CN220467581U

CN220467581U - Radiating mechanism of oxygenerator

Info

Publication number: CN220467581U
Application number: CN202321798012.4U
Authority: CN
Inventors: 王勤修; 王良辰; 王浩然
Original assignee: Shangqiu Qinheng Oxygen Supply Technology Co ltd
Current assignee: Shangqiu Qinheng Oxygen Supply Technology Co ltd
Priority date: 2023-07-10
Filing date: 2023-07-10
Publication date: 2024-02-09
Anticipated expiration: 2033-07-10

Abstract

The utility model provides a heat dissipation mechanism of an oxygenerator, which relates to the technical field of oxygenerators, and comprises an oxygenerator main body, wherein an air extraction mechanism is arranged in the oxygenerator main body, an air inlet mechanism for air inlet is arranged on one side of the air extraction mechanism, an air outlet mechanism for air exhaust is arranged on the other side of the air extraction mechanism, and a heat dissipation bottom plate is arranged at the bottom of the air extraction mechanism for heat dissipation of the oxygenerator; after oxygen production is finished, the baffle is enabled to fall down, the automatic sweeping function is activated, the air inlet is swept, the water flow is blocked by the baffle to enter the air inlet, the damage to the molecular film is prevented, dust is cleaned, the dust flows into the dust accumulation groove, the air inlet of the cleaning oxygenerator is directly realized, dust accumulation is avoided at the air inlet, the influence on the air inlet quantity is avoided, the automatic sweeping function is realized through the linkage mechanism, and the more beneficial heat dissipation effect of the heat dissipation device is realized.

Description

Radiating mechanism of oxygenerator

Technical Field

The utility model relates to the technical field of oxygenerators, in particular to a heat dissipation mechanism of an oxygenerator.

Background

An oxygenerator, also known as an oxygen generator or oxygenerator, is a device that is capable of extracting oxygen from air. It is mainly applied to the medical field and provides high-purity oxygen for patients needing additional oxygen supply. The working principle of the oxygenerator is that oxygen is separated from air through a molecular sieve adsorption technology or a membrane separation technology, the oxygenerator generates oxygen rapidly, the oxygen concentration is high, the oxygenerator uses a large-displacement oil-free compressor as power, the power consumption is low, the oxygenerator is suitable for oxygen therapy and oxygen health care of various people, after the oxygen prepared by the oxygenerator is inhaled by a user, the arterial blood oxygen content is directly improved, and the low-flow oxygen therapy and the oxygen health care are fast, positively beneficial and harmless without special guidance effects.

For example, application number 202222138082.9 discloses a high-efficient oxygenerator radiator, including the fan of bleeding, one side of the fan of bleeding is provided with air inlet mechanism, the opposite side of the fan of bleeding is provided with air outlet mechanism, the bottom fixedly connected with radiating bottom plate of the fan of bleeding, air inlet mechanism and air outlet mechanism all include the block frame, the inside that blocks the frame is provided with the blocking piece, one side swing joint that blocks the frame has the wind frame baffle, a plurality of fender lath grooves have been seted up to the inside of wind frame baffle, the inside that wind frame baffle openly and the back all is provided with the hand screw, threaded connection has oxygenerator main part between four hand screw, air inlet mechanism and air outlet mechanism set up the both sides in oxygenerator main part bottom respectively. According to the utility model, the wind frame baffle is detached from the oxygenerator main body by adjusting the threaded connection condition of the hand screw and the oxygenerator main body, so that the blocking piece can be taken out from the inside of the blocking frame, and dust collected on the inner side of the blocking piece can be conveniently and directly cleaned. Still there is the radiator configuration of current oxygenerator inside the casing, and it is after long-time use, and the inside dust that gathers of air intake is difficult for the clearance, produces the influence to the size of intake, and the oxygen production efficiency is lower and equipment trouble etc. appear in the emergency treatment in-process easily.

Disclosure of Invention

According to the defects in the background art, the utility model provides the heat dissipation mechanism of the oxygen generator, and solves the technical problems that the radiator of the existing oxygen generator is arranged in the shell, dust is easy to accumulate in the air inlet after the radiator is used for a long time, the radiator is inconvenient to clean, the air inlet is influenced, and the oxygen generation efficiency is low and equipment faults are easy to occur in the emergency process.

