CN114737212B

CN114737212B - Mixed carbon dioxide electrolytic cell

Info

Publication number: CN114737212B
Application number: CN202210620875.6A
Authority: CN
Inventors: 张贤文; 王力; 唐旭; 马英馨; 刘国顺; 马康
Original assignee: Hefei University of Technology
Current assignee: Hefei University of Technology
Priority date: 2022-06-02
Filing date: 2022-06-02
Publication date: 2023-08-11
Anticipated expiration: 2042-06-02
Also published as: CN114737212A

Abstract

The application discloses a mixed carbon dioxide electrolytic cell, which comprises a supporting component, wherein a moving component is arranged below the supporting component, a guiding component is arranged behind the supporting component, a linkage component is arranged behind the moving component, the supporting component comprises a supporting bottom plate, a guiding transverse plate, a pedal and a fulcrum shaft, a central rotating hole is formed in the center of the top end of the supporting bottom plate, the top end of the supporting bottom plate is fixedly connected with a rear vertical plate, a fulcrum hole is formed in the side surface of the rear vertical plate, and the top end of the rear vertical plate is fixedly connected with the bottom end of the guiding transverse plate. According to the application, the pedal is arranged to drive the motion guide assembly to move, the linkage assembly is driven to reciprocate by the transmission of the guide assembly, the linkage assembly drives the turntable to rotate, the turntable drives the cam to rotate in the bottom surface groove to drive the electrolytic cell to reciprocate along the guide transverse plate, the electrolytic solution in the electrolytic cell is driven to be fully mixed, the electrolytic cell is driven to move in a labor-saving mode, and the stirring type mixing is replaced, so that the corrosion risk is avoided.

Description

Mixed carbon dioxide electrolytic cell

Technical Field

The application belongs to the field of electrochemistry, and particularly relates to a mixed carbon dioxide electrolytic cell.

Background

The electrocatalytic reduction conversion of carbon dioxide into useful fuels and chemicals by using renewable energy under mild and controllable conditions is an important front edge of energy chemistry, and has wide application prospect; the key challenge is to develop an electrocatalyst for high-performance carbon dioxide reduction reaction (CO 2 RR) and a device for realizing the electrocatalyst reaction, thereby improving the yield of target products and realizing high selectivity. The cell design is one of the very important experimental facilities in electrocatalyst reactions.

The solution in the electrolytic cell may have higher density and low fluidity, and insufficient mixing may exist when the electrolytic solution is just put into the electrolytic cell, so that the electrolytic cell is heavy and is inconvenient to shake, the solution is easy to spill in a stirring manner, the electrolytic solution is corrosive, and potential safety hazards may be caused. We have therefore made improvements to this and have proposed a hybrid carbon dioxide cell.

Disclosure of Invention

The application aims to overcome the problems in the prior art and provide a mixed carbon dioxide electrolytic cell, wherein a pedal is arranged to drive a motion guide assembly to move, a linkage assembly is driven to reciprocate under the transmission of the guide assembly, the linkage assembly drives a rotary table to rotate, the rotary table drives a cam to rotate in a bottom groove to drive an electrolytic cell to reciprocate along a guide transverse plate, electrolyte in the electrolytic cell is driven to be fully mixed, the electrolytic cell is driven to move in a labor-saving mode, and the stirring type mixing is replaced, so that the corrosion risk is avoided.

In order to achieve the technical purpose and the technical effect, the application is realized by the following technical scheme:

the mixed carbon dioxide electrolytic cell comprises a supporting component, wherein a moving component is arranged below the supporting component, a guiding component is arranged behind the supporting component, and a linkage component is arranged behind the moving component;

the supporting component comprises a supporting bottom plate, a guide transverse plate, a pedal and a fulcrum shaft, wherein a central rotating hole is formed in the center of the top end of the supporting bottom plate, a rear vertical plate is fixedly connected to the top end of the supporting bottom plate, a fulcrum hole is formed in the side face of the rear vertical plate, the top end of the rear vertical plate is fixedly connected with the bottom end of the guide transverse plate, the top end of the supporting bottom plate is fixedly connected with a front vertical plate which is positioned in front of the rear vertical plate, the top end of the front vertical plate is fixedly connected with the bottom end of the guide transverse plate, swinging rods are symmetrically and fixedly connected to the two sides of the pedal, a positioning rotating hole is formed in the middle of each swinging rod, a driving groove is formed in one end, far away from the pedal, of each swinging rod is inserted into the fulcrum hole to be fixedly connected with the rear vertical plate, and the other end of each fulcrum shaft is inserted into the positioning rotating hole to be in rotary connection with the swinging rods;

