CN110828185A

CN110828185A - Process for batch production of dye-sensitized cells

Info

Publication number: CN110828185A
Application number: CN201911124715.7A
Authority: CN
Inventors: 罗军
Original assignee: Beijing Dinghan Technology Co Ltd
Current assignee: Beijing Dinghan Technology Co Ltd
Priority date: 2019-11-18
Filing date: 2019-11-18
Publication date: 2020-02-21

Abstract

The invention discloses a process for producing dye-sensitized cells in batches, which relates to the technical field of dye-sensitized cells. This batch production dye-sensitized cell's technology, anticlockwise rotation through servo motor one drives the carousel and rotates, thereby rotatory in-process draw-in groove to coincide completely with the breach, thereby make the inside of processing section of thick bamboo transport to the draw-in groove, and continue to rotate, through first the inside of drawing material pump with titanium dioxide thick liquids suction to spouting the material pipe, and spout through the nozzle head, thereby electrode substrate to in the processing section of thick bamboo carries out spraying titanium dioxide, pour into the inside of processing section of thick bamboo with photosensitive dye through two pump pumps, until submerging electrode substrate, thereby obtain the dye-sensitized cell working electrode that has titanium dioxide and photosensitive dye, the production efficiency of the device is improved, and the device is suitable for assembly line batch processing production.

Description

Process for batch production of dye-sensitized cells

Technical Field

The invention relates to the technical field of dye-sensitized cells, in particular to a process for producing dye-sensitized cells in batch.

Background

The dye-sensitized solar cell has a sandwich-like structure, nano titanium dioxide is attached to a substrate, a photosensitive dye is embedded on the surface of the nano titanium dioxide to form a working electrode, a liquid electrolyte containing a redox substance is arranged between the working electrode and a counter electrode (usually conductive glass carrying a catalytic amount of platinum or carbon), the liquid electrolyte is immersed into holes of the nano titanium dioxide and is contacted with the photosensitive dye, the photosensitive dye embedded on the surface of the nano titanium dioxide absorbs photons under the irradiation of incident light and transits to an excited state, electrons are injected into a conduction band of the titanium dioxide, the dye becomes positive ions of an oxidation state, the electrons form a current to the counter electrode through an external circuit, the positive ions of the dye receive electrons of a reducing agent in an electrolyte solution and are reduced to an initial dye, and an oxidizing agent in the electrolyte diffuses to the counter electrode to obtain the electrons so as to regenerate the reducing agent, forming a complete cycle, wherein the apparent chemical substances are not changed in the whole process, and the light energy is converted into the electric energy, and the spraying processing equipment is usually used in the processing of the working electrode of the dye-sensitized solar cell.

The dye-sensitized cell working electrode processing equipment is generally manually coated with nano titanium dioxide on a substrate in the using process, and then the substrate is soaked and embedded with photosensitive dye, but in the using process, the automation effect is poor, a large amount of manual work is needed on a production line to coat and dye the substrate and operate the substrate, and the production line is low in batch production efficiency.

Disclosure of Invention

The invention aims to provide a process for producing dye-sensitized cells in batches, which has the advantage of high production efficiency of an assembly line in batches and solves the problem of low production efficiency of a working electrode processing device of the dye-sensitized cells in batches.

In order to solve the technical problems, the invention provides the following technical scheme: the process for producing the dye-sensitized cells in batches comprises a base, wherein a conveying mechanism is arranged above and on the right side of the base, and a processing mechanism is arranged on the rear and on the left side of the base.

Conveying mechanism includes annular ring, recess, transmission and carousel device, annular ring fixed mounting is at the upper surface of base, and the right side of annular ring and the place ahead all set up jaggedly, and the upper portion at the base right flank is seted up to the recess, and transmission places in the inside of recess, and the carousel device is placed at the upper surface of base, and the carousel device is located the inside of annular ring.

