CN221580194U - Novel high-pressure air source treatment device - Google Patents

Abstract

The application relates to the field of gas filtration, in particular to a novel high-pressure gas source treatment device, which comprises a shell, wherein a drying cavity is formed in the shell, an air inlet hole for allowing gas to enter the drying cavity and an air outlet hole for allowing the gas to exit the drying cavity are formed in the shell, the air inlet hole is obliquely formed so that the gas entering the air inlet hole rotates to form vortex so as to separate oil from the gas, and a through hole for draining water is formed in the shell. The application has the effect of improving the filtering efficiency of the high-pressure gas.

Description

Novel high-pressure air source treatment device

Technical Field

The application relates to the field of gas filtration, in particular to a novel high-pressure gas source treatment device.

Background

The high-low pressure gas used in daily life is produced by compressed natural air of a compressor, and in pipeline interlinking conveying, water condensation can be produced due to temperature difference and high-speed gas flow transmission, so that a large amount of condensed water is produced in the pipeline, meanwhile, in normal use, lubricating grease for reducing mechanical friction exists in accessories such as a gas pipeline cylinder and the like, and the water can cause grease deterioration to cause equipment and spare parts to damage, and meanwhile, oil is driven to be conveyed in the pipeline to further pollute the gas.

The common triple piece filtering device utilizes gravity and a filter element mode to adsorb oil and water in a pipeline, the filter element is easy to be saturated and replaced troublesome when in large-flow use, and the filter element is easy to damage under high-pressure impact when the conveyed gas is conveyed at high pressure, so that the filter element cannot be used. The common triplet is difficult to separate oil from water in the compressed air in the gas conveying pipeline, and only the low-pressure gas source can be treated.

Disclosure of utility model

In order to solve the problem that a common triplet can only treat a low-pressure air source, the application provides a novel high-pressure air source treatment device.

The application provides a novel high-pressure air source treatment device, which adopts the following technical scheme:

The utility model provides a novel high-pressure air source treatment device, includes the shell, be formed with the dry chamber in the shell, offer on the shell and be used for the gas to get into the inlet port in dry chamber and be used for the gas to discharge the venthole in dry chamber, the inlet port is the slope and offers, so that the gas rotation that the inlet port got into realizes oil water and separates from gas in order to form the vortex, still be formed with the through-hole that is used for the drainage on the shell.

By adopting the technical scheme, the compressed gas output by the high-pressure gas source is reduced to be low-pressure gas and then filtered by the filter element for adsorption of the oil water, the oil-water separation in the gas is carried out by the centripetal force of the gas, and the gas pressure is taken as power during gas transmission to form high-speed vortex water-gas separation so as to realize the dryness and cleanliness of the gas, the filter element is not required to be used for adsorption, the influence of the filter element on the oil-water filtration efficiency is reduced, the impact damage probability of the filter element by the high-pressure gas is reduced, the high-pressure gas is filtered, the probability of additional loss generated when the high-pressure gas is reduced to be low-pressure gas and then filtered is reduced, meanwhile, the direct conveying speed of the high-pressure gas is far greater than the conveying speed of the low-pressure gas, the conveying efficiency of the gas is greatly improved, no electronic fittings, power supplies and controllers are additionally arranged, the oil-water separation is realized by a pure mechanical structure, and the purposes of energy consumption and energy conservation and emission reduction are greatly realized.

Optionally, be provided with the air drying subassembly in the shell, the air drying subassembly includes the desicator, be formed with the air cavity in the desicator, the inlet port with the air cavity is linked together, run through on the desicator inner wall set up be used for with the guiding hole of dry cavity intercommunication, the guiding hole be used for with rotatory the throwing away of gas in the air cavity extremely in the dry cavity is in order to form the vortex, realizes that the profit separates out from gas, the venthole is seted up outside in the air cavity on the dry cavity inner wall.

Through adopting above-mentioned technical scheme, realize leading the gaseous that will get into through the guiding hole of desicator to make gaseous rotatory formation vortex, realize gaseous self-driven formation vortex through mechanical structure, and need not to add the air pump and produce the vortex, convenient and fast, and the cost is reduced, has made conveniently, has practiced thrift the energy.

