline is communicated with the air pipe connecting opening through an air suction channel, and an air outlet pipe of the shunt pipeline is perpendicular to the air suction channel.

Further, an air inlet of the vacuum valve is communicated with the adjusting mechanism; the air inlet comprises a first air inlet communicated with the air blowing channel and a second air inlet communicated with the diversion pipeline; the air pipe connecting port comprises an air blowing port communicated with the air blowing channel and an air suction port communicated with the shunt pipeline.

Further, the air blowing channel comprises a first pipeline; one end of the first pipeline is communicated with the first air inlet, the other end of the first pipeline is communicated with the air blowing opening, and a ball valve is arranged between the first pipeline and the first air inlet.

Further, the flow dividing pipeline comprises a flow divider communicated with the second air inlet; the flow divider is provided with a plurality of outlets and is respectively communicated with a plurality of air outlet pipes through a plurality of outlets; a silencer is arranged at one end of the air outlet pipe far away from the shunt; the mufflers all comprise muffling pipes, and muffling holes are formed in the muffling pipes.

Furthermore, the air suction channel comprises suction pipes which are correspondingly connected with the air outlet pipes one by one; one end of the suction pipe is vertical to the air outlet pipe, and the other end of the suction pipe is communicated with the air suction port; a third barometer is arranged between the suction pipe and the air suction port.

Furthermore, the suction pipes comprise vertical pipe bodies connected with the air outlet pipes and bearing pipe bodies connected with the air suction ports; the vertical pipe bodies are vertical to the air outlet pipe; all having set up in the vertical body and having accepted the body, the junction of vertical body and accepting the body all is provided with sealing device, and sealing device all includes sealing ring, gasket, and the sealing ring all cup joints on accepting the body and is located vertical body, and the gasket sets up the one end that sets up in the left end of sealing ring and gasket and is connected with the sealing ring.

Furthermore, the air source type boomerangs comprise a first air source type boomerang connected with the air blowing port and a second air source type boomerang connected with the air suction port.

Furthermore, the adjusting mechanism comprises a blowing adjusting mechanism and a suction adjusting mechanism which are arranged in parallel; the air blowing adjusting mechanism comprises a first adjusting valve and a first electromagnetic valve which are arranged between the air source inlet and the first air inlet and are sequentially connected, the first adjusting valve is connected with a first air pressure gauge, and the first electromagnetic valve is connected with the first air source type flight platform through a first air flow sensor;

the air suction adjusting mechanism comprises a second adjusting valve and a second electromagnetic valve which are arranged between an air source inlet and a second air inlet and are sequentially connected, wherein the second adjusting valve is connected with a second air pressure meter, and the second electromagnetic valve is connected with a second air source type flight platform through a second air flow sensor.

Furthermore, the air volume adjusting knob comprises a first adjusting knob and a second adjusting knob; the first adjusting knob and the second adjusting knob are sequentially arranged from front to back along the top surface of the adjuster box body; the barometer group comprises a first barometer, a second barometer and a third barometer which are sequentially arranged from left to right.

Further, the air source inlet is communicated with the high-pressure air pipe port; the vacuum valve is connected with the high-pressure air pipe port through the air source inlet.

The utility model discloses a connect high-pressurepipe and realized blowing simultaneously and induced draft (negative pressure) operation, not only replaced traditional motor formula carbon piece air pump, the energy has been practiced thrift, production cost is reduced, the noise has been reduced, and the heat energy of having avoided traditional motor air pump among the prior art to produce because of wearing and tearing carbon piece when the operation produces adverse effect to staff's health and operational environment, energy-conservation falls the non-maintaining of making an uproar, for a large amount of industrial production enterprises the cost is practiced thrift and the operational environment in workshop has been improved.

Drawings

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

Fig. 2 is a schematic view of the internal structure of fig. 1.

Fig. 3 is a schematic view of the sealing sheet at the joint of the vertical pipe body and the receiving pipe body in a sealing state.

Fig. 4 is a schematic view showing the sealing sheet at the joint of the vertical pipe body and the receiving pipe body in an opened state.