the motion assembly comprises an electrolytic cell, a cam and a rotary table, wherein side sliding grooves are formed in two sides of the electrolytic cell, a bottom surface groove is formed in the bottom end of the electrolytic cell, the outer peripheral side of the cam is contacted with the inner peripheral side of the bottom surface groove, a wheel hole is formed in the bottom end of the cam, an inner groove is formed in the peripheral side of the rotary table, an ejector rod fixedly connected with the wheel hole is fixedly connected to the top end of the rotary table, and a bottom rod is fixedly connected to the bottom end of the rotary table;

the guide assembly comprises a vertical sliding block, symmetrically arranged guide seats and a fixed rod, wherein an inclined sliding groove is formed in the front of the vertical sliding block, side sliding plates are fixedly connected to two sides of the vertical sliding block, vertical holes are formed in the top ends of the side sliding plates, lengthened plates are fixedly connected to the bottom ends of the side sliding plates, driving shafts are fixedly connected to the outer sides of the lengthened plates, inner sliding grooves which are in sliding connection with the vertical sliding blocks are formed in the inner sides of the guide seats, outer sliding grooves which are in sliding connection with the side sliding plates are formed in the outer sides of the guide seats, fixing holes are formed in the upper end and the lower end of the outer sliding grooves, clamping grooves are formed in the front of the guide seats, the two ends of the fixing rods are inserted into the fixing holes and are fixedly connected with the guide seats, the fixing rods penetrate through the vertical holes and are in sliding connection with the side sliding plates, and first springs are movably sleeved on the periphery of the fixing rods;

the linkage assembly comprises a horizontal seat, a horizontal sliding block and an inclined surface block, wherein a horizontal sliding groove which is in sliding fit with the horizontal sliding block is formed in the front of the horizontal seat, a through groove is formed in the rear of the horizontal seat, a linkage rod which is in sliding fit with the through groove is fixedly connected to the rear of the horizontal sliding block, a reset hole is formed in the front of the horizontal sliding block, an inserted link which is in sliding connection with the reset hole is fixedly connected to the rear of the inclined surface block, and a second spring is movably sleeved on the periphery of the inserted link.

Further, the guide cross plate is in sliding connection with the electrolytic cell through the side sliding groove, and the bottom end of the bottom rod is inserted into the central rotating hole to be in rotary connection with the supporting bottom plate.

Further, the front of the guide seat is fixedly connected with the rear of the supporting bottom plate, and the driving shaft is in sliding connection with the swinging rod through the driving groove.

Further, the top end of the first spring is in contact connection with the guide seat, and the bottom end of the first spring is in contact connection with the side sliding plate.

Further, the inclined surface block is fixedly clamped with the guide seat through the clamping groove, the linkage rod is in sliding connection with the vertical sliding block through the inclined sliding groove, and the inclined surface block is positioned in the inner groove.

Further, one end of the second spring is in contact connection with the inclined surface block, and the other end of the second spring is in contact connection with the horizontal sliding block.

The beneficial effects of the application are as follows: this kind of mixed carbon dioxide electrolytic cell drives motion direction subassembly motion through being provided with trampling, drives linkage subassembly reciprocating motion under the direction subassembly transmission, and linkage subassembly drive carousel rotates, and the carousel drives the cam and rotates in the bottom surface groove and drive electrolytic cell along direction diaphragm round trip movement, drives electrolyte intensive mixing in the electrolytic cell, drives electrolytic cell motion with laborsaving mode, has also replaced stirring formula to mix, has avoided the corruption risk.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute a limitation on the application. In the drawings:

FIG. 1 is a schematic diagram of the structure of the present application;

FIG. 2 is a schematic view of a partial structure of the present application;

FIG. 3 is an exploded view of a partial structure of the present application;

FIG. 4 is an exploded view of a partial structure of the present application;

FIG. 5 is an exploded view of a partial structure of the present application;

fig. 6 is an exploded view of a partial structure of the present application.