Optionally, the inner wall of the drying cavity and the inner wall of the air cavity are cambered surfaces, a guide air inlet hole for communicating with the air inlet hole is formed in the dryer in a penetrating manner, the guide air inlet hole is formed in an inclined manner, the opening of the guide air inlet hole is formed in an inclined manner along the cambered surface angle of the inner wall of the air cavity, and the opening of the guide hole is formed in an inclined manner along the cambered surface angle of the inner wall of the drying cavity.

Through adopting above-mentioned technical scheme, through being the air cavity inner wall and the dry cavity inner wall of cambered surface, further promoted the rotation of gas, improved the efficiency that forms the vortex.

Optionally, the inlet port includes inlet cone hole and first air bleed hole, and gas is followed inlet cone hole's opening gets into, inlet cone hole sets up the bottom inner wall of direction and is concave toper in order to guide gas buffering speed reduction, first air bleed Kong Kaishe is in on the inner wall of inlet cone hole sets up the direction side, first air bleed hole with the direction inlet port intercommunication.

Through adopting above-mentioned technical scheme, through the diapire of admitting air taper hole come to carry out the deceleration buffering to the gas of entering, and indent conical diapire guide gas deceleration back with just entering gas produce the hedging, improved the deceleration efficiency, also reduced the impact of gas to the taper hole inner wall of admitting air, then the gas after the deceleration gets into first gas vent through the extrusion, the probability of gas impact dryer has been reduced, the guard action has been played to the dryer, and get into through the extrusion, still have certain speed when having guaranteed again to get into the dryer, the follow-up vortex wind tunnel that forms of having made things convenient for.

Optionally, the direction inlet port includes speed reduction ring chamber, second gas vent and direction gas vent, first gas vent with speed reduction ring chamber intercommunication, just first gas vent opening surface orientation speed reduction ring chamber inner wall, the direction gas vent with the air cavity intercommunication, the direction gas vent opening is followed the cambered surface angle slope of air cavity inner wall is seted up, makes the angle of direction gas vent opening exhaust gas with the inclination adaptation of air cavity inner wall, the second gas vent intercommunication is in speed reduction ring chamber with between the direction gas vent.

Through adopting above-mentioned technical scheme, the gas that gets into the speed reduction ring chamber will produce the flow direction of two directions, and the flow direction of two directions is towards after half circles in the speed reduction ring chamber, further played the effect of slowing down, and at the speed reduction ring intracavity gas through extrudeing then squeeze into the second bleed hole and get into the direction gas pocket, the direction of gas that gets into the air cavity has been guided through the direction gas pocket that inclines for the gas direction is tangent with the air cavity inner wall, realized that the gas gets into can rotate along the direction of air cavity inner wall cambered surface, reduced the gas that gets into the air cavity and impacted the air cavity inner wall, the probability that causes the damage to the desicator, when having made things convenient for vortex formation, played the guard action to the desicator.

Optionally, the air drying assembly further comprises an oil-water separation accessory, the through hole is formed in the oil-water separation accessory in a penetrating manner, the oil-water separation accessory is provided with a concave conical surface, the concave conical surface is inclined towards the concave of the opening surface of the through hole, the concave conical surface is used for promoting vortex flow formed by gas to further form a wind tunnel, and separated oil-water is guided to enter the through hole along self gravity.

Through adopting above-mentioned technical scheme, collect the profit that separates through the indent cone of oil water separation accessory, still assist the formation of vortex wind-tunnel simultaneously, through the guide of inclined plane, the gas that gets into the dry chamber rotation from the air cavity can be better rotatory with star constant vortex wind-tunnel, improves oil water separation's efficiency.

Optionally, still be provided with the drainer on the shell, be formed with in the drainer with the drainage chamber of through-hole intercommunication, be provided with the valve body in the drainage chamber, set up the siphon hole that is used for the drainage on the valve body, it has the floater to float in the drainage chamber, be provided with on the floater and be used for with the blocking post of siphon hole opening shutoff.

Through adopting above-mentioned technical scheme, after the oil water separates from gaseous and gets into the drainer through the through-hole, every time the oil water accumulates to certain height, when the buoyancy that produces enough makes the floater float, the siphon hole is opened and will produce the siphonage and come the oil water discharge in the drainage chamber, when the liquid level in the drainage chamber descends to unable the sucking, the floater whereabouts again will siphon hole shutoff to this circulation, need not motor, treater and power, through mechanical structure, can realize the automatic discharge to the oil water, reduce cost, the energy saving.