The transmission device comprises a low-speed motor, a fixing plate, a conveying belt, a side baffle and a processing barrel, the turntable device comprises a servo motor I, a turntable, an output groove, an output belt and a clamping groove, the processing mechanism comprises a material spraying device and a material pumping device, the material spraying device comprises a fixing seat I, a material spraying pipe, a first expansion piece, a first mounting plate I, a servo motor II and a material pumping pump I, and the material pumping mechanism comprises a material filling pipe, a material pumping pump II, a mounting plate II, a second expansion piece and a fixing seat II.

Further, fixed plate fixed mounting is in the lower part of base right flank, and the upper surface of fixed plate passes through two mounts and conveyer belt fixed connection, and the left end of conveyer belt extends to the inside of recess, and low-speed motor fixed mounting is in the left side of fixed plate upper surface, and the output of low-speed motor passes through the drive belt and is connected with the conveyer belt transmission, and a side that two side shields kept away from each other all passes through link and conveyer belt fixed mounting, and the upper surface at the conveyer belt is placed to the processing section of thick bamboo.

Further, the carousel is placed in the inside of annular circle, and the surface of carousel bottom contacts with the inner circle of annular circle, and a servo motor fixed mounting is in the center department of carousel, and the output of servo motor is connected with the last fixed surface of base, and the draw-in groove is the edge of seting up at the carousel of annular array.

Further, a fixing base fixed mounting is at the back of base, and a first expansion bend fixed mounting is at the upper surface of fixing base, and a mounting panel fixed mounting is at the output of expansion bend, and two fixed mounting of servo motor are at the upper surface of mounting panel one, spout the material pipe and place the below at mounting panel one, and the output of servo motor two and the top fixed connection who spouts the material pipe, a material pump fixed mounting is at the upper surface of mounting panel one, and the output of material pump one is linked together through hose and spout the material pipe, and the external surface fixed intercommunication that spouts the material pipe has two sets of symmetrical material heads that spout.

Further, two fixed mounting of fixing base are at the left surface of base, and two fixed mounting of expansion bend are at the upper surface of fixing base two, and two fixed mounting of mounting panel are at the flexible end of expansion bend two, and two fixed mounting of pump are at the upper surface of mounting panel two, and the output of pump two passes through the hose and feeds through with the irrigation pipe is fixed.

Furthermore, the diameter value of the clamping groove is equal to that of the processing cylinder, and the diameter value of the notch of the annular ring is equal to that of the clamping groove.

Furthermore, the output groove is formed in the upper side of the front face of the base, the output groove clamping grooves are communicated, and the output belt is fixedly installed in the output groove.

Furthermore, the inner bottom wall of each processing barrel is fixedly connected with a hexagonal frustum, and the diameter value of the hexagonal frustum is smaller than that of the inner ring of the processing barrel.

Furthermore, the diameter value of the material spraying pipe is smaller than that of the inner ring of the processing cylinder, and the horizontal length value between the ends, far away from each other, of the two groups of material spraying heads is smaller than that of the hexagonal frustum pyramid.

Furthermore, the upper surface of conveyer belt and the upper surface of base are located same horizontal plane, and the equal fixed mounting in bottom surface of mounting panel one and mounting panel two has infrared emitter, the fixed surface of carousel inlays and has the infrared inductor of whole circle.

Compared with the prior art, the process for mass production of the dye-sensitized solar cells has the following beneficial effects:

1. according to the invention, the base is arranged, the annular ring, the groove, the low-speed motor, the fixing plate, the conveying belt, the side baffle, the processing cylinder, the first servo motor, the turntable, the output groove, the output belt and the clamping groove are matched for use, the electrode substrate can be placed in the processing cylinder in the processing process, clamped between the hexagonal frustum and the inner ring of the processing cylinder and guided into the conveying belt to be conveyed to the left side into the notch of the annular ring, the turntable is driven to rotate through the anticlockwise rotation of the first servo motor, so that the clamping groove rotates to be completely overlapped with the notch in the rotating process, the processing cylinder is conveyed into the clamping groove and continues to rotate, and the motor substrate in the processing cylinder is subjected to step-by-step assembly line batch processing.

