CN113286494A

CN113286494A - Low oxygen generation all-in-one radiating component

Info

Publication number: CN113286494A
Application number: CN202110541885.6A
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: 2021-08-20
Anticipated expiration: 2041-05-18
Also published as: CN113286494B

Abstract

The invention discloses a radiating assembly of a low-oxygen generating all-in-one machine, and relates to the technical field of low-oxygen machines. The invention comprises a box body; the inner walls of the two sides of the box body are fixedly connected with clapboards; the inner wall of the top end of the box body and the upper surface of the partition plate are fixedly connected with two first transverse plates which are symmetrical to each other; two vertical plates which are symmetrical to each other are fixedly connected to the inner walls of the two sides of the box body; the inner side walls of the two vertical plates and the middle part of the inner wall of one side of the box body are fixedly connected with a second transverse plate; the two first transverse plates and the second transverse plate are respectively clamped with a first liquid cooling plate and a second liquid cooling plate; the inner side walls of the two vertical plates and the inner wall of one side of the box body are provided with heat dissipation devices; and a cooling device is arranged on the inner wall of the bottom end of the box body and close to the bottom of the partition plate. According to the invention, the servo motor is started to drive the driving gear, the driven gear and the rack to be in meshing transmission with each other, so that the rotating shaft and the blades are driven to rotate to be matched with the first liquid cooling plate and the second liquid cooling plate, the heat dissipation of the interior of the box body is further accelerated, the heat dissipation effect is greatly improved, the operation is simple, and the practicability is strong.

Description

Low oxygen generation all-in-one radiating component

Technical Field

The invention belongs to the technical field of low oxygen machines, and particularly relates to a radiating assembly of a low oxygen generation all-in-one machine.

Background

The low oxygen generating integrated machine is an instrument which can reduce the volume percentage of oxygen in the air so as to obtain mixed gas with rated low oxygen partial pressure. The hypoxia generation integrated machine is used for intermittent hypoxia training, can effectively form hypoxia tolerance to improve aerobic metabolism capability and promote the endurance level of athletes, and can also be used for treatment of respiratory, cardiovascular and cerebrovascular system diseases and health care rehabilitation in clinical medicine.

The existing hypoxia generation all-in-one machine is single in heat dissipation, low in heat dissipation effect efficiency, poor in heat dissipation effect and low in practicability.

Disclosure of Invention

The invention aims to provide a radiating component of a low-oxygen generating all-in-one machine, which solves the problems of single radiating effect and poor radiating effect of the low-oxygen generating all-in-one machine by matching a box body, a first liquid cooling plate, a second liquid cooling plate, a radiating device and a cooling device.

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

the invention relates to a radiating component of a low-oxygen generation all-in-one machine, which comprises a box body; the inner walls of the two sides of the box body are fixedly connected with clapboards; the inner wall of the top end of the box body and the upper surface of the partition plate are fixedly connected with two first transverse plates which are symmetrical to each other; two vertical plates which are symmetrical to each other are fixedly connected to the inner walls of the two sides of the box body and positioned on the upper surface of the partition plate; the inner side walls of the two vertical plates and the middle part of the inner wall of one side of the box body are fixedly connected with a second transverse plate; the two first transverse plates and the second transverse plates are respectively clamped with a first liquid cooling plate and a second liquid cooling plate; heat dissipation devices are arranged on the inner side walls of the two vertical plates and the inner wall of one side of the box body; a cooling device is arranged on the inner wall of the bottom end of the box body and close to the bottom of the partition plate; the heat dissipation device comprises a servo motor; the connecting shaft is connected with the connecting shaft end of the servo motor; the end part of the connecting shaft is fixedly connected with a driving gear; shaft seats are arranged on the inner side walls of the two vertical plates and the inner wall of one side of the box body in a linear array manner; a rotating shaft is rotatably connected inside the shaft seat; the peripheral side surface of the rotating shaft is fixedly connected with a driven gear; the circumferential side surface of the rotating shaft and the circumferential array on one side close to the driven gear are provided with adjusting blades; the driven gear and the driving gear are in meshed transmission connection with each other to form a rack; the cooling device comprises a water tank; a water outlet pipe is arranged on one side of the water tank; the end part of the water outlet pipe is communicated with a first connecting pipe; the linear arrays on the upper part of the first connecting pipe are communicated with water distribution pipes; the end part of the water distribution pipe is communicated with a second connecting pipe; one side of the second connecting pipe is communicated with a water inlet pipe; the water inlet pipe is communicated with the other side of the water tank; and valves are respectively arranged on the water outlet pipe and the water inlet pipe.