Optionally, a funnel cover is disposed on the housing, and the funnel cover is configured to concentrate oil water passing through the through hole, and output the concentrated oil water to the drainer.

Through adopting above-mentioned technical scheme, collect the oil water that the through-hole passed through the funnel lid and get into the drainer, convenient and fast.

Optionally, the method further comprises:

The high-low pressure automatic pressure regulating module is used for regulating the air pressure of the air so as to form a stable high-low pressure air source as output.

By adopting the technical scheme, stable high-pressure air source output or low-pressure air source output is formed through the control of the high-pressure and low-pressure automatic pressure regulating module, and the stability of air source output is improved.

Optionally, the method further comprises:

The digital pressure gauge is arranged at the air outlet end of the high-low pressure automatic pressure regulating module, and is used for detecting the air pressure of the air output by the air outlet end of the high-low pressure automatic pressure regulating module and outputting a corresponding detection signal;

the processing module is used for receiving the detection signal, comparing the detection signal with a preset air pressure threshold value and outputting a corresponding control signal;

and the control module is used for receiving the control signal and correspondingly regulating and controlling the high-low pressure automatic pressure regulating module so as to keep the gas pressure output by the high-low pressure automatic pressure regulating module within the range of the corresponding gas pressure threshold.

By adopting the technical scheme, the detection is carried out through the digital pressure gauge, the processing module and the control module are used for correspondingly controlling the high-low pressure automatic pressure regulating module, namely when the output air pressure of the high-low pressure automatic pressure regulating module is detected to be reduced, the processing module judges that the output is too low when processing the detection signal, and then the control module is controlled to improve the output of the high-low pressure automatic pressure regulating module; or when the increase of the output air pressure of the high-low pressure automatic pressure regulating module is detected, the processing module judges that the output is too high when processing the detection signal, and then controls the control module to reduce the output of the high-low pressure automatic pressure regulating module; the automatic feedback control of the output of the high-low pressure automatic pressure regulating module is realized, and the stability of the output gas of the high-low pressure automatic pressure regulating module is further improved.

In summary, the present application includes at least one of the following beneficial technical effects:

1. The probability of the high-pressure gas impacting and damaging the filter element is reduced, the high-pressure gas is filtered, the probability of extra loss generated when the high-pressure gas is depressurized into low-pressure gas and then filtered is reduced, meanwhile, the speed of direct conveying of the high-pressure gas is far greater than the conveying speed of the low-pressure gas, and the conveying efficiency of the gas is greatly improved.

2. The oil-water separation is realized through a pure mechanical structure without adding an electronic accessory, a power supply and a controller, so that the energy loss is greatly reduced, and the purposes of energy conservation and emission reduction are realized.

3. The stability of the output of the air source is improved.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a novel high-pressure air source treatment device in an embodiment of the application.

Fig. 2 is a schematic view showing the structure of the drying chamber.

Fig. 3 is an enlarged schematic view of the structure at a in fig. 2.

Fig. 4 is a schematic view showing the structure of a dryer with the second air introduction hole highlighted.

Fig. 5 is an enlarged schematic view of the structure at B in fig. 2.

FIG. 6 is a schematic view showing the structure of the connecting rod and the blocking column.

FIG. 7 is a schematic block diagram of a novel high pressure gas source processing apparatus in accordance with an embodiment of the present application.

Reference numerals illustrate: 1. a housing; 11. a drying chamber; 12. an air inlet hole; 121. an air inlet taper hole; 122. a first air vent; 13. an air outlet hole; 14. a through hole; 2. an air drying assembly; 21. a dryer; 22. an air cavity; 23. a guide hole; 24. guiding the air inlet hole; 241. a speed reducing ring cavity; 242. a second air vent; 243. a guide air hole; 25. an oil-water separation accessory; 26. a concave conical surface; 3. a drain; 31. a drainage cavity; 32. a valve body; 321. a siphon hole; 322. a blocking groove; 323. a floating slot; 33. a floating ball; 331. a connecting rod; 34. a blocking column; 35. a funnel cover; 4. the high-low pressure automatic pressure regulating module; 41. a digital pressure gauge; 42. a processing module; 43. and a control module.

Detailed Description

The application is described in further detail below with reference to fig. 1-7.