In the figure: 1. a support assembly; 11. a support base plate; 111. a central turning hole; 12. a rear vertical plate; 121. a fulcrum hole; 13. a front vertical plate; 14. a guide cross plate; 15. stepping on the pedal; 16. a swinging rod; 161. positioning a rotating hole; 162. a driving groove; 17. a fulcrum shaft; 2. a motion assembly; 21. an electrolytic cell; 211. a side chute; 212. a bottom surface groove; 22. a cam; 221. wheel holes; 23. a turntable; 231. an inner groove; 24. a push rod; 25. a bottom bar; 3. a guide assembly; 31. a vertical sliding block; 311. tilting the chute; 32. a side slide plate; 321. a vertical hole; 33. a lengthening plate; 331. a driving shaft; 34. a guide seat; 341. an inner chute; 342. an outer chute; 343. a fixing hole; 344. a clamping groove; 35. a fixed rod; 36. a first spring; 4. a linkage assembly; 41. a horizontal seat; 411. a horizontal chute; 412. a pass through slot; 42. a horizontal slider; 421. a reset hole; 43. a linkage rod; 44. a bevel block; 441. a rod; 45. and a second spring.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

In the description of the present application, it should be understood that the terms "open," "upper," "lower," "thickness," "top," "middle," "length," "inner," "peripheral," and the like indicate orientation or positional relationships, merely for convenience in describing the present application and to simplify the description, and do not indicate or imply that the components or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present application.

The mixed carbon dioxide electrolytic cell shown in fig. 1 and 2 comprises a support component 1, wherein a motion component 2 is arranged below the support component 1, a guide component 3 is arranged behind the support component 1, and a linkage component 4 is arranged behind the motion component 2.

As shown in fig. 3, the support assembly 1 includes a support bottom plate 11, a guide cross plate 14, a pedal 15, and a pivot shaft 17, a central rotation hole 111 is formed in the center of the top end of the support bottom plate 11, a rear vertical plate 12 is fixedly connected to the top end of the support bottom plate 11, a pivot hole 121 is formed in the side surface of the rear vertical plate 12, the top end of the rear vertical plate 12 is fixedly connected to the bottom end of the guide cross plate 14, a front vertical plate 13 is fixedly connected to the top end of the support bottom plate 11, the top end of the front vertical plate 13 is fixedly connected to the bottom end of the guide cross plate 14, swing rods 16 are symmetrically and fixedly connected to both sides of the pedal 15, a positioning rotation hole 161 is formed in the middle of the swing rod 16, a driving groove 162 is formed in one end of the swing rod 16 away from the pedal 15, one end of the pivot shaft 17 is inserted into the pivot hole 121 and fixedly connected to the rear vertical plate 12, the other end of the pivot shaft 17 is inserted into the positioning rotation hole 161 and is rotationally connected to the swing rod 16, the guide cross plate 14 is slidably connected to the electrolytic cell 21 through a side chute 211, and the bottom end of the bottom rod 25 is inserted into the central rotation hole 111 and is rotationally connected to the support bottom plate 11.

As shown in fig. 4, the moving assembly 2 comprises an electrolytic cell 21, a cam 22 and a turntable 23, wherein side sliding grooves 211 are formed in two sides of the electrolytic cell 21, a bottom surface groove 212 is formed in the bottom end of the electrolytic cell 21, the outer peripheral side of the cam 22 is contacted with the inner peripheral side of the bottom surface groove 212, a wheel hole 221 is formed in the bottom end of the cam 22, an inner groove 231 is formed in the peripheral side of the turntable 23, a top rod 24 fixedly connected with the wheel hole 221 is fixedly connected to the top end of the turntable 23, and a bottom rod 25 is fixedly connected to the bottom end of the turntable 23.

As shown in fig. 5, the guide assembly 3 includes a vertical sliding block 31, a symmetrically arranged guide seat 34, and a fixing rod 35, wherein the front of the vertical sliding block 31 is provided with an inclined sliding slot 311, two sides of the vertical sliding block 31 are fixedly connected with a side sliding plate 32, the top of the side sliding plate 32 is provided with a vertical hole 321, the bottom of the side sliding plate 32 is fixedly connected with an extension plate 33, the outer side of the extension plate 33 is fixedly connected with a driving shaft 331, the inner side of the guide seat 34 is provided with an inner sliding slot 341 slidably connected with the vertical sliding block 31, the outer side of the guide seat 34 is provided with an outer sliding slot 342 slidably connected with the side sliding plate 32, the upper and lower ends of the outer sliding slot 342 are provided with fixing holes 343, the front of the guide seat 34 is provided with a clamping slot 344, the two ends of the fixing rod 35 are inserted into the fixing holes 343 and fixedly connected with the guide seat 34, the fixing rod 35 passes through the vertical hole 321 and is slidably connected with the side sliding plate 32, the circumference of the fixing rod 35 is movably sleeved with a first spring 36, the front of the guide seat 34 is fixedly connected with the back of the support bottom 11, the driving shaft 331 is slidably connected with the swing rod 16 through a driving slot 162, the top of the driving shaft 331 is in contact connection with the guide seat 34, and the bottom of the first spring 36 is in contact with the guide seat 34.

