CN113230776A

CN113230776A - Air intake system of intelligent hypoxia generating device

Info

Publication number: CN113230776A
Application number: CN202110541877.1A
Authority: CN
Inventors: 徐玮; 张�荣; 钱昌伟
Original assignee: HEFEI HENGCHENG INTELLIGENT TECHNOLOGY CO LTD
Current assignee: HEFEI HENGCHENG INTELLIGENT TECHNOLOGY CO LTD
Priority date: 2021-05-18
Filing date: 2021-05-18
Publication date: 2021-08-10

Abstract

The invention discloses an air inlet system of an intelligent low-oxygen generating device, and relates to the technical field of low-oxygen equipment. The condenser comprises a box body, wherein an opening is formed in the top of a fine filtering box, the top of the fine filtering plate penetrates through the opening and is fixedly connected with a sealing cover, a scrap receiving box is fixed at the bottom of the fine filtering plate, a buckle is hinged to one side face of the sealing cover, a clamping groove is formed in the top outside the fine filtering box, a threaded rod is rotatably connected to the top of the inner top of the fine filtering box, an internal threaded ring is in threaded connection with the peripheral side face of the threaded rod, a sweeping plate is fixed on the internal threaded ring through a connecting rod, and one side face of the sweeping plate is in sliding fit with one side face, close to a condensation box, of the fine filtering plate. According to the invention, through the design of the fine filter plate, the sealing cover, the scrap collecting box, the threaded rod and the sweeping plate, the sweeping plate cleans dust attached to the fine filter plate into the scrap collecting box, so that the fine filter plate is prevented from being blocked, the dust in the scrap collecting box is conveniently cleaned, and the problem that the filter plate in the air inlet system is easily blocked by the dust, and the air inlet system cannot be normally used due to blockage is avoided.

Description

Air intake system of intelligent hypoxia generating device

Technical Field

The invention belongs to the technical field of low-oxygen equipment, and particularly relates to an air inlet system of an intelligent low-oxygen generating device.

Background

With the continuous deepening of people's understanding of the benefit of plateau exercise training and the increasing of activities of people to plateau areas, the research work of simulating the plateau environment in the plain areas to carry out targeted training is more and more highly valued by people. The main influence of the plateau environment on human activities is just "plateau oxygen deficiency", from the perspective of human physiology, along with the reduction of atmospheric pressure, the oxygen partial pressure of the inhaled gas by the human body is reduced, then the oxygen partial pressure of the organism tissue is reduced, and the organism can be enabled to generate two aspects of reactions: physiological compensatory responses and pathological dysfunctions. The physiological compensatory ability of the human body can be improved by proper scientific training, and the effective method for improving the ability of the human body to tolerate low air pressure, namely low oxygen partial pressure environment is to carry out adaptive training under the condition of low oxygen frequently. In order to adapt to the competition in the plateau environment, most of the athletes set a training base in the plateau region for a long time to train the physical ability of the plateau so that the athletes can adapt to the physical ability requirement of the high-intensity competitive competition in the plateau environment. However, due to the limitation of conditions, all athletes cannot be effectively trained in the plateau training base, so that the plateau environment is simulated under the plain environment, so that the athletes can obtain training modes with equivalent effects, and the simulated plateau environment needs a hypoxia generating device.

The air inlet system of the existing low-oxygen generating device usually filters dust in air, so that a pure low-oxygen environment is provided for a user, but the dust easily blocks a filter plate in the air inlet system, so that the air inlet system is blocked and cannot be normally used.