The embodiment of the application discloses a novel high-pressure air source treatment device. Referring to fig. 1 and 2, in this embodiment, the direction of the gravity direction is downward, and the direction opposite to the downward direction is upward, the novel high-pressure air source treatment device comprises a housing 1, a drying cavity 11 is formed in the housing 1, an air inlet hole 12 for allowing air to enter the drying cavity 11 and an air outlet hole 13 for allowing air to exit the drying cavity 11 are formed in the housing 1, the air inlet hole 12 and the air outlet hole 13 are all communicated with the inner wall of the upper end of the drying cavity 11 from the side wall of the housing 1 close to the upper end in a penetrating manner, the air inlet hole 12 is obliquely formed, so that air entering the air inlet hole 12 rotates to form vortex so as to separate oil from the air, and a through hole 14 for draining water is formed in the housing 1.

Referring to fig. 2 and 3, an air drying assembly 2 is installed in a housing 1, the air drying assembly 2 includes a dryer 21, the dryer 21 is fixedly connected to an inner wall of an upper end of a drying cavity 11, a diameter of the dryer 21 is smaller than a cross-section diameter of the drying cavity 11, a space for air circulation exists between an outer ring side wall of the dryer 21 and the inner wall of the drying cavity 11, and an opening direction of the drying cavity 11 and a length direction of the dryer 21 extend along a gravity direction. The dryer 21 is internally provided with an air cavity 22, the air cavity 22 is also formed along the gravity direction, the air inlet 12 is communicated with the air cavity 22, the air inlet 12 is communicated on the peripheral inner wall of the air cavity 22 in the opening direction, at least two guide holes 23 used for being communicated with the drying cavity 11 are formed in the inner wall of the dryer 21 in a penetrating manner, the guide holes 23 are communicated on the peripheral inner wall of the air cavity 22 in the opening direction, the guide holes 23 are uniformly distributed circumferentially, the guide holes 23 are uniformly distributed on the horizontal position, the guide holes 23 are used for rotating and throwing out the gas in the air cavity 22 into the drying cavity 11 to form vortex flow so as to separate oil from the gas, and the air outlet 13 is formed on the inner wall of the drying cavity 11 outside the air cavity 22.

Referring to fig. 2 and 3, the drying chamber 11 and the air chamber 22 are both cylindrical, that is, the inner wall of the drying chamber 11 and the inner wall of the air chamber 22 are both cylindrical, the dryer 21 is provided with a guide air inlet 24 in a penetrating manner, one end of the guide air inlet 24 is communicated with the air inlet 12, and the other end of the guide air inlet 24 is communicated with the air chamber 22.

Referring to fig. 3, the air intake hole 12 includes an air intake taper hole 121 and a first air intake hole 122, the air intake taper hole 121 is opened along a horizontal direction, the air intake taper hole 121 is entirely cylindrical, air enters from the air intake taper hole 121 toward an opening outside the housing 1, the bottom end inner wall of the air intake taper hole 121 penetrating into the housing 1 is concave tapered to guide the air to buffer and slow down, that is, the bottom end inner wall of the air intake taper hole 121 is inclined and recessed along a direction approaching to a central position of the air intake taper hole 121 and further away from an opening surface of the air intake taper hole 121, the first air intake hole 122 is opened on an inner wall of a side edge of the opening direction of the air intake taper hole 121, the opening direction of the first air intake hole 122 is perpendicular to the opening direction of the air intake taper hole 121, and the first air intake hole 122 is communicated with the guide air intake hole 24.

Referring to fig. 3 and 4, the guide air inlet 24 includes a deceleration ring cavity 241, a second air introducing hole 242 and a guide air hole 243, the deceleration ring cavity 241 is formed on the upper end surface of the dryer 21, the upper end surface of the dryer 21 and the inner wall of the upper end of the drying cavity 11 enclose to form a deceleration ring cavity 241, the deceleration ring cavity 241 is formed by extending in a horizontal direction, the deceleration ring cavity 241 is formed by extending in a ring shape, the first air introducing hole 122 extends from top to bottom to the inner wall of the upper end of the deceleration ring cavity 241, the first air introducing hole 122 is communicated with the deceleration ring cavity 241, and the extending direction of the first air introducing hole 122 is perpendicular to the extending direction of the deceleration ring cavity 241, i.e. the opening surface of the first air introducing hole 122 faces the inner wall of the deceleration ring cavity 241 vertically.