2. The invention uses the first fixing seat, the spraying pipe, the first expansion piece, the first mounting plate, the second servo motor, the first pumping pump, the filling pipe, the second pumping pump, the second mounting plate, the second expansion piece and the second fixing seat in a matching way by arranging the base, when the processing cylinder is rotated to be right below the spraying pipe by the turntable, the spraying pipe is drawn into the processing cylinder by the retraction of the first expansion piece, titanium dioxide slurry is pumped into the spraying pipe by the first pumping pump, and is sprayed out by the spraying head, so that titanium dioxide is sprayed on an electrode substrate in the processing cylinder, the spraying pipe is driven by the rotation of the second servo motor to spray the substrate in the processing cylinder, so that the spraying is more uniform, the spraying pipe is drawn out of the processing cylinder by the extension of the first expansion piece, and the sprayed processing cylinder is conducted to a next fixed point position by the continuous rotation of the first servo motor, until conducting to the below of irritating the material pipe, draw in the inside of processing section of thick bamboo with irritating the material pipe through the retraction of expansion bend two, and pour into the inside of processing section of thick bamboo with photosensitive dye through pump two, until submerging the electrode substrate, thereby accomplish processing, and pass through output tape conduction department the device with the processing section of thick bamboo, and the processing section of thick bamboo that will be processed stew, after the certain time of stewing, pour out titanium dioxide thick liquids and photosensitive dye, take out when no raffinate on the electrode substrate, thereby obtain the dye-sensitized cell working electrode that has titanium dioxide and photosensitive dye, the production efficiency of the device is improved, and the device is suitable for assembly line batch processing production.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a top view of the base of the present invention;

FIG. 3 is a block diagram of a control system of the present invention.

In the figure: 1-a base, 2-a conveying mechanism, 21-an annular ring, 22-a groove, 23-a transmission device, 231-a transmission belt, 232-a low-speed motor, 233-a connecting frame, 234-a fixing frame, 235-a fixing plate, 236-a conveying belt, 237-a side baffle, 238-a processing cylinder, 24-a turntable device, 241-a first servo motor, 242-a turntable, 243-an output groove, 244-an output belt, 245-a clamping groove, 3-a processing mechanism, 31-a material spraying device, 311-a fixing seat, 312-a material spraying pipe, 313-a first expansion device, 314-a second servo motor, 315-a material spraying head, 316-a first material pumping pump, 317-a first mounting plate, 32-a material filling mechanism, 321-a material filling pipe and 322-a second material pumping pump, 323-mounting plate two, 324-expansion piece two, 325-fixing seat two, 4-infrared inductor, 5-infrared emitter.

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. 1-3, the present invention provides a technical solution: a process for mass production of dye-sensitized cells comprises a base 1, wherein conveying mechanisms 2 are arranged above and on the right side of the base 1, and processing mechanisms 3 are arranged behind and on the left side of the base 1.

Conveying mechanism 2 includes annular ring 21, recess 22, transmission 23 and carousel device 24, and annular ring 21 fixed mounting is on the upper surface of base 1, and the right side of annular ring 21 and the place ahead all set up jaggedly, and recess 22 sets up the upper portion at base 1 right flank, and transmission 23 places the inside at recess 22, and carousel device 24 places the upper surface at base 1, and carousel device 24 is located the inside of annular ring 21.

The transmission device 23 comprises a low-speed motor 232, a fixing plate 235, a conveying belt 236, a side baffle 237 and a processing cylinder 238, the turntable device 24 comprises a first servo motor 241, a turntable 242, an output groove 243, an output belt 244 and a clamping groove 245, the processing mechanism 3 comprises a spraying device 31 and a pouring device 32, the spraying device 31 comprises a first fixing seat 311, a spraying pipe 312, a first expansion piece 313, a first mounting plate 317, a second servo motor 314 and a first pumping pump 316, and the pouring mechanism 32 comprises a pouring pipe 321, a second pumping pump 322, a second mounting plate 323, a second expansion piece 324 and a second fixing seat 325.