Disclosure of Invention

The invention aims to provide an air inlet system of an intelligent low-oxygen generating device, which solves the problems that the air inlet system is blocked and cannot be normally used due to the fact that dust easily blocks a filter plate in the air inlet system through the design of a fine filter plate, a sealing cover, a scrap receiving box, a threaded rod and a sweeping plate.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to an air inlet system of an intelligent low-oxygen generating device, which comprises a box body; a condensation box, a fine filtering box and a gas separation box are sequentially fixed on the outer top of the box body from right to left, and an oxygen storage chamber, a gas storage chamber and an oxygen mixing chamber are respectively formed in the box body; one side surface of the condensation box is fixedly communicated with an air inlet pipe, and the other side surface of the condensation box is communicated with the inner part of the fine filter box through a connecting pipe; an opening is formed in the top of the fine filtering box, a fine filtering plate is placed between the inner walls of the fine filtering box, the top of the fine filtering plate penetrates through the opening and is fixedly connected with a sealing cover, the lower surface of the sealing cover is matched with the opening, and the lower surface of the sealing cover is attached to the outer top of the fine filtering box; a scrap receiving box is fixed at the bottom of the fine filter plate, a buckle is hinged to one side face of the sealing cover, a clamping groove is formed in the outer top of the fine filter box, and one end of the buckle is matched with the inside of the clamping groove; the top rotates in the essence filter box and is connected with the threaded rod, threaded rod week side threaded connection has the internal thread ring, the internal thread ring is fixed with through the connecting rod and sweeps the board, sweep a side of board and a side sliding fit that the essence filters the board and is close to the condensation box.

Further, the threaded rod lower extreme runs through essence and strains box bottom and extend to mixing oxygen indoor bottom, the threaded rod is located the inside week side of mixing oxygen indoor portion and evenly is fixed with the puddler.

Further, the outer top fixed mounting of fine filter box has the motor, motor output shaft one end and threaded rod upper end fixed connection.

Further, a side face of the fine filtering box is communicated with the inside of the gas separation box through a connecting pipe, the gas separation box is close to an inner side wall of the fine filtering box and is provided with an air compressor, a gas separation membrane is fixedly connected between inner walls of the gas separation box, the bottom of the gas separation box is fixedly communicated with two air pipes respectively, and the two air pipes are located on two sides of the gas separation membrane respectively.

Furthermore, the lower end of one air pipe close to the air compressor is communicated with the inside of the air storage chamber, and the lower end of the other air pipe far away from the air compressor is communicated with the inside of the oxygen storage chamber.

Furthermore, two the gas pipe all is provided with the check valve in the side all around, oxygen concentration monitor is all installed to gas receiver inner wall and oxygen storage chamber inner wall.

Further, mix oxygen room inside wall and install first gas flow valve, second gas flow valve respectively, first gas flow valve one end is linked together with the gas receiver is inside, second gas flow valve one end is linked together with the oxygen storage indoor portion.

Further, a condenser is installed inside the condensation box, and an electric heating plate and a temperature sensor are respectively installed on the inner wall of the oxygen mixing chamber.

The invention has the following beneficial effects:

1. according to the invention, through the design of the fine filter plate, the sealing cover, the chip receiving box, the threaded rod and the sweeping plate, outside air enters the fine filter box and then passes through the fine filter plate to filter dust, meanwhile, the threaded rod is driven by the motor to rotate, the threaded rod drives the sweeping plate to ascend and descend along the side face of the fine filter plate through the internal thread ring and the connecting rod, so that the sweeping plate cleans the dust attached to the fine filter plate into the chip receiving box, the fine filter plate is prevented from being blocked, then when the dust in the chip receiving box is cleaned, the buckle is manually opened, the sealing cover is horizontally moved leftwards, the chip receiving box is positioned right below the opening of the fine filter box, and then the fine filter plate is lifted upwards, so that the chip receiving box is taken out of the opening of the fine filter box, the dust in the chip receiving box is conveniently cleaned, and the problems that the filter plate in an air inlet system is easily blocked by the dust, and the air inlet system cannot be normally used are avoided.

2. According to the invention, through the design of the condenser in the condensation box, the entering external air is condensed, so that water vapor in the air is condensed on dust, the particle radius of the dust is increased, the fine filter plate is easier to filter the dust in the air, and the low-oxygen environment is purer.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic diagram of an air intake system of an intelligent hypoxia generator;

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

FIG. 3 is a schematic left-view structural diagram of the present invention;

FIG. 4 is a schematic bottom view of FIG. 3;

FIG. 5 is a structural elevation view of the present invention;

in the drawings, the components represented by the respective reference numerals are listed below:

1-box, 101-condensation box, 102-fine filtration box, 103-gas separation box, 104-oxygen storage chamber, 105-gas storage chamber, 106-oxygen mixing chamber, 107-gas inlet pipe, 108-opening, 109-fine filtration plate, 110-sealing cover, 111-scrap receiving box, 112-buckle, 113-threaded rod, 114-internal thread ring, 115-sweeping plate, 116-stirring rod, 117-motor, 118-air compressor, 119-gas separation membrane, 120-gas pipe, 121-oxygen concentration monitor, 122-first gas flow valve, 123-second gas flow valve, 124-condenser, 125-electric heating plate, 126-temperature sensor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present invention is an air intake system of an intelligent hypoxia generator, comprising a housing 1; a condensation box 101, a fine filtration box 102 and a gas separation box 103 are sequentially fixed on the outer top of the box body 1 from right to left, and an oxygen storage chamber 104, an air storage chamber 105 and an oxygen mixing chamber 106 are respectively arranged in the box body 1; an air inlet pipe 107 is fixedly communicated with one side surface of the condensation box 101, the other opposite side surface of the condensation box 101 is communicated with the inside of the fine filtration box 102 through a connecting pipe, an opening 108 is formed in the top of the fine filtration box 102, a fine filtration plate 109 is placed between the inner walls of the fine filtration box 102, the top of the fine filtration plate 109 penetrates through the opening 108 and is fixedly connected with a sealing cover 110, the lower surface of the sealing cover 110 is matched with the opening 108, the lower surface of the sealing cover 110 is attached to the outer top of the fine filtration box 102, a scrap receiving box 111 is fixed at the bottom of the fine filtration plate 109, a buckle 112 is hinged to one side surface of the sealing cover 110, a clamping groove is formed in the outer top of the fine filtration box 102, one end of the buckle 112 is matched with the inside of the clamping groove, a threaded rod 113 is rotatably connected to the inner top of the fine filtration box 102, an inner threaded ring 114 is in threaded connection with the peripheral side surface of the threaded rod 113, a sweeping plate 115 is fixed through a connecting rod, one side surface of the sweeping plate 115 is in sliding fit with one side surface of the fine filtration plate 109, which is close to the condensation box 101, the condensation box 101 condenses the entering outside air, so that the water vapor in the air is condensed on the dust, the particle radius of the dust is increased, the fine filter plate 109 filters the dust in the air more easily, the air passes through the fine filter plate 109 after entering the fine filter box 102 to filter the dust, meanwhile, the motor 117 drives the threaded rod 113 to rotate, the threaded rod 113 drives the sweeping plate 115 to ascend and descend along the side surface of the fine filter plate 109 through the internal thread ring 114 and the connecting rod, the sweeping plate 115 cleans the dust attached to the fine filter plate 109 into the scrap receiving box 111 to prevent the fine filter plate 109 from being blocked, when the dust in the scrap receiving box 111 is cleaned, the buckle 112 is manually opened, the sealing cover 110 is horizontally moved leftwards, the scrap receiving box 111 is positioned right below the opening 108 of the fine filter box 102, then the fine filter plate 109 is lifted upwards, so that the scrap receiving box 111 is taken out from the opening 108 of the fine filter box 102, and the dust in the scrap receiving box 111 is cleaned conveniently, the problem of dust block up the filter plate in the air intake system easily, lead to air intake system to take place to block up, can not normal use is avoided.

As shown in fig. 1-3, the lower end of the threaded rod 113 penetrates through the bottom of the fine filtering box 102 and extends to the bottom of the oxygen mixing chamber 106, the stirring rods 116 are uniformly fixed on the circumferential side surface of the threaded rod 113 located inside the oxygen mixing chamber 106, and the threaded rod 113 can drive the stirring rods 116 to rotate, so that the gas in the oxygen mixing chamber 106 is mixed and stirred by the stirring rods 116, and the mixing speed of the gas is increased.

Wherein as shown in fig. 1 and 5, a motor 117 is fixedly mounted at the outer top of the fine filtering box 102, one end of an output shaft of the motor 117 is fixedly connected with the upper end of the threaded rod 113, and the motor 117 can drive the threaded rod 113 to rotate to provide power for the low oxygen generating device.