The scheme adopted by the utility model is as follows: the heat dissipation mechanism of oxygenerator includes:

the oxygen generator comprises an oxygen generator main body, wherein an air extraction mechanism is arranged in the oxygen generator main body, an air inlet mechanism for air inlet is arranged on one side of the air extraction mechanism, an air outlet mechanism for air exhaust is arranged on the other side of the air extraction mechanism, and a heat dissipation bottom plate is arranged at the bottom of the air extraction mechanism and used for dissipating heat of the oxygen generator;

the cleaning disc is arranged on one side of the air inlet mechanism and used for cleaning the air inlet mechanism, a limiting groove is formed in the top of the air inlet mechanism, and a linkage mechanism is arranged inside one side of the air suction mechanism and used for driving the cleaning disc to move left and right along the limiting groove for cleaning.

Preferably, air inlet mechanism one side is provided with the air inlet bar groove, rectangular groove has been seted up at air inlet mechanism top, rectangular inslot portion sliding connection has the baffle, baffle top fixedly connected with handle, the inside fastener that is provided with of baffle, the fastener is connected with rectangular groove block, baffle one side fixedly connected with ejector pad, air inlet mechanism one side fixedly connected with rack, air inlet mechanism bottom is provided with the hourglass groove.

Preferably, the inside link gear that is provided with of mechanism of bleeding, link gear includes driving motor, and driving motor one side is provided with the fan of bleeding, fan one side fixedly connected with first conical gear of bleeding, first conical gear one side and second conical gear meshing are connected, the inside fixedly connected with bull stick of second conical gear, the outside fixedly connected with third conical gear of first connection dwang bottom, mechanism one side fixedly connected with connecting pipe bleeds, mechanism opposite side fixedly connected with tail pipe bleeds, tail pipe and air inlet mechanism one side block are connected.

Preferably, the bottom of the third conical gear is meshed with and connected with a fourth conical gear, a second connecting rotating rod is fixedly connected inside the fourth conical gear, a supporting piece is rotationally connected outside the second connecting rotating rod, the supporting piece is fixedly connected with a radiating bottom plate, the other end of the second connecting rotating rod is fixedly connected with a fifth conical gear, one side of the fifth conical gear is meshed with and connected with a sixth conical gear, a third connecting rotating rod is fixedly connected inside the sixth conical gear, one end of the third connecting rotating rod is fixedly connected with a belt wheel, a first conveying belt is arranged outside the belt wheel, and the belt wheel is rotationally connected with a driven belt wheel through the first conveying belt.

Preferably, the oxygenerator main part bilateral symmetry fixedly connected with mount, mount inboard symmetry is provided with the spring bayonet lock, adjacent two spring bayonet lock one side fixedly connected with bearing mounting, adjacent two rotate between the bearing mounting and be connected with two-way lead screw, bearing mounting one side fixedly connected with stopper.

Preferably, the cleaning mechanism comprises a threaded sleeve plate, a bidirectional screw rod is connected to the inner side of the threaded sleeve plate in a threaded mode, the threaded sleeve plate is approximately in a digital six-shape, a water tank is fixedly connected to one side of the threaded sleeve plate, a connecting block is fixedly connected to one side of the water tank, a limiting rod is fixedly connected to one side of the connecting block, the limiting rod is in an L shape, and the limiting rod is slidably connected with the limiting groove.

Preferably, the connecting block is kept away from gag lever post one side and rotates and be connected with the transfer line, transfer line one side fixedly connected with gear, the gear is connected with the rack meshing, and the transfer line outside is provided with the second drive belt, and the transfer line passes through the second drive belt and rotates with the washing dish to be connected, the washing dish passes through the transfer line and rotates with the thread bushing board to be connected, the washing dish is located air inlet strip groove one side.

Preferably, an atomization interface is arranged on one side of the oxygenerator main body, casters are arranged at four corners of the bottom of the oxygenerator main body, a spring piece is arranged on one side of the oxygenerator main body and connected with a handle in a clamping mode, an air inlet groove is formed in the oxygenerator main body, close to the bottom of the spring piece, and an air inlet mechanism is arranged inside the air inlet groove.

The utility model has the beneficial effects that:

after oxygen production is finished, the baffle is enabled to fall down, an automatic sweeping function is activated, the air inlet is swept, water flow is blocked to enter the air inlet through the baffle, and the molecular film is prevented from being damaged. The dust flows into the dust accumulation groove after being cleaned, the air inlet of the cleaning oxygenerator is directly realized, dust accumulation is avoided at the air inlet, the influence on the air inlet quantity is avoided, and the automatic sweeping function is realized through the linkage mechanism, so that the heat dissipation effect of the heat dissipation device is more beneficial.