The fixed plate 235 is fixedly arranged at the lower part of the right side surface of the base 1, the upper surface of the fixed plate 235 is fixedly connected with the conveying belt 236 through two fixed brackets 234, and the left end of the conveyor belt 236 extends to the inside of the groove 22, the low-speed motor 232 is fixedly installed at the left side of the upper surface of the fixing plate 235, the output end of the low-speed motor 232 is in transmission connection with the conveying belt 236 through the transmission belt 231, the upper surface of the conveying belt 236 and the upper surface of the base 1 are located at the same horizontal plane, the processing cylinder 238 is better conducted into the clamping groove 245, one side surface of the two side baffles 237 which are far away from each other is fixedly installed with the conveying belt 236 through the connecting frame 233, the processing cylinder 238 is placed on the upper surface of the conveying belt 236, the inner bottom wall of each processing cylinder 238 is fixedly connected with a hexagonal frustum 239, and the diameter value of the hexagonal frustum 239 is smaller than that of the inner ring of the processing barrel 238, so that the battery electrode substrate can be clamped between the hexagonal frustum 239 and the inner ring of the processing barrel 238.

The diameter value of the clamping groove 245 is equal to that of the processing cylinder 238, the diameter value of the notch of the annular ring 21 is equal to that of the clamping groove 245, the processing cylinder 238 can be better guided into the clamping groove 245, so that the processing cylinder can be better conveyed, the rotary disc 242 is placed inside the annular ring 21, the outer surface of the bottom end of the rotary disc 242 is in contact with the inner ring of the annular ring 21, the first servo motor 241 is fixedly installed at the center of the rotary disc 242, the output end of the first servo motor 241 is fixedly connected with the upper surface of the base 1, the clamping grooves 245 are arranged at the edge of the rotary disc 242 in an annular array mode, the output grooves 243 are arranged above the front surface of the base 1, the clamping grooves 245 of the output grooves 243 are communicated, the output belt 244 is fixedly installed inside the output grooves 243, and the processing cylinder 238 after production can be better guided out for subsequent.

The diameter value of the spraying pipe 312 is smaller than that of the inner ring of the processing barrel 238, the horizontal length value between the ends, far away from each other, of the two groups of spraying heads 315 is smaller than that of the hexagonal frustum 239, so that the problem of collision and blocking during rotation of the spraying pipe 312 is better avoided, the first fixing seat 311 is fixedly arranged on the back surface of the base 1, the first expansion piece 313 is fixedly arranged on the upper surface of the first fixing seat 311, the first mounting plate 317 is fixedly arranged at the output end of the first expansion piece 313, the second servo motor 314 is fixedly arranged on the upper surface of the first mounting plate 317, the spraying pipe 312 is arranged below the first mounting plate 317, the output end of the second servo motor 314 is fixedly connected with the top end of the material spraying pipe 312, the first material pumping pump 316 is fixedly arranged on the upper surface of the first mounting plate 317, the output end of the first pumping pump 316 is communicated with the material spraying pipe 312 through a hose, and two groups of symmetrical material spraying heads 315 are fixedly communicated with the outer surface of the material spraying pipe 312.

The bottom surface of the first mounting plate 317 and the bottom surface of the second mounting plate 323 are fixedly provided with infrared emitters 5, the upper surface of the turntable 242 is fixedly embedded with a full circle of infrared sensors 4, the operating states of the first servo motor 241, the first expansion piece 313, the second servo motor 314, the first pumping pump 316, the second expansion piece 324 and the second pumping pump 322 are better controlled and processed through the infrared emitters 5 and the infrared sensors 4, the second fixing base 325 is fixedly arranged on the left side surface of the base 1, the second expansion piece 324 is fixedly arranged on the upper surface of the second fixing base 325, the second mounting plate 323 is fixedly arranged at the telescopic end of the second expansion piece 324, the second pumping pump 322 is fixedly arranged on the upper surface of the second mounting plate 323, and the output end of the second pumping pump 322 is fixedly communicated with the filling pipe 321 through a hose.