As shown in fig. 1-2, one side of the fine filtration box 102 is connected to the inside of the gas separation box 103 through a connecting pipe, an air compressor 118 is installed on an inner side wall of the gas separation box 103 close to the fine filtration box 102, the structure and function of the air compressor 118 are all the prior art and are not described again, a gas separation membrane 119 is fixedly connected between inner walls of the gas separation box 103, the gas separation membrane 119 adopts an existing oxygen enrichment membrane, oxygen in the air easily passes through the gas separation membrane 119, oxygen-enriched gas can be obtained, the bottom of the gas separation box 103 is respectively and fixedly connected with two air pipes 120, and the two air pipes 120 are respectively located on two sides of the gas separation membrane 119.

As shown in FIG. 2 and FIG. 5, the lower end of an air pipe 120 far away from the air compressor 118 is communicated with the interior of the oxygen storage chamber 104, oxygen-enriched air enters the oxygen storage chamber 104 through the air pipe 120, the lower end of the air pipe 120 near the air compressor 118 is communicated with the interior of the air storage chamber 105, and the rest air in the air enters the air storage chamber 105 through the air pipe 120 for storage and standby.

Wherein as shown in fig. 2 and 5, the two gas pipes 120 are provided with check valves on the peripheral sides thereof to prevent the gas in the gas storage chamber 105 and the oxygen storage chamber 104 from flowing back to the gas separation box 103, the oxygen concentration monitors 121 are mounted on the inner walls of the gas storage chamber 105 and the oxygen storage chamber 104, the structures and functions of the oxygen concentration monitors 121 are the prior art and are not repeated, and the oxygen concentration monitors 121 can detect the oxygen concentrations in the gas storage chamber 105 and the oxygen storage chamber 104 respectively.

As shown in fig. 1-2, a first gas flow valve 122 and a second gas flow valve 123 are respectively installed on an inner side wall of the oxygen mixing chamber 106, one end of the first gas flow valve 122 is communicated with the inside of the gas storage chamber 105, one end of the second gas flow valve 123 is communicated with the inside of the oxygen storage chamber 104, the first gas flow valve 122 and the second gas flow valve 123 are adjusted according to oxygen concentrations in the gas storage chamber 105 and the oxygen storage chamber 104, and gas amounts of the gas storage chamber 105 and the oxygen storage chamber 104 respectively introduced into the oxygen mixing chamber 106 are determined, so that the oxygen content of mixed gas in the oxygen mixing chamber 106 is determined, and gas required by a low-oxygen environment is formed.

Wherein as shown in fig. 1 and fig. 5, the condenser 124 is installed inside the condensation box 101, the structure and function of the condenser 124 are all prior art, and no longer repeated description, the condenser 124 can condense the outside air entering, make the water vapor in the air condense on the dust, increase the particle radius of the dust, make the fine filter plate 109 filter the dust in the air more easily, the electric heating plate 125 and the temperature sensor 126 are installed respectively to the inner wall of the oxygen mixing chamber 106, the structure and function of the electric heating plate 125 and the temperature sensor 126 are all prior art, and no longer repeated description, the temperature sensor 126 can detect the temperature in the oxygen mixing chamber 106, the electric heating plate 125 can heat the mixed gas in the oxygen mixing chamber 106, and the gas temperature required by the low oxygen environment is formed.

The motor 117, the air compressor 118, the oxygen concentration monitor 121, the first gas flow valve 122, the second gas flow valve 123, the condenser 124, the electric heating plate 125 and the temperature sensor 126 are all electrically connected to the existing PLC controller through wires, and all electricity is provided by an external power source.

The working principle of the embodiment is as follows: when the dust collecting box is used, the condenser 124 in the condensation box 101 condenses the entering outside air, so that water vapor in the air is condensed on dust, the particle radius of the dust is increased, the fine filter plate 109 filters the dust in the air more easily, the air passes through the fine filter plate 109 after entering the fine filter box 102 to filter the dust, the motor 117 drives the threaded rod 113 to rotate, the threaded rod 113 drives the sweeping plate 115 to ascend and descend along the side surface of the fine filter plate 109 through the internal thread ring 114 and the connecting rod, the sweeping plate 115 cleans the dust attached to the fine filter plate 109 into the dust collecting box 111 to prevent the fine filter plate 109 from being blocked, when the dust in the dust collecting box 111 is cleaned, the buckle 112 is manually opened, the sealing cover 110 is horizontally moved leftwards to enable the dust collecting box 111 to be positioned right below the opening 108 of the fine filter box 102, then the fine filter plate 109 is lifted upwards, so that the dust collecting box 111 is taken out from the opening 108 of the fine filter box 102, and the dust in the dust collecting box 111 is cleaned conveniently, the problem of dust block up the filter plate in the air intake system easily, lead to air intake system to take place to block up, can not normal use is avoided.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. An air inlet system of an intelligent hypoxia generating device comprises a box body (1); the method is characterized in that:

a condensation box (101), a fine filtration box (102) and a gas separation box (103) are sequentially fixed on the outer top of the box body (1) from right to left, and an oxygen storage chamber (104), an air storage chamber (105) and an oxygen mixing chamber (106) are respectively formed in the box body (1);

an air inlet pipe (107) is fixedly communicated with one side surface of the condensation box (101), and the other side surface of the condensation box (101) is communicated with the interior of the fine filtering box (102) through a connecting pipe;

an opening (108) is formed in the top of the fine filtering box (102), fine filtering plates (109) are placed between the inner walls of the fine filtering box (102), the top of each fine filtering plate (109) penetrates through the opening (108) and is fixedly connected with a sealing cover (110), the lower surfaces of the sealing covers (110) are matched with the opening (108), and the lower surfaces of the sealing covers (110) are attached to the outer top of the fine filtering box (102);

a scrap receiving box (111) is fixed at the bottom of the fine filter plate (109), a buckle (112) is hinged to one side face of the sealing cover (110), a clamping groove is formed in the outer top of the fine filter box (102), and one end of the buckle (112) is matched with the inner part of the clamping groove;

the top is rotated and is connected with threaded rod (113) in smart filter box (102), threaded rod (113) week side threaded connection has internal thread ring (114), internal thread ring (114) are fixed with through the connecting rod and sweep board (115), sweep a side sliding fit that board (115) a side and smart filter plate (109) are close to condensation box (101).

2. The air intake system of the intelligent hypoxia generating device, according to claim 1, wherein the lower end of the threaded rod (113) penetrates through the bottom of the fine filtering box (102) and extends to the bottom of the interior of the oxygen mixing chamber (106), and the circumferential side surface of the threaded rod (113) inside the oxygen mixing chamber (106) is uniformly fixed with the stirring rod (116).

3. The air intake system of the intelligent hypoxia generating device, according to claim 1, wherein a motor (117) is fixedly mounted on the outer top of the fine filtering box (102), and one end of an output shaft of the motor (117) is fixedly connected with the upper end of a threaded rod (113).

4. The air intake system of an intelligent hypoxia generator, according to claim 1, wherein one side of the fine filtering box (102) is connected with the inside of the gas separation box (103) through a connecting pipe, an air compressor (118) is installed on the inner side wall of the gas separation box (103) close to the fine filtering box (102), a gas separation membrane (119) is fixedly connected between the inner walls of the gas separation box (103), two air pipes (120) are respectively fixedly connected to the bottom of the gas separation box (103), and the two air pipes (120) are respectively located on two sides of the gas separation membrane (119).

5. The air intake system of an intelligent hypoxia generator, according to claim 4, wherein the lower end of one air pipe (120) near the air compressor (118) is communicated with the inside of the air storage chamber (105), and the lower end of the other air pipe (120) far away from the air compressor (118) is communicated with the inside of the oxygen storage chamber (104).

6. The air intake system of an intelligent hypoxia generator, according to claim 5, wherein the air pipes (120) are provided with check valves on the peripheral sides, and the oxygen concentration monitors (121) are installed on the inner walls of the air storage chamber (105) and the oxygen storage chamber (104).

7. The air intake system of an intelligent hypoxia generator, according to claim 1, wherein a first gas flow valve (122) and a second gas flow valve (123) are respectively installed on an inner side wall of the oxygen mixing chamber (106), one end of the first gas flow valve (122) is communicated with the inside of the air storage chamber (105), and one end of the second gas flow valve (123) is communicated with the inside of the oxygen storage chamber (104).

8. The air intake system of the intelligent hypoxia generating device, according to claim 1, wherein the condenser (124) is installed inside the condensation box (101), and the inner wall of the oxygen mixing chamber (106) is respectively installed with an electric heating plate (125) and a temperature sensor (126).