Referring to fig. 3 and 4, the air guiding hole 243 is communicated with the air cavity 22, the opening of the air guiding hole 243 is obliquely opened along the arc surface angle of the inner wall of the air cavity 22, namely, the extending opening direction of the air guiding hole 243 is tangential to the inner wall of the air cavity 22, namely, the inner wall of the air guiding hole 243 is connected with the inner wall of the air cavity 22 along the tangential direction, so that the angle of the air discharged by the opening of the air guiding hole 243 is the same as the inclination angle of the inner wall of the air cavity 22, the extending direction of the air guiding hole 243 extends horizontally, one end of the second air guiding hole 242 is communicated with the inner wall of the lower end of the speed reducing ring cavity 241, the other end of the second air guiding hole 242 is communicated in the air guiding hole 243 from top to bottom along the vertical direction, and the opening of the second air guiding hole 242 is staggered with the opening of the first air guiding hole 122.

Referring to fig. 2, the air drying assembly 2 further includes an oil-water separation fitting 25, wherein the oil-water separation fitting 25 is located in the drying cavity 11 and below the dryer 21, the oil-water separation fitting 25 is fixedly connected to the inner wall of the drying cavity 11, and the through hole 14 is vertically and vertically formed in a central position of the oil-water separation fitting 25. The oil-water separation accessory 25 is provided with a concave conical surface 26 on the upper end surface, the concave conical surface 26 inclines in a downward direction along the direction closer to the opening surface of the through hole 14, namely, the concave conical surface 26 inclines inwards towards the opening surface of the through hole 14, the concave conical surface 26 is used for promoting vortex formed by gas to further form a wind tunnel, and the separated oil-water is guided to enter the through hole 14 along the self gravity.

Referring to fig. 1 and 2, the drain 3 is fixedly connected to the housing 1, the upper end of the drain 3 is connected to the lower end of the housing 1, the lower end of the housing 1 is fixedly connected with the funnel cover 35, the upper end surface of the funnel cover 35 in the drying chamber 11 is inclined, the water outlet hole of the funnel cover 35 is positioned at the center, the inclined funnel cover 35 is inclined downwards along the position closer to the water outlet hole opening, and the funnel cover 35 is used for concentrating oil water passing through the through hole 14 and outputting the oil water to the upper end of the drain 3 to enter the drain 3.

Referring to fig. 2 and 5, a drain chamber 31 communicating with the through hole 14 is formed in the drain 3, a valve body 32 is fixedly connected to an inner wall of a lower end of the drain chamber 31, a length direction of the valve body 32 extends from a lower to an upper direction, a blocking groove 322 is formed in an upper end surface of the valve body 32, the blocking groove 322 extends downward, a siphon hole 321 for draining water is formed in a bottom wall of the blocking groove 322 facing an opening surface of the blocking groove, and the siphon hole 321 extends from the upper to the lower direction along a gravity direction and penetrates through the valve body 32 to the outside.

Referring to fig. 5 and 6, a floating ball 33 is floating up and down in the drainage cavity 31, the floating ball 33 is annular and circumferentially surrounds the outer ring of the valve body 32, a connecting rod 331 is fixedly connected to the upper end surface of the floating ball 33 in a clamped manner, a floating slot hole 323 is further formed in the inner wall of the blocking groove 322, the floating slot hole 323 penetrates through the side wall of the valve body 32 to the side wall of the length direction of the valve body 32, and the penetrating direction of the floating slot hole 323 is perpendicular to the opening direction of the blocking groove 322. The end of the connecting rod 331 extends into the blocking groove 322 through the floating groove hole 323, the connecting rod 331 moves up and down in the floating groove hole 323 along with the floating of the floating ball 33, the end of the connecting rod 331 in the blocking groove 322 is fixedly connected with a blocking column 34 in a clamping and connecting mode, the blocking column 34 slides up and down in the blocking groove 322, the blocking column 34 is used for blocking an opening of the siphon hole 321, and a sealing ring is fixedly connected to the side wall of the blocking column 34, facing the opening surface of the siphon hole 321, so that the opening surface of the siphon hole 321 is circumferentially sealed in a surrounding mode.

Referring to fig. 5, a certain space exists between the inner side wall of the float ball 33 and the outer side wall of the valve body 32 for oil and water to be pumped out.

The fixed connection in this embodiment may be a metal rivet, interference fit, or a threaded connection.