Drawings

FIG. 1 is a schematic perspective view of a heat dissipation mechanism of an oxygenerator of the present utility model;

FIG. 2 is an expanded schematic view of the internal structure of the heat dissipation mechanism of the oxygenerator of the present utility model;

FIG. 3 is a schematic view showing the internal structural details of the heat dissipating mechanism of the oxygenerator of the present utility model;

FIG. 4 is a detailed schematic view of the cleaning mechanism of the heat dissipating mechanism of the oxygenerator of the present utility model;

FIG. 5 is a detailed schematic diagram of the linkage mechanism of the heat dissipation mechanism of the oxygenerator of the present utility model;

FIG. 6 is a schematic view showing the structure of a baffle plate of a heat radiation mechanism of the oxygenerator of the present utility model in detail;

fig. 7 is a detailed structural schematic diagram of an adjusting block of a heat dissipating mechanism of the oxygenerator of the present utility model.

Reference numerals:

10. an oxygenerator body; 101. an atomization interface; 102. casters; 103. a spring member; 104. an air inlet groove;

11. an air inlet mechanism; 111. an air inlet strip groove; 112. a baffle; 1121. a handle; 1122. a clamping piece; 1123. a pushing block; 113. a limit groove; 114. a rack; 115. a drain groove; 12. an air outlet mechanism; 13. a heat dissipation base plate;

14. an air extraction mechanism; 141. an air extraction fan; 1411. a first bevel gear; 1412. a second bevel gear; 142. a first connecting rod; 1421. a third bevel gear; 1422. a fourth bevel gear; 143. a second connecting rod; 1431. a fifth bevel gear; 1432. a sixth bevel gear; 144. a support; 145. a third connecting rotating rod; 146. a belt wheel; 147. a first conveyor belt; 148. a driven pulley; 149. a two-way screw rod;

15. a thread sleeve plate; 151. a water tank; 152. a connecting block; 1521. a limit rod; 153. a gear; 154. a second belt; 155. cleaning a tray;

16. a fixing frame; 161. a spring bayonet lock; 162. a bearing mount; 163. a limiting block; 17. a connecting pipe; 18. a fish tail pipe.

Detailed Description

The radiator of the existing oxygenerator is arranged in the shell, dust is easy to accumulate in the air inlet after the radiator is used for a long time, cleaning is inconvenient, the size of the air inlet is influenced, and the oxygen generation efficiency is low and equipment faults are easy to occur in the emergency treatment process;

referring to fig. 1-7, a heat dissipation mechanism of an oxygenerator includes: an oxygenerator main body 10, an air inlet mechanism 11, an air extraction mechanism 14 and a cleaning disc 155,

the oxygenerator main body 10 both sides are provided with air inlet mechanism 11 and play fan mechanism 12 respectively, oxygenerator main body 10 inside is provided with air extraction mechanism 14, air extraction mechanism 14 is located air inlet mechanism 11 one side, air inlet mechanism 11 is cuboid form, air inlet mechanism 11 one side is provided with clean mechanism, clean mechanism is including being provided with cleaning disk 155, be used for carrying out the cleanness to air inlet bar groove 111 of air inlet mechanism 11 one side, cleaning disk 155 can be square dish or disc, this embodiment adopts discoid, air extraction mechanism 14 inside is provided with the link gear, drive clean mechanism through the link gear and control along spacing groove 113 and remove, drive cleaning disk 155 simultaneously and rotate, air extraction mechanism 14 one side is provided with connecting pipe 17, connecting pipe 17 is the L font, and the air extraction mechanism 14 opposite side is provided with the fish tail pipe 18, fish tail pipe 18 is fan-shaped, and fish tail pipe 18 one side and air inlet mechanism 11 block connection, carry out the convulsions through air extraction fan 141 that air inlet bar groove 111 is inside was arranged in fish tail pipe 18, thereby make oxygen, through after the oxygen making, fall baffle 112, automatic sweeping function is carried out to the air intake. And the baffle 112 prevents water flow from entering the air inlet to prevent damage to the molecular film, so that dust can flow into the leakage groove 115 after being cleaned, and uniform treatment is facilitated.