As shown in fig. 6, the linkage assembly 4 includes a horizontal seat 41, a horizontal sliding block 42, and an inclined surface block 44, a horizontal sliding groove 411 slidably engaged with the horizontal sliding block 42 is provided in front of the horizontal seat 41, a through groove 412 is provided in back of the horizontal seat 41, a linkage rod 43 slidably engaged with the through groove 412 is fixedly connected to back of the horizontal sliding block 42, a reset hole 421 is provided in front of the horizontal sliding block 42, an insert rod 441 slidably engaged with the reset hole 421 is fixedly connected to back of the inclined surface block 44, a second spring 45 is movably sleeved on a peripheral side of the insert rod 441, the inclined surface block 44 is fixedly engaged with the guide seat 34 through a clamping groove 344, the linkage rod 43 is slidably engaged with the vertical sliding block 31 through the inclined sliding groove 311, the inclined surface block 44 is located in the inner groove 231, one end of the second spring 45 is in contact connection with the inclined surface block 44, and the other end of the second spring 45 is in contact connection with the horizontal sliding block 42.

In the application, the sole of a foot is stepped on a pedal 15 and moves downwards, a swinging rod 16 swings, one end of the swinging rod 16 close to a driving groove 162 is tilted, the driving groove 162 is in sliding connection with a driving shaft 331 to drive the driving shaft 331 to move upwards, the driving shaft 331 drives a vertical sliding block 31 to move upwards vertically in the direction of a sliding groove 341 in smoke through an extension plate 33 and a side sliding plate 32, an inclined sliding groove 311 is in sliding connection with a linkage rod 43 to drive the linkage rod 43 to move horizontally through a groove 412, the linkage rod 43 drives the linkage rod 43 to move horizontally, the horizontal sliding block 42 drives a bevel block 44 to move horizontally through an inserting rod 441, the straight surface of the bevel block 44 contacts with the inner side surface of an inner groove 231 to drive a rotary disc 23 to rotate, the rotary disc 23 drives a cam 22 to rotate through a push rod 24 to leave the pedal 15, a first spring 36 drives the side sliding plate 32 to move downwards, the bevel block 44 contacts with the rotary disc 23 and drives the bevel block 44 to move towards the horizontal sliding block 42, when moving to the next inner groove 231, the bevel block 44 is in elastic force of a second spring 45 acts on the bevel block 44 to reset to insert into the next inner groove 231, thus reciprocating cam 22 rotates in the bottom surface 212 to drive the electrolytic cell to move horizontally along the direction of the electrolytic cell 21 to move along the side 21 along the direction of the reciprocating direction.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, 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 present application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. 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 foregoing has shown and described the basic principles, principal features and advantages of the application. It will be understood by those skilled in the art that the present application is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present application, and various changes and modifications may be made without departing from the spirit and scope of the application, which is defined in the appended claims.

Claims

1. The mixed carbon dioxide electrolytic cell is characterized by comprising a supporting component (1), wherein a moving component (2) is arranged below the supporting component (1), a guiding component (3) is arranged behind the supporting component (1), and a linkage component (4) is arranged behind the moving component (2);