In the figure: 1. a regulator case; 11. a switch; 12. a power supply connector; 2. a vacuum valve; 21. an air blowing port; 22. an air suction port; 23. a first air inlet; 24. a second air inlet; 25. a flow divider; 251. an air outlet pipe; 252. a muffler; 26. a ball valve; 27. a first pipeline; 28. a straw; 281. a vertical pipe body; 282. receiving the pipe body; 283. a seal ring; 284. sealing the sheet; 29. a third barometer; 3. a gas source inlet; 4. a first adjusting knob; 5. a second adjusting knob; 6. air source type Feida; 61. a first air source type Feida; 62. second, air source type Feida; 7. a blowing adjustment mechanism; 71. a first regulating valve; 72. a first electromagnetic valve; 73. a barometer; 74. a first airflow sensor; 8. an air suction adjusting mechanism; 81. a second regulating valve; 82. a second electromagnetic valve; 83. a second barometer; 84. and a second airflow sensor.

Detailed Description

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

As shown in fig. 1, the intelligent air pump regulator comprises a regulator box body 1, wherein the regulator box body 1 is a cuboid, an air source inlet 3 is arranged in the middle of the left side surface of the regulator box body 1, an air pipe connecting port is correspondingly arranged on the right side surface of the regulator box body, an air quantity adjusting knob is arranged on the top surface of the regulator box body, an air pressure gauge set is arranged on the front side surface of the regulator box body, a switch 11 is arranged above the air source inlet 3, a power supply connecting port 12 is arranged below the air source inlet, and a silencer; a vacuum valve 2 is arranged in the regulator box body 1; the gas source inlet 3 is communicated with a high-pressure gas pipe port; the vacuum valve 2 is connected with a high-pressure air pipe port through an air source inlet 3.

As shown in fig. 2, one end of the vacuum valve 2 is provided with an air inlet, and the other end is provided with an air pipe connector, one end of the vacuum valve 2 is communicated with the air source inlet 3 through the air inlet, and the other end is connected with the air source type flight path 6 through the air pipe connector; an adjusting mechanism is arranged between the vacuum valve 2 and the air source inlet 3, and the vacuum valve 2 is communicated with the air source inlet 3 through the adjusting mechanism; an air blowing channel and a shunt pipeline are arranged in the vacuum valve 2 in parallel, one end of the air blowing channel and one end of the shunt pipeline are communicated with an air inlet, the other end of the air blowing channel and the other end of the shunt pipeline are communicated with an air pipe connecting port, the shunt pipeline is communicated with the air pipe connecting port through an air suction channel, and an air outlet pipe 251 of the shunt pipeline is perpendicular to the air suction channel.

The utility model is provided with an air blowing channel and a shunt pipeline inside the vacuum valve on the basis of the prior vacuum valve, wherein the air blowing channel connects a first air inlet 23 with an air blowing port 21; the second air inlet 24 and the air suction pipeline are respectively connected with the shunt pipeline, and the other end of the air suction pipeline is communicated with the air suction port 22.

The air inlet of the vacuum valve 2 is communicated with the adjusting mechanism; the air inlet comprises a first air inlet 23 communicated with the air blowing channel and a second air inlet 24 communicated with the diversion pipeline; the air pipe connecting port comprises an air blowing port 21 communicated with the air blowing channel and an air suction port 22 communicated with the shunt pipeline.

The blowing channel comprises a first pipeline 27; one end of the first pipeline 27 is communicated with the first air inlet 23, the other end of the first pipeline is communicated with the air blowing port 21, and a ball valve 26 is arranged between the first pipeline 27 and the first air inlet 23. The first regulating valve 71 and the ball valve 26 cooperatively control the blowing air pressure from the end close to the first air inlet 23 and the end close to the blowing port 21 respectively, so that the adjustment of the blowing air pressure is more accurate and reliable.

The flow dividing pipeline comprises a flow divider 25 communicated with the second air inlet 24; the flow divider 25 is provided with a plurality of outlets, and the flow divider 25 is respectively communicated with a plurality of air outlet pipes 251 through the plurality of outlets; a silencer 252 is arranged at one end of the air outlet pipe 251 far away from the flow divider 25; the silencer plays a role in silencing and reducing noise. The mufflers 252 each include a muffling tube, and muffling holes are formed in the muffling tube.