Furthermore, the linear arrays on two sides of the first cold liquid plate are provided with first convex blocks; the linear arrays on one side of the first cold liquid plate are provided with first through grooves; the linear arrays on one side of the first cold liquid plate and on two sides of the first through groove are provided with first hinged supports; two sides of the first hinged support are fixedly connected with first water pipe sleeves; and a first clamping groove matched with the water distribution pipe is formed in the first water pipe sleeve.

Further, the linear arrays on two sides of the second cold liquid plate are provided with second convex blocks; a second through groove is formed in each linear array on one side of the second cold liquid plate; the linear arrays on one side of the second liquid cooling plate and on two sides of the second through groove are provided with second hinged supports; two sides of the second hinged support are fixedly connected with second water pipe sleeves; a second clamping groove matched with the water distribution pipe is formed in the second water pipe sleeve; the second cold liquid plate is the same as the first cold liquid plate in structure.

Furthermore, the two first transverse plates are provided with first blind holes matched with the first convex blocks in a linear array manner relative to the inner walls; the two first transverse plates are provided with second blind holes in linear arrays relative to the inner wall; and third blind holes matched with the second convex blocks and the second blind holes are formed in the linear arrays on the two sides of the second transverse plate.

Furthermore, two mutually symmetrical U-shaped support frames are fixedly connected to the top of the partition plate and far away from the servo motor; and the inner walls of the two U-shaped supporting frames are provided with sliding chutes matched with the racks.

Furthermore, a door plate is hinged to the edge of the outer wall of one side of the box body; the surface of the door plate is fixedly connected with a handle.

The invention has the following beneficial effects:

1. according to the invention, the box body, the first liquid cooling plate, the second liquid cooling plate and the cooling device are matched, the valve on the water outlet pipe of the water tank is opened, water flows into the first connecting pipe, the water distribution pipe, the second connecting pipe and the water inlet pipe through the water outlet pipe respectively, the valve on the water inlet pipe is opened to realize water circulation, meanwhile, the water distribution pipe is clamped and fixed by the first water pipe sleeve and the second water pipe sleeve on the first liquid cooling plate and the second liquid cooling plate, the first liquid cooling plate and the second liquid cooling plate can effectively radiate the inside of the box body, and the radiating efficiency is high.

2. According to the invention, the box body, the heat dissipation device, the servo motor, the driving gear, the driven gear and the rack are matched, and the servo motor is started to drive the driving gear, the driven gear and the rack to be in meshing transmission with each other, so that the rotating shaft and the blades are driven to rotate to be matched with the first liquid cooling plate and the second liquid cooling plate, the heat dissipation of the interior of the box body is further accelerated, the heat dissipation effect is greatly improved, the operation is simple, and the practicability is strong.

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 structural view of a heat dissipation assembly of a hypoxia generation all-in-one machine according to the present invention;

FIG. 2 is a schematic cross-sectional view of a heat dissipation assembly of the integrated hypoxia generator;

FIG. 3 is a schematic diagram of a right side cross-sectional view of a heat sink assembly of the integrated hypoxia generator;

FIG. 4 is a schematic structural view of the case;

FIG. 5 is an enlarged view taken at A in FIG. 4;

FIG. 6 is a schematic diagram of a first liquid cold plate;

FIG. 7 is a schematic diagram of a second liquid cooling plate;

fig. 8 is a schematic structural view of the rotating shaft.