When the device is used, the electrode substrate is placed in the processing cylinder 238, the central processing unit of the device is connected with a municipal power supply and clamped between the hexagonal frustum 239 and the inner ring of the processing cylinder 238, the central processing unit drives the low-speed motor 232 to rotate continuously to drive the conveying belt 236 to rotate to the left side, so that the processing cylinder 238 is conveyed into the gap of the annular ring 21, the central processing unit controls the first servo motor 241 to rotate at a low speed anticlockwise to drive the turntable 242 to rotate, the clamping groove 245 rotates to be completely overlapped with the gap in the rotating process, so that the processing cylinder 238 is conveyed into the clamping groove 245, the ray of the infrared emitter 5 on the mounting plate I317 is overlapped with the infrared inductor 4, the central processing unit sends an instruction, the infrared emitter 5 enters a countdown state, and the central processing unit controls the first servo motor 241 to stop running, and controlling the telescopic end of the first telescopic device 313 to retract and the pumping pump 316 to pump the titanium dioxide slurry into the material spraying cylinder and controlling the second servo motor 314 to rotate, so that the titanium dioxide slurry is uniformly sprayed on the electrode substrate in the processing cylinder 238, after the spraying is finished, the central processing unit controls the first pumping pump 316 and the second servo motor 314 to power off and stop running, controls the first telescopic device 313 to extend out, pulls the material spraying pipe 312 out of the processing cylinder 238, at the moment, the infrared emitter 5 is powered off and stops emitting, controls the first servo motor 241 to continue to rotate anticlockwise and the infrared emitter 5 to continue running until the infrared emitter 5 is superposed with the next infrared inductor 4, so as to spray the electrode substrate in the next processing cylinder 238, when the telescopic end rotates to the lower part of the material filling pipe 321, the rays of the infrared emitter 5 on the second mounting plate 323 are superposed with the infrared inductor 4, the central processing unit sends an instruction to the central processing unit, the central processing unit controls the second pumping pump 322 and the second expansion piece 324 to operate, the filling pipe 321 is pulled into the processing barrel 238 through retraction of the second expansion piece 324, the photosensitive dye is pumped into the filling pipe 321 through the second pumping pump 322 until the infrared emitter 5 is powered off for next conveying, flow line production is conducted, the processing barrel 238 which rotates to the front is output through operation of the output belt 244, standing processing is conducted on the processing barrel 238 in the follow-up process, after standing for a certain time, the titanium dioxide slurry and the photosensitive dye are poured out, the titanium dioxide slurry and the photosensitive dye are taken out when no residual liquid exists on an electrode substrate, and the dye-sensitized battery working electrode with titanium dioxide and the photosensitive dye is obtained, production efficiency of the device is improved, and the device is suitable for batch processing production of flow lines.

Claims

1. The utility model provides a technology of batch production dye-sensitized cell, includes base (1), conveying mechanism (2), its characterized in that are installed to the top and the right side of base (1): machining mechanisms (3) are arranged at the rear and the left side of the base (1);

the conveying mechanism (2) comprises an annular ring (21), a groove (22), a transmission device (23) and a turntable device (24), the annular ring (21) is fixedly installed on the upper surface of the base (1), gaps are formed in the right side and the front of the annular ring (21), the groove (22) is formed in the upper portion of the right side face of the base (1), the transmission device (23) is placed in the groove (22), the turntable device (24) is placed on the upper surface of the base (1), and the turntable device (24) is located in the annular ring (21);

the processing mechanism is characterized in that the transmission device (23) comprises a low-speed motor (232), a fixing plate (235), a conveying belt (236), a side baffle (237) and a processing cylinder (238), the turntable device (24) comprises a servo motor I (241), a turntable (242), an output groove (243), an output belt (244) and a clamping groove (245), the processing mechanism (3) comprises a spraying device (31) and a material pouring device (32), the spraying device (31) comprises a fixing seat I (311), a spraying pipe (312), a first expansion piece (313), a first mounting plate I (317), a servo motor II (314) and a material pumping pump I (316), and the material pouring mechanism (32) comprises a material pouring pipe (321), a material pumping pump II (322), a second mounting plate (323), a second expansion piece (324) and a fixing seat II (325).