The air suction passage comprises suction pipes 28 which are correspondingly connected with the air outlet pipes 251 one by one; one end of the suction pipe 28 is perpendicular to the air outlet pipe 251, and the other end is communicated with the air suction port 22; a third air pressure gauge 29 is provided between the suction pipe 28 and the suction port 22. The air pressure of the air sucked from the second air source type flight device 62 is cooperatively controlled by the second air pressure gauge 83 and the third air pressure gauge 29.

The suction pipes 28 each include a vertical pipe body 281 connected to the air outlet pipe 251 and a receiving pipe body 282 connected to the suction port 22; the vertical pipe bodies 281 are all perpendicular to the air outlet pipe 251; the supporting tube body 282 is embedded in the vertical tube body 281, sealing devices are arranged at the joints of the vertical tube body 281 and the supporting tube body 282, the vertical tube body 281 and the supporting tube body 282 are detachably connected, and the sealing devices can seal the connection between the vertical tube body 281 and the supporting tube body 282 to avoid air leakage; meanwhile, after the vertical pipe 281 and the receiving pipe 282 are separated, the sealing device is easy to detach and replace.

The sealing devices each include a sealing ring 283 and a sealing sheet 284, the sealing ring 283 is sleeved on the receiving pipe body 282 and is located in the vertical pipe body 281, and the sealing sheet 284 is arranged at the left end of the sealing ring 283 and one end of the sealing sheet 284 is connected with the sealing ring 283. The sealing plate 284 has elasticity; as shown in fig. 4, when the air supply inlet 3 is opened and negative pressure is formed in the suction pipe 28, the sealing sheet 284 is elastically deformed, and the end of the sealing sheet 284 which is not connected with the sealing ring 283 moves towards the receiving pipe 282, so that the suction pipe 28 is opened and air flow is enabled, thereby generating suction effect on the suction pipe 28; when the gas supply inlet 3 stops supplying gas, the sealing plate 284 is elastically deformed and seals the opening of the receiving tube 282, as shown in fig. 3.

The air source type booms 6 comprise a first air source type booms 61 connected with the air blowing openings 21 and a second air source type booms 62 connected with the air suction openings 22.

The adjusting mechanism comprises a blowing adjusting mechanism 7 and a suction adjusting mechanism 8 which are arranged in parallel; the air blowing adjusting mechanism 7 comprises a first adjusting valve 71 and a first electromagnetic valve 72 which are arranged between the air source inlet 3 and the first air inlet 23 and are sequentially connected, the first adjusting valve 71 is connected with a first barometer 73, and the first electromagnetic valve 72 is connected with the first air source type boomerang 61 through a first air flow sensor 74; the first electromagnetic valve 72 is used for controlling the air supply from the air source inlet 3 to the first air inlet 23, and the first regulating valve 71 is used for connecting the air source inlet 3 with the first electromagnetic valve 72 and regulating the air pressure for supplying air from the air source inlet 3 to the first air inlet 23.

The air pressure currently passing through the first regulating valve 71 can be obtained through the first air pressure meter 73; the first electromagnetic valve 72 is provided with a first airflow sensor 74, and the first airflow sensor 74 is connected with the first air source type flight path 61; solenoid valve number one 72 can sense opening and closing of air supply type one boomerang 61 according to air flow sensor number one 74, so that solenoid valve number one 72 can be opened or closed synchronously with air supply type one boomerang 61.

The air suction adjusting mechanism 8 comprises a second adjusting valve 81 and a second electromagnetic valve 82 which are arranged between the air source inlet 3 and the second air inlet 24 and are sequentially connected, a second air pressure gauge 83 is connected to the second adjusting valve 81, and the second electromagnetic valve 82 is connected with the second air source type boomerang 62 through a second air flow sensor 84. The second electromagnetic valve 82 is used for controlling the air supply from the air source inlet 3 to the second air inlet 24, and the second regulating valve 81 is used for connecting the air source inlet 3 with the second electromagnetic valve 82 and regulating the air pressure from the air source inlet 3 to the second air inlet 24.