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

1-box body, 2-first liquid cooling plate, 3-second liquid cooling plate, 4-heat dissipation device, 5-cooling device, 6-rotating shaft, 7-rack, 8-valve, 9-door plate, 101-partition plate, 102-first transverse plate, 103-vertical plate, 104-second transverse plate, 105-first blind hole, 106-second blind hole, 107-third blind hole, 108-U-shaped support frame, 109-sliding groove, 201-first lug, 202-first through groove, 203-first hinge seat, 204-first water pipe sleeve, 205-first clamping groove, 301-second lug, 302-second through groove, 303-second hinge seat, 304-second water pipe sleeve, 305-second clamping groove, 401-servo motor, 402-connecting shaft, 403-driving gear, 404-shaft seat, 501-water tank, 502-water outlet pipe, 503-first connecting pipe, 504-water dividing pipe, 505-second connecting pipe, 506-water inlet pipe, 601-driven gear, 602-blade, and 901-handle.

Detailed Description

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

Referring to fig. 1-8, the present invention is a heat dissipation assembly of an integrated hypoxia generator, comprising a housing 1; the inner walls of two sides of the box body 1 are fixedly connected with partition plates 101; the inner wall of the top end of the box body 1 and the upper surface of the clapboard 101 are fixedly connected with two first transverse plates 102 which are symmetrical with each other; two vertical plates 103 which are symmetrical to each other are fixedly connected to the inner walls of the two sides of the box body 1 and positioned on the upper surface of the partition plate 101; the inner side walls of the two vertical plates 103 and the middle part of the inner wall of one side of the box body 1 are fixedly connected with a second transverse plate 104; the two first transverse plates 102 and the second transverse plate 104 are respectively clamped with a first liquid cooling plate 2 and a second liquid cooling plate 3; the inner side walls of the two vertical plates 103 and the inner wall of one side of the box body 1 are provided with heat dissipation devices 4; a cooling device 5 is arranged on the inner wall of the bottom end of the box body 1 and close to the bottom of the partition plate 101; the heat dissipation device 4 includes a servo motor 401; a connecting shaft 402 is connected to the connecting shaft end of the servo motor 401; the end of the connecting shaft 402 is fixedly connected with a driving gear 403; shaft seats 404 are arranged on the inner side walls of the two vertical plates 103 and the inner wall of one side of the box body 1 in a linear array manner; a rotating shaft 6 is rotatably connected inside the shaft seat 404; the peripheral side surface of the rotating shaft 6 is fixedly connected with a driven gear 601; blades 602 are arranged on the circumferential side surface of the rotating shaft 6 and on the side close to the driven gear 601 in a circumferential array manner; the driven gear 601 and the driving gear 403 are in meshed transmission connection with a rack 7; the servo motor 401 is started to drive the driving gear 403, the driven gear 601 and the rack 7 to be in meshing transmission with each other, so that the rotating shaft 6 and the blades 602 are driven to rotate to be matched with the first liquid cooling plate 2 and the second liquid cooling plate 3, heat dissipation inside the box body 1 is further accelerated, and the heat dissipation effect is greatly improved; the cooling device 5 includes a water tank 501; a water outlet pipe 502 is arranged on one side of the water tank 501; the end part of the water outlet pipe 502 is communicated with a first connecting pipe 503; the linear arrays on the upper part of the first connecting pipe 503 are all communicated with a water distribution pipe 504; a second connecting pipe 505 is communicated with the end part of the water distribution pipe 504; one side of the second connecting pipe 505 is communicated with a water inlet pipe 506; the water inlet pipe 506 is communicated with the other side of the water tank 1; the water outlet pipe 502 and the water inlet pipe 506 are respectively provided with a valve 8; the valve on the water outlet pipe 502 on one side of the water tank 501 is opened, water flows into the first connecting pipe 503, the water distribution pipe 504, the second connecting pipe 505 and the water inlet pipe 506 through the water outlet pipe 502, and then the valve 8 on the water inlet pipe 506 is opened to realize water circulation, so that the first liquid cooling plate 2 and the second liquid cooling plate 3 can effectively dissipate heat inside the tank body 1.

Wherein, the linear arrays on both sides of the first cold liquid plate 2 are provided with first bumps 201; the linear arrays on one side of the first cold liquid plate 2 are all provided with first through grooves 202; the linear arrays on one side of the first cold liquid plate 2 and on two sides of the first through groove 202 are both provided with first hinged supports 203; two sides of the first hinged support 203 are fixedly connected with a first water pipe sleeve 204; a first clamping groove 205 matched with the water distribution pipe 504 is formed in the first water pipe sleeve 204; the first through groove 202 drives the driving gear 403, the driven gear 601 and the rack 7 to be meshed for transmission through the servo motor 401, so as to drive the rotating shaft 6 and the blades 602 to rotate, and the heat dissipation efficiency is improved.