Referring to fig. 7, the automatic pressure regulating device further comprises a high-low pressure automatic pressure regulating module 4, a digital pressure gauge 41, a processing module 42 and a control module 43, wherein an air inlet end of the automatic pressure regulating module 4 is communicated with the air outlet hole 13, the automatic pressure regulating module 4 is used for regulating air pressure of air to form a stable high-low pressure air source, and in the embodiment, the automatic pressure regulating module 4 adopts a precise pressure regulating valve 102A4J of the american faerie.

Referring to fig. 7, a digital pressure gauge 41 is installed at the air outlet end of the high-low pressure automatic pressure regulating module 4, and is used for detecting the air pressure of the air output by the air outlet end of the high-low pressure automatic pressure regulating module 4 and outputting a corresponding detection signal. The processing module 42 is configured to receive the detection signal, compare the detection signal with a preset air pressure threshold, and output a corresponding control signal after the comparison is completed, where the air pressure threshold is the air pressure preset by the worker and output by the automatic high-low pressure regulating module 4. The control module 43 is configured to receive the control signal and perform corresponding adjustment control on the high-low pressure automatic pressure adjustment module 4, so that the gas pressure output by the high-low pressure automatic pressure adjustment module 4 is kept within a range of a corresponding gas pressure threshold. A database may be included that ultimately stores the barometric pressure threshold and stores the operating status of the processing module 42 and digital pressure gauge 41 in a log for convenient personnel invocation.

The processing module 42 may include a central processing unit such as a CPU or an MPU, or a host system including hardware or software, which is built with the CPU or the MPU as a core. With the meter having a processing module 42, one can freely control the meter by programming to operate as one wishes. The processing module 42 may control local metering, remote communication components, etc. via internal protocols. Internal protocols broadly refer to all protocols within the same meter or within the same system that enable mutual communication or linking, including: human-machine interaction protocol, software/hardware (interface) protocol, chip Bus (C-Bus) protocol, internal Bus (I-Bus) protocol, etc. With the development of integrated circuit technology, some protocols belonging to external buses (E-Bus) are also attributed to internal protocols after the external buses (E-Bus) are integrated into a chip.

The implementation principle of the novel high-pressure air source treatment device provided by the embodiment of the application is as follows: high-pressure gas enters from the air inlet taper hole 121, then enters the speed reducing annular cavity 241 through the first air guiding hole 122, then enters the guide air hole 243 through the second air guiding hole 242, enters the air cavity 22 through the guide of the guide air hole 243, and enters the guide hole 23 along the inner cambered surface of the air cavity 22 in a rotating way, enters the drying cavity 11 through the guide rotation of the guide hole 23, forms vortex through the inner cambered surface of the drying cavity 11, and forms a wind tunnel by being matched with the concave conical surface 26 of the oil-water separation accessory 25, at the moment, the gas density is slightly increased and is discharged from the air outlet hole 13, and oil and water are thrown out from the gas and are discharged from the through hole 14 to the drainer 3 along the inner cambered surface of the drying cavity 11 and the concave conical surface 26;

Along with the rising of the water level in the drainage cavity 31, the buoyancy force received by the floating ball 33 is larger and larger until the floating ball 33 floats upwards, the blocking column 34 is driven to float upwards by the connecting rod 331, at the moment, the blocking column 34 moves away from the opening of the siphon hole 321, and the siphon hole 321 is opened to siphon oil and water in the drainage cavity 31 to drain.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (10)

1. The utility model provides a novel high-pressure air source handles device which characterized in that: including shell (1), be formed with dry chamber (11) in shell (1), offer on shell (1) be used for the gas to get into inlet port (12) of dry chamber (11) and be used for the gas to discharge venthole (13) of dry chamber (11), inlet port (12) are the slope and offer, so that the gas rotation that inlet port (12) got into realizes oil water separation in the gas with forming the vortex, still be formed with through-hole (14) that are used for the drainage on shell (1).

2. The novel high-pressure air source treatment device according to claim 1, wherein: be provided with air drying component (2) in shell (1), air drying component (2) include desicator (21), be formed with air cavity (22) in desicator (21), inlet port (12) with air cavity (22) are linked together, run through on desicator (21) inner wall set up be used for with guiding hole (23) of dry cavity (11) intercommunication, guiding hole (23) are used for with rotatory throwing away of gas in air cavity (22) extremely in dry cavity (11) in order to form the vortex, realize that the profit separates out from gas, venthole (13) are seted up on the outside dry cavity (11) inner wall of air cavity (22).