The current air pressure passing through the second regulating valve 81 can be obtained through the second air pressure gauge 83; the second electromagnetic valve 82 is provided with a second airflow sensor 84, and the second airflow sensor 84 is connected with the second air source type flight path 62; the second solenoid valve 82 can sense the opening and closing of the second air source type flight stop 62 according to the second air flow sensor 84, so that the second solenoid valve 82 can be opened or closed synchronously with the second air source type flight stop 62.

The air volume adjusting knob comprises a first adjusting knob 4 and a second adjusting knob 5; the first adjusting knob 4 and the second adjusting knob 5 are sequentially arranged from front to back along the top surface of the adjuster box body 1; the barometer group comprises a first barometer 73, a second barometer 83 and a third barometer 29 which are sequentially arranged from left to right.

The first adjusting knob 4 is used for adjusting the first adjusting valve 71. When the first air source type flight reach 61 needs to be blown, the air source inlet 3 is opened and the first electromagnetic valve 72 is opened, and at the moment, the air flow supplied from the air source inlet 3 can flow into the first air inlet 23 in a total number; when the first regulating valve 71 is regulated, the air pressure of the air flow supplied from the air source inlet 3 can be regulated, and when the first regulating valve 71 is closed, the air pressure for supplying air to the first air inlet 23 is reduced; when the first regulating valve 71 is opened, the air pressure for supplying air to the first air inlet 23 is increased.

The second adjusting knob 5 is used for adjusting the second adjusting valve 81. When the second air source type flight path 62 needs to be sucked, the air source inlet 3 is opened and the second electromagnetic valve 82 is opened, and at the moment, the air flow supplied from the air source inlet 3 can flow into the second air inlet 24 in a full number; when the second regulating valve 81 is regulated, the air pressure of the air flow supplied from the air source inlet 3 can be regulated, and when the second regulating valve 81 is closed, the air pressure for supplying air to the second air inlet 24 is reduced, and the suction force on the second air source type flight reach 62 is reduced; when the second regulating valve 81 is opened, the air pressure for supplying air to the second air inlet 24 is increased, and the suction force on the second air source type flight device 62 is increased.

When only the vacuum valve 2 is needed to blow air outwards, the second electromagnetic valve 82 is closed, the first electromagnetic valve 72 is opened, and the air blowing pressure is adjusted through the first adjusting valve 71; when only the vacuum valve 2 is required to suck air from the outside, the first electromagnetic valve 72 is closed, the second electromagnetic valve 82 is opened, and the air suction pressure is adjusted through the second adjusting valve 81; when the vacuum valve 2 is required to blow air to the outside and the vacuum valve 2 is required to suck air from the outside, the first electromagnetic valve 72 and the second electromagnetic valve 82 are synchronously opened, the air blowing pressure is adjusted through the first adjusting valve 71, and the air sucking pressure is adjusted through the second adjusting valve 81.

The utility model discloses a concrete work flow does:

the high-pressure gas flow delivered by the high-pressure gas pipe orifice respectively enters a first regulating valve 71 and a second regulating valve 81 through a gas source inlet 3, the first regulating valve 71 and the second regulating valve 81 respectively regulate the pressure through a first regulating knob 4 and a second regulating knob 5, and the pressure can be displayed through a first barometer 73 and a second barometer 83 which are connected with the first regulating valve 71 and the second regulating valve 81. The regulated air pressure is connected with a first electromagnetic valve 72 (air blowing electromagnetic valve) and a second electromagnetic valve 82 (air suction electromagnetic valve), the first electromagnetic valve 72 and the second electromagnetic valve 82 are respectively connected with a first air flow sensor 74 and a second air flow sensor 84, and the first air flow sensor 74 and the second air flow sensor 84 are respectively connected with a first air source type flight motor 61 and a second air source type flight motor 62.