Wherein, the linear arrays on both sides of the second cold liquid plate 3 are provided with second bumps 301; the linear arrays on one side of the second cold liquid plate 3 are all provided with second through grooves 302; the second hinging seats 303 are arranged on one side of the second cold liquid plate 3 and positioned on the two sides of the second through groove 302 in a linear array manner; two sides of the second hinged support 303 are fixedly connected with a second water pipe sleeve 304; a second clamping groove 305 matched with the water distribution pipe 504 is formed in the second water pipe sleeve 304; the second cold liquid plate 3 has the same structure as the first cold liquid plate 2; the first water pipe sleeve 204 and the second water pipe sleeve 304 on the first liquid cooling plate 2 and the second liquid cooling plate 3 are clamped and fixed to the water distribution pipe 504, and therefore the water distribution pipe 504 can be effectively prevented from being deviated.

The two first transverse plates 102 are provided with first blind holes 105 matched with the first convex blocks 201 in a linear array manner relative to the inner walls; the two first transverse plates 102 are provided with second blind holes 106 opposite to the linear array of the inner walls; third blind holes 107 matched with the second convex blocks 301 and the second blind holes 106 are formed in the linear arrays on the two sides of the two second transverse plates 104; first blind hole 105, second blind hole 106 and third blind hole 107 can effectually fix first liquid-cooling board 2 and second liquid-cooling board 3, and the effectual first liquid-cooling board 2 and the second liquid-cooling board 3 that prevents drop.

Two mutually symmetrical U-shaped support frames 108 are fixedly connected to the top of the partition plate 101 and far away from the servo motor 401; the inner walls of the two U-shaped supporting frames 108 are provided with sliding chutes 109 matched with the racks 7; the sliding groove 109 facilitates fixing of the rack 7, prevents deviation during transmission, and improves working efficiency. A door plate 9 is hinged at the edge of the outer wall of one side of the box body 1; a handle 901 is fixedly connected to the surface of the door panel 9.

One specific application of this embodiment is: when the water circulation cooling box is used, the valve 8 on the water outlet pipe 502 communicated with one side of the water box 501 is opened, water flows into the first connecting pipe 503, the water distribution pipe 504, the second connecting pipe 505 and the water inlet pipe 506 through the water outlet pipe 502 respectively, the valve 8 on the water inlet pipe 506 is opened to realize water circulation, meanwhile, the water distribution pipe 504 is sleeved and connected by the first water pipe sleeve 204 and the second water pipe 304 on the first liquid cooling plate 2 and the second liquid cooling plate 3, the first water pipe sleeve 204 and the second water pipe 304 are sleeved and respectively provided with the first clamping groove 205 and the second clamping groove 305 which are matched with the water distribution pipe 504 to clamp and fix, the first liquid cooling plate 2 and the second liquid cooling plate 3 can effectively radiate the inside of the box body 1, the driving gear 406, the driven gear 601 and the rack 7 are driven to be in mutual meshing transmission by starting the servo motor 401, so as to drive the rotating shaft 6 and the blades 602 to rotate to be matched with the first liquid cooling plate 2 and the second liquid cooling plate 3, further accelerate to dispel the heat to box 1 inside, improve the radiating effect greatly, easy operation, the practicality is strong.

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. A radiating assembly of a low-oxygen generation all-in-one machine comprises a box body (1), wherein partition plates (101) are fixedly connected to the inner walls of two sides of the box body (1);

the method is characterized in that:

the inner wall of the top end of the box body (1) and the upper surface of the partition plate (101) are fixedly connected with two first transverse plates (102) which are symmetrical to each other;

two vertical plates (103) which are symmetrical to each other are fixedly connected to the inner walls of the two sides of the box body (1) and are positioned on the upper surface of the partition plate (101); the inner side walls of the two vertical plates (103) and the middle part of the inner wall of one side of the box body (1) are fixedly connected with a second transverse plate (104); the two first transverse plates (102) and the second transverse plates (104) are respectively clamped with a first liquid cooling plate (2) and a second liquid cooling plate (3); the inner side walls of the two vertical plates (103) and the inner wall of one side of the box body (1) are provided with heat dissipation devices (4);