Referring to fig. 5, in the present utility model, preferably, the linkage mechanism includes an air extraction fan 141, and the first conical gear 1411 disposed at one side of the air extraction fan 141 is engaged with the second conical gear 1412 to drive the third conical gear 1421 at the bottom of the first connecting rod 142 to be engaged with the fourth conical gear 1422, and simultaneously, the second connecting rod 143 inside the fourth conical gear 1422 is linked to drive the fifth conical gear 1431 at one side of the second connecting rod 143 to be engaged with the sixth conical gear 1432 to rotate, and the third connecting rod 145 inside the sixth conical gear 1432 and the belt pulley 146 at one side of the third connecting rod 145 to be rotated;

referring to fig. 1, 3 and 6, in the present utility model, preferably, the fixing frames 16 symmetrically arranged at both sides of the main body 10 of the oxygenerator are used for pushing the limiting block 163 to move to one side by the pushing block 1123 when the baffle 112 falls, so that the bearing fixing piece 162 and the bidirectional screw rod 149 are tensioned, and the cleaning mechanism outside the bidirectional screw rod 149 is driven to move by the linkage mechanism;

referring to fig. 4, in the present utility model, preferably, the cleaning mechanism includes a threaded sleeve plate 15, and through a limit rod 1521 on one side of the threaded sleeve plate 15, the cleaning mechanism slides along a limit groove 113 in a limit manner, and simultaneously, a gear 153 is meshed with a rack 114 to rotate, so as to drive a second driving belt 154 and a cleaning disc 155 to rotate, thereby, the air inlet slot 111 is moved and cleaned, a baffle 112 can protect the inside of the air inlet mechanism 11, and cleaned water flows into a drain groove 115, so that uniform treatment is performed;

working principle: after oxygen production is finished, the handle 1121 is sprung by pressing the spring member 103 on one side of the oxygenerator main body 10, so that the baffle 112 slides along the inside of the air inlet mechanism 11 under the action of gravity, meanwhile, the push block 1123 arranged on one side of the baffle 112 pushes the limiting block 163 on one side of the fixing frame 16 downwards to move to one side, meanwhile, the spring bayonet 161 on the inner side of the fixing frame 16 tightens the bearing fixing member 162 and the bidirectional screw 149, so that the threaded sleeve plate 15 on the outer side of the bidirectional screw 149 is driven to rotate, the water tank 151 is driven to move through the limit rod 1521 arranged on one side of the threaded sleeve plate 15 and the limit groove 113, and meanwhile, the gear 153 is meshed with the rack 114 to drive the cleaning disc 155 to rotate, so that the air inlet groove 111 is cleaned, during cleaning, the baffle 112 falls to block water flow into the air inlet, damage to prevent molecular films, dust in the air inlet is cleaned, and then flows into the air leakage groove 115, so that uniform treatment is performed, and during oxygen production, the bearing fixing member 162 is not tensioned with the bidirectional screw 149, so that the bidirectional screw 149 is not driven to rotate, and the cleaning mechanism is not started.

The above description is only for the purpose of illustrating the utility model, and it should be understood that the utility model is not limited to the above embodiments, but various modifications consistent with the idea of the utility model are within the scope of the utility model.

Claims

1. Heat dissipation mechanism of oxygenerator, its characterized in that includes:

the oxygen generator comprises an oxygen generator main body (10), wherein an air extraction mechanism (14) is arranged in the oxygen generator main body (10), an air inlet mechanism (11) for air inlet is arranged on one side of the air extraction mechanism (14), an air outlet mechanism (12) for air exhaust is arranged on the other side of the air extraction mechanism (14), and a heat dissipation bottom plate (13) is arranged at the bottom of the air extraction mechanism (14) for dissipating heat of the oxygen generator;

the cleaning device comprises a cleaning disc (155), wherein the cleaning disc (155) is arranged on one side of an air inlet mechanism (11) and used for cleaning the air inlet mechanism (11), a limiting groove (113) is formed in the top of the air inlet mechanism (11), and a linkage mechanism is arranged inside one side of an air suction mechanism (14) and used for driving the cleaning disc (155) to move left and right along the limiting groove (113).

2. The heat dissipation mechanism of an oxygen generator according to claim 1, wherein an air inlet bar groove (111) is formed in one side of the air inlet mechanism (11), a rectangular groove is formed in the top of the air inlet mechanism (11), a baffle plate (112) is slidably connected inside the rectangular groove, a handle (1121) is fixedly connected to the top of the baffle plate (112), a clamping piece (1122) is arranged inside the baffle plate (112), the clamping piece (1122) is clamped and connected with the rectangular groove, a pushing block (1123) is fixedly connected to one side of the baffle plate (112), a rack (114) is fixedly connected to one side of the air inlet mechanism (11), and a leakage groove (115) is formed in the bottom of the air inlet mechanism (11).