2. The process according to claim 1, wherein the dye-sensitized solar cell is produced in batch by the following steps: the fixed plate (235) is fixedly arranged at the lower part of the right side face of the base (1), the upper surface of the fixed plate (235) is fixedly connected with the conveying belt (236) through two fixed frames (234), the left end of the conveying belt (236) extends to the inside of the groove (22), the low-speed motor (232) is fixedly arranged at the left side of the upper surface of the fixed plate (235), the output end of the low-speed motor (232) is in transmission connection with the conveying belt (236) through a transmission belt (231), one side face, away from each other, of the two side baffles (237) is fixedly arranged with the conveying belt (236) through a connecting frame (233), and the processing barrel (238) is arranged on the upper surface of the conveying belt (236).

3. The process according to claim 1, wherein the dye-sensitized solar cell is produced in batch by the following steps: the carousel (242) are placed in the inside of annular circle (21), and the surface of carousel (242) bottom contacts with the inner circle of annular circle (21), and servo motor (241) fixed mounting is in the center department of carousel (242), and the output of servo motor (241) is connected with the last fixed surface of base (1), and draw-in groove (245) are the edge of seting up in carousel (242) of annular array.

4. The process according to claim 1, wherein the dye-sensitized solar cell is produced in batch by the following steps: the utility model discloses a material spraying device, including base (1), first fixing base (311), expansion bend (313), mounting panel (317), servo motor (316), pump (316), spray pipe (312), and the output of pump (316) is linked together through hose and spray pipe (312), and the outer fixed surface that spouts pipe (312) communicates two sets of symmetrical spray head (315).

5. The process according to claim 1, wherein the dye-sensitized solar cell is produced in batch by the following steps: the second fixing base (325) is fixedly installed on the left side face of the base (1), the second expansion piece (324) is fixedly installed on the upper surface of the second fixing base (325), the second mounting plate (323) is fixedly installed at the telescopic end of the second expansion piece (324), the second pumping pump (322) is fixedly installed on the upper surface of the second mounting plate (323), and the output end of the second pumping pump (322) is fixedly communicated with the material filling pipe (321) through a hose.

6. The process according to claim 1, wherein the dye-sensitized solar cell is produced in batch by the following steps: the diameter value of the clamping groove (245) is equal to that of the processing cylinder (238), and the diameter value of the notch of the annular ring (21) is equal to that of the clamping groove (245).

7. The process according to claim 1, wherein the dye-sensitized solar cell is produced in batch by the following steps: the output groove (243) is formed in the upper portion of the front face of the base (1), the output groove (243) is communicated with the clamping groove (245), and the output belt (244) is fixedly installed in the output groove (243).

8. The process according to claim 1, wherein the dye-sensitized solar cell is produced in batch by the following steps: the inner bottom wall of each processing cylinder (238) is fixedly connected with a hexagonal frustum pyramid (239), and the diameter value of the hexagonal frustum pyramid (239) is smaller than that of the inner ring of the processing cylinder (238).

9. The process according to claim 1, wherein the dye-sensitized solar cell is produced in batch by the following steps: the diameter value of the material spraying pipe (312) is smaller than that of the inner ring of the processing cylinder (238), and the horizontal length value between the ends, far away from each other, of the two groups of material spraying heads (315) is smaller than that of the hexagonal frustum pyramid (239).

10. The process according to claim 1, wherein the dye-sensitized solar cell is produced in batch by the following steps: the upper surface of conveyer belt (236) and the upper surface of base (1) are located same horizontal plane, the equal fixed mounting in bottom surface of the bottom surface of mounting panel one (317) and mounting panel two (323) has infrared emitter (5), the fixed surface of carousel (242) inlays infrared inductor (4) that have the whole circle.