When the first air source type flight 61 and the second air source type flight 62 are started, the first electromagnetic valve 72 and the second electromagnetic valve 82 are opened simultaneously, and high-pressure air flow conveyed by the high-pressure air pipe port enters the vacuum valve 2 through the first air inlet 23 and the second air inlet 24 after being adjusted by the first adjusting valve 71 and the second adjusting valve 81 respectively; after high-pressure gas flow is input into the vacuum valve 2 through the first gas inlet 23, blowing gas flow is output under the action of the vacuum valve 2, and the blowing gas flow is connected with the blowing port 21 and is conveyed to the first gas source type flight path 61; wherein high-pressure gas flows and produces a vacuum pumping process in the vacuum valve under vacuum valve 2's effect after inputting vacuum valve 2 through No. two air inlets 24 for form a negative pressure space in the vacuum valve, the negative pressure space is connected with induction port 22, forms the effect of breathing in and carries No. two air supply formulas and flies to reach 62, makes the utility model discloses possess the effect of blowing simultaneously and breathe in the effect.

If the air flow of the air blowing opening 21 and the air suction opening 22 needs to be adjusted, the first adjusting valve 71 and the second adjusting valve 81 can be controlled by the first adjusting knob 4 and the second adjusting knob 5 to adjust the air inlet pressure, and the larger the air inlet pressure is, the larger the air flow of the air blowing opening 21 and the air suction opening 22 is. When the air source type flight 6 stops operating, the first solenoid valve 72 and the second solenoid valve 82 are simultaneously closed, and no air pressure is input to the vacuum valve 2, so that no air flow is generated in the air blowing port 21 and the air suction port 22.

The utility model discloses can realize blowing and breathing in simultaneously through connecting high-pressurepipe, can guarantee the normal operation demand of equipment, and have the effect of energy-conservation and noise reduction. The power of the traditional motor type carbon sheet air pump is 4000-; traditional motor air pump is driven by the motor, the sound of during operation motor is great, can reach more than 80-90 decibels, and the utility model discloses only gas flow, do not have the motor operation, set up the gas muffler in addition, so bigger noise that has reduced, do not also produce heat energy simultaneously, intelligence air pump regulator long-time continuous operation can not cause the air pump trouble, the stability can be better, can not produce waste gas and the difficult loss of spare part, traditional motor air pump who avoids using among the prior art can wear and tear the carbon piece and produce heat energy when the operation, avoid producing adverse effect to staff's health and operational environment, can practice thrift the cost and improve workshop operational environment for a large amount of industrial production enterprises.

The above embodiments are not intended to limit the present invention, and the present invention is not limited to the above examples, and the technical personnel in the technical field are in the present invention, which can also belong to the protection scope of the present invention.

Claims (10)

1. The utility model provides an intelligence air pump regulator, includes regulator box (1), its characterized in that: the air conditioner is characterized in that the conditioner box body (1) is a cuboid, an air source inlet (3) is arranged in the middle of the left side face of the conditioner box body, an air pipe connecting port is correspondingly arranged on the right side face of the conditioner box body, an air volume adjusting knob is arranged on the top face of the conditioner box body, an air pressure gauge set is arranged on the front side face of the conditioner box body, a switch (11) is arranged above the air source inlet (3), a power supply connecting port (12) is arranged below the air source inlet; a vacuum valve (2) is arranged in the regulator box body (1);

one end of the vacuum valve (2) is provided with an air inlet, the other end of the vacuum valve is provided with an air pipe connector, one end of the vacuum valve (2) is communicated with the air source inlet (3) through the air inlet, and the other end of the vacuum valve is connected with the air source type feeder (6) through the air pipe connector; an adjusting mechanism is arranged between the vacuum valve (2) and the air source inlet (3), and the vacuum valve (2) is communicated with the air source inlet (3) through the adjusting mechanism; an air blowing channel and a shunt pipeline are arranged in the vacuum valve (2) in parallel, one end of the air blowing channel and one end of the shunt pipeline are communicated with an air inlet, the other end of the air blowing channel and the other end of the shunt pipeline are communicated with an air pipe connecting port, the shunt pipeline is communicated with the air pipe connecting port through an air suction channel, and an air outlet pipe (251) of the shunt pipeline is perpendicular to the air suction channel.