3. The heat dissipation mechanism of an oxygen generator according to claim 1, wherein a linkage mechanism is arranged inside the air extraction mechanism (14), the linkage mechanism comprises a driving motor, an air extraction fan (141) is arranged on one side of the driving motor, a first conical gear (1411) is fixedly connected on one side of the air extraction fan (141), one side of the first conical gear (1411) is meshed with a second conical gear (1412), a first connecting rotating rod (142) is fixedly connected inside the second conical gear (1412), and a third conical gear (1421) is fixedly connected on the outer side of the bottom of the first connecting rotating rod (142).

4. The heat dissipation mechanism of an oxygen generator according to claim 3, wherein a fourth conical gear (1422) is connected to the bottom of the third conical gear (1421) in a meshed manner, a second connecting rod (143) is fixedly connected to the inside of the fourth conical gear (1422), a supporting piece (144) is rotatably connected to the outside of the second connecting rod (143), the supporting piece (144) is fixedly connected to the heat dissipation bottom plate (13), a fifth conical gear (1431) is fixedly connected to the other end of the second connecting rod (143), one side of the fifth conical gear (1431) is connected to the sixth conical gear (1432) in a meshed manner, a third connecting rod (145) is fixedly connected to the inside of the sixth conical gear (1432), one end of the third connecting rod (145) is fixedly connected to a belt pulley (146), a first conveying belt (147) is arranged on the outside of the belt pulley (146), the belt pulley (146) is rotatably connected to a driven belt pulley (148) through the first conveying belt (147), one side of the air extraction mechanism (14) is fixedly connected to a connecting pipe (17), one side of the air extraction mechanism (14) is fixedly connected to the other side of the tail pipe (18), and the other side of the tail pipe (18) is fixedly connected to the air intake mechanism (18).

5. The heat dissipation mechanism of an oxygen generator according to claim 1, wherein a fixing frame (16) is symmetrically and fixedly connected to two sides of the oxygen generator main body (10), spring clamping pins (161) are symmetrically arranged on the inner sides of the fixing frame (16), bearing fixing pieces (162) are fixedly connected to one sides of two adjacent spring clamping pins (161), a bidirectional screw rod (149) is rotatably connected between the two adjacent bearing fixing pieces (162), a limiting block (163) is fixedly connected to one side of the bearing fixing piece (162), and a cleaning mechanism is arranged on the outer sides of the bidirectional screw rods (149).

6. The heat dissipation mechanism of an oxygen generator according to claim 5, wherein the cleaning mechanism comprises a threaded sleeve plate (15), a bidirectional screw rod (149) is connected to the inner side of the threaded sleeve plate (15) in a threaded manner, the threaded sleeve plate (15) is approximately in a digital six-shape, a water tank (151) is fixedly connected to one side of the threaded sleeve plate (15), a connecting block (152) is fixedly connected to one side of the water tank (151), a limit rod (1521) is fixedly connected to one side of the connecting block (152), the limit rod (1521) is in an L shape, and the limit rod (1521) is slidably connected with the limit groove (113).

7. The cooling mechanism of an oxygenerator according to claim 6, wherein the connecting block (152) is rotatably connected with a transmission rod on one side far away from the limit rod (1521), a gear (153) is fixedly connected on one side of the transmission rod, the gear (153) is in meshed connection with the rack (114), a second transmission belt (154) is arranged on the outer side of the transmission rod, the transmission rod is rotatably connected with a cleaning disc (155) through the second transmission belt (154), the cleaning disc (155) is rotatably connected with a thread sleeve plate (15) through the transmission rod, and the cleaning disc (155) is positioned on one side of the air inlet strip groove (111).

8. The heat dissipation mechanism of an oxygenerator according to claim 2, wherein an atomization interface (101) is arranged on one side of the oxygenerator main body (10), casters (102) are arranged at four corners of the bottom of the oxygenerator main body (10), a spring piece (103) is arranged on one side of the oxygenerator main body (10), the spring piece (103) is connected with a handle (1121) in a clamping mode, an air inlet groove (104) is arranged on the oxygenerator main body (10) close to the bottom of the spring piece (103), and an air inlet mechanism (11) is arranged in the air inlet groove (104).