3. A novel high pressure gas source processing apparatus according to claim 2, wherein: the inner wall of the drying cavity (11) and the inner wall of the air cavity (22) are cambered surfaces, a guide air inlet hole (24) communicated with the air inlet hole (12) is formed in the dryer (21) in a penetrating mode, the guide air inlet hole (24) is formed in an inclined mode, an opening of the guide air inlet hole (24) is formed in an inclined mode along the cambered surface angle of the inner wall of the air cavity (22), and an opening of the guide hole (23) is formed in an inclined mode along the cambered surface angle of the inner wall of the drying cavity (11).

4. A novel high pressure gas source processing apparatus according to claim 3, wherein: the air inlet hole (12) comprises an air inlet taper hole (121) and a first air introducing hole (122), air enters from an opening of the air inlet taper hole (121), the inner wall of the bottom end of the air inlet taper hole (121) in the direction is in a concave taper shape to guide air to buffer and reduce speed, the first air introducing hole (122) is formed in the inner wall of the side edge of the air inlet taper hole (121) in the direction, and the first air introducing hole (122) is communicated with the guide air inlet hole (24).

5. The novel high-pressure air source treatment device according to claim 4, wherein: the guide air inlet hole (24) comprises a speed reduction annular cavity (241), a second air guide hole (242) and a guide air hole (243), the first air guide hole (122) is communicated with the speed reduction annular cavity (241), the opening surface of the first air guide hole (122) faces the inner wall of the speed reduction annular cavity (241), the guide air hole (243) is communicated with the air cavity (22), the opening of the guide air hole (243) is obliquely formed along the cambered surface angle of the inner wall of the air cavity (22), the angle of air discharged by the opening of the guide air hole (243) is matched with the inclination angle of the inner wall of the air cavity (22), and the second air guide hole (242) is communicated between the speed reduction annular cavity (241) and the guide air hole (243).

6. A novel high pressure gas source processing apparatus according to claim 2, wherein: the air drying assembly (2) further comprises an oil-water separation accessory (25), the through hole (14) is formed in the oil-water separation accessory (25) in a penetrating mode, an inward concave conical surface (26) is formed in the oil-water separation accessory (25), the inward concave conical surface (26) faces towards the opening surface of the through hole (14) and is inclined inwards, the inward concave conical surface (26) is used for promoting vortex of gas formation to further form a wind tunnel, and separated oil-water is guided to enter the through hole (14) along self gravity.

7. The novel high-pressure air source treatment device according to claim 1, wherein: still be provided with drainer (3) on shell (1), be formed with in drainer (3) with drainage chamber (31) of through-hole (14) intercommunication, be provided with valve body (32) in drainage chamber (31), set up siphon hole (321) that are used for the drainage on valve body (32), it has floater (33) to float in drainage chamber (31), be provided with on floater (33) and be used for with stopper post (34) of siphon hole (321) opening shutoff.

8. The novel high-pressure air source treatment device according to claim 7, wherein: the shell (1) is provided with a funnel cover (35), and the funnel cover (35) is used for concentrating oil water passing through the through holes (14) and outputting the concentrated oil water to the drainer (3).

9. The novel high pressure gas source processing device of claim 1, further comprising:

The high-low pressure automatic pressure regulating module (4), the inlet end of high-low pressure automatic pressure regulating module (4) with venthole (13) intercommunication, high-low pressure automatic pressure regulating module (4) are used for adjusting the atmospheric pressure of output gas to form stable high-low pressure gas source and as output.

10. The novel high pressure gas source processing device of claim 9, further comprising:

the digital pressure gauge (41) is arranged at the air outlet end of the high-low pressure automatic pressure regulating module (4) and is used for detecting the air pressure of the air output by the air outlet end of the high-low pressure automatic pressure regulating module (4) and outputting a corresponding detection signal;

the processing module (42) is used for receiving the detection signal, comparing the detection signal with a preset air pressure threshold value and outputting a corresponding control signal;

And the control module (43) is used for receiving the control signal and correspondingly regulating and controlling the high-low pressure automatic pressure regulating module (4) so as to keep the gas pressure output by the high-low pressure automatic pressure regulating module (4) within the range of the corresponding gas pressure threshold.