the supporting assembly (1) comprises a supporting bottom plate (11), a guide transverse plate (14), a pedal plate (15) and a fulcrum shaft (17), wherein a center rotating hole (111) is formed in the center of the top end of the supporting bottom plate (11), a rear vertical plate (12) is fixedly connected to the top end of the supporting bottom plate (11), a fulcrum hole (121) is formed in the side face of the rear vertical plate (12), the top end of the rear vertical plate (12) is fixedly connected with the bottom end of the guide transverse plate (14), the top end of the supporting bottom plate (11) is fixedly connected with a front vertical plate (13) in front of the rear vertical plate (12), the top end of the front vertical plate (13) is fixedly connected with the bottom end of the guide transverse plate (14), swinging rods (16) are symmetrically and fixedly connected on two sides of the pedal plate (15), a positioning rotating hole (161) is formed in the middle of each swinging rod (16), a driving groove (162) is formed in one end, far away from the pedal plate (15), one end of the fulcrum shaft (17) is inserted into the fulcrum hole (121) to be fixedly connected with the rear vertical plate (12), and the other end of the fulcrum shaft (17) is inserted into the positioning rotating hole (161) to be rotationally connected with the swinging rods (16).

The motion assembly (2) comprises an electrolytic cell (21), a cam (22) and a rotary table (23), wherein side sliding grooves (211) are formed in two sides of the electrolytic cell (21), a bottom surface groove (212) is formed in the bottom end of the electrolytic cell (21), the outer peripheral side of the cam (22) is contacted with the inner peripheral side of the bottom surface groove (212), a wheel hole (221) is formed in the bottom end of the cam (22), an inner groove (231) is formed in the peripheral side of the rotary table (23), a top rod (24) fixedly connected with the wheel hole (221) is fixedly connected to the top end of the rotary table (23), and a bottom rod (25) is fixedly connected to the bottom end of the rotary table (23);

the guide assembly (3) comprises a vertical sliding block (31), symmetrically arranged guide seats (34) and fixing rods (35), wherein inclined sliding grooves (311) are formed in the front of the vertical sliding block (31), side sliding plates (32) are fixedly connected to the two sides of the vertical sliding block (31), vertical holes (321) are formed in the top ends of the side sliding plates (32), lengthened plates (33) are fixedly connected to the bottom ends of the side sliding plates (32), driving shafts (331) are fixedly connected to the outer sides of the lengthened plates (33), inner sliding grooves (341) which are in sliding connection with the vertical sliding block (31) are formed in the inner sides of the guide seats (34), outer sliding grooves (342) which are in sliding connection with the side sliding plates (32) are formed in the outer sides of the guide seats (34), fixing holes (343) are formed in the upper ends and the lower ends of the outer sliding grooves (342), clamping grooves (344) are formed in the front of the guide seats (34), the two ends of each fixing rod (35) are inserted into the fixing holes (343) to be fixedly connected with the guide seats (34), the fixing rods (35) penetrate through the vertical holes (321) to be in sliding connection with the side sliding plates (32), and the circumference sides of the fixing rods (35) are movably sleeved with first springs (36);

the linkage assembly (4) comprises a horizontal seat (41), a horizontal sliding block (42) and an inclined surface block (44), a horizontal sliding groove (411) which is in sliding fit with the horizontal sliding block (42) is formed in the front of the horizontal seat (41), a through groove (412) is formed in the rear of the horizontal seat (41), a linkage rod (43) which is in sliding fit with the through groove (412) is fixedly connected to the rear of the horizontal sliding block (42), a reset hole (421) is formed in the front of the horizontal sliding block (42), a inserted link (441) which is in sliding connection with the reset hole (421) is fixedly connected to the rear of the inclined surface block (44), and a second spring (45) is movably sleeved on the periphery of the inserted link (441);

the front of the guide seat (34) is fixedly connected with the rear of the supporting bottom plate (11), and the driving shaft (331) is in sliding connection with the swinging rod (16) through the driving groove (162);

the top end of the first spring (36) is in contact connection with the guide seat (34), and the bottom end of the first spring (36) is in contact connection with the side sliding plate (32);

the inclined surface block (44) is fixedly clamped with the guide seat (34) through the clamping groove (344), the linkage rod (43) is in sliding connection with the vertical sliding block (31) through the inclined sliding groove (311), and the inclined surface block (44) is located in the inner groove (231).

2. A mixed carbon dioxide electrolytic cell according to claim 1, characterized in that the guide cross plate (14) is slidably connected with the electrolytic cell (21) through a side chute (211), and the bottom end of the bottom rod (25) is inserted into the central rotary hole (111) and is rotatably connected with the supporting bottom plate (11).

3. A mixed carbon dioxide electrolytic cell according to claim 1, characterized in that one end of the second spring (45) is in contact connection with the ramp block (44), and the other end of the second spring (45) is in contact connection with the horizontal slider (42).