2. The intelligent air pump regulator of claim 1, wherein: the air inlet of the vacuum valve (2) is communicated with the adjusting mechanism; the air inlet comprises a first air inlet (23) communicated with the air blowing channel and a second air inlet (24) communicated with the diversion pipeline; the air pipe connecting port comprises an air blowing port (21) communicated with the air blowing channel and an air suction port (22) communicated with the shunt pipeline.

3. The intelligent air pump regulator of claim 2, wherein: the blowing channel comprises a first pipeline (27); one end of the first pipeline (27) is communicated with the first air inlet (23), the other end of the first pipeline is communicated with the air blowing opening (21), and a ball valve (26) is arranged between the first pipeline (27) and the first air inlet (23).

4. The intelligent air pump regulator of claim 3, wherein: the flow dividing pipeline comprises a flow divider (25) communicated with a second air inlet (24); the flow divider (25) is provided with a plurality of outlets, and the flow divider (25) is respectively communicated with a plurality of air outlet pipes (251) through the outlets; a silencer (252) is arranged at one end of the air outlet pipe (251) far away from the flow divider (25); the silencers (252) all comprise a silencing pipe, and silencing holes are formed in the silencing pipe.

5. The intelligent air pump regulator of claim 4, wherein: the air suction channel comprises suction pipes (28) which are correspondingly connected with the air outlet pipes (251) one by one; one end of the suction pipe (28) is vertical to the air outlet pipe (251) and the other end is communicated with the air suction port (22); a third barometer (29) is arranged between the suction pipe (28) and the air suction port (22).

6. The intelligent air pump regulator of claim 5, wherein: the suction pipes (28) respectively comprise a vertical pipe body (281) connected with the air outlet pipe (251) and a bearing pipe body (282) connected with the air suction port (22); the vertical pipe bodies (281) are all perpendicular to the air outlet pipe (251); all having set up in vertical body (281) and accepting body (282), vertical body (281) all are provided with sealing device with the junction of accepting body (282), and sealing device all includes sealing ring (283), gasket (284), and sealing ring (283) all cup joints and is just located vertical body (281) on accepting body (282), and gasket (284) set up in the left end of sealing ring (283) and the one end of gasket (284) is connected with sealing ring (283).

7. The intelligent air pump regulator of claim 6, wherein: the air source type boomerangs (6) comprise a first air source type boomerang (61) connected with the air blowing opening (21) and a second air source type boomerang (62) connected with the air suction opening (22).

8. The intelligent air pump regulator of claim 7, wherein: the adjusting mechanism comprises a blowing adjusting mechanism (7) and a suction adjusting mechanism (8) which are arranged in parallel; the air blowing adjusting mechanism (7) comprises a first adjusting valve (71) and a first electromagnetic valve (72) which are arranged between the air source inlet (3) and the first air inlet (23) and are sequentially connected, a first barometer (73) is connected to the first adjusting valve (71), and the first electromagnetic valve (72) is connected with the first air source type boomerang (61) through a first air flow sensor (74);

inhale adjustment mechanism (8) including set up No. two governing valves (81), No. two solenoid valves (82) that set up between air supply entry (3) and No. two air inlets (24) and connect gradually, be connected with No. two barometers (83) on No. two governing valves (81), No. two solenoid valves (82) are connected with No. two air supply formula flies to reach (62) through No. two air flow sensor (84).

9. The intelligent air pump regulator of claim 8, wherein: the air volume adjusting knob comprises a first adjusting knob (4) and a second adjusting knob (5); the first adjusting knob (4) and the second adjusting knob (5) are sequentially arranged from front to back along the top surface of the adjuster box body (1); the barometer group comprises a first barometer (73), a second barometer (83) and a third barometer (29) which are sequentially arranged from left to right.

10. The intelligent air pump regulator of any one of claims 1-9, wherein: the gas source inlet (3) is communicated with the high-pressure gas pipe port; the vacuum valve (2) is connected with the high-pressure air pipe port through the air source inlet (3).

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