a cooling device (5) is arranged on the inner wall of the bottom end of the box body (1) and close to the bottom of the partition plate (101);

the heat dissipation device (4) comprises a servo motor (401); the connecting shaft (402) is connected to the connecting shaft end of the servo motor (401); the end part of the connecting shaft (402) is fixedly connected with a driving gear (403); shaft seats (404) are arranged on the inner side walls of the two vertical plates (103) and the inner wall of one side of the box body (1) in a linear array;

the shaft seat (404) is internally and rotatably connected with a rotating shaft (6).

2. A hypoxia generation all-in-one heat dissipation assembly according to claim 1, wherein the cooling device (5) comprises a water tank (501); a water outlet pipe (502) is arranged on one side of the water tank (501);

the end part of the water outlet pipe (502) is communicated with a first connecting pipe (503); the linear arrays on the upper parts of the first connecting pipes (503) are communicated with water distribution pipes (504);

a second connecting pipe (505) is communicated with the end part of the water diversion pipe (504); one side of the second connecting pipe (505) is communicated with a water inlet pipe (506); the water inlet pipe (506) is communicated with the other side of the water tank (1).

3. The integrated hypoxia generator heat dissipation assembly according to claim 2, wherein the water outlet pipe (502) and the water inlet pipe (506) are respectively provided with a valve (8).

4. The integrated hypoxia generator heat dissipation assembly according to claim 1, wherein a driven gear (601) is fixedly connected to the peripheral side surface of the rotating shaft (6); blades (602) are arranged on the circumferential side surface of the rotating shaft (6) and on the circumferential array close to one side of the driven gear (601); the driven gear (601) and the driving gear (403) are in meshed transmission connection with a rack (7).

5. The hypoxia generation all-in-one heat dissipation assembly according to claim 2, wherein the linear arrays on both sides of the first cold liquid plate (2) are provided with first bumps (201);

the linear arrays on one side of the first liquid cooling plate (2) are provided with first through grooves (202);

the linear arrays on one side of the first liquid cooling plate (2) and on two sides of the first through groove (202) are provided with first hinged supports (203); two sides of the first hinged support (203) are fixedly connected with a first water pipe sleeve (204);

the first water pipe sleeve (204) is provided with a first clamping groove (205) matched with the water distribution pipe (504).

6. The integrated low-oxygen generating machine heat dissipation assembly of claim 2, wherein the linear arrays on both sides of the second cold liquid plate (3) are provided with second bumps (301);

a second through groove (302) is formed in each linear array on one side of the second cold liquid plate (3);

the linear arrays on one side of the second cold liquid plate (3) and on two sides of the second through groove (302) are provided with second hinged supports (303);

two sides of the second hinged support (303) are fixedly connected with a second water pipe sleeve (304); a second clamping groove (305) matched with the water distribution pipe (504) is formed in the second water pipe sleeve (304); the second cold liquid plate (3) has the same structure as the first cold liquid plate (2).

7. The integrated low-oxygen generating machine heat dissipation assembly of claim 6, wherein the two first transverse plates (102) are provided with first blind holes (105) in linear arrays relative to the inner walls, and the first blind holes are matched with the first protrusions (201); the two first transverse plates (102) are provided with second blind holes (106) in a linear array relative to the inner wall; and third blind holes (107) matched with the second convex blocks (301) and the second blind holes (106) are formed in the linear arrays on the two sides of the second transverse plates (104).

8. The integrated low-oxygen generating machine heat dissipation assembly of claim 1, wherein two symmetrical U-shaped support frames (108) are fixedly connected to the top of the partition plate (101) and far away from the servo motor (401); the inner walls of the two U-shaped supporting frames (108) are provided with sliding chutes (109) matched with the racks (7).

9. The hypoxia generation all-in-one heat dissipation assembly according to claim 1, wherein a door panel (9) is hinged to the edge of the outer wall of one side of the box body (1); the surface of the door panel (9) is fixedly connected with a handle (901).