CN113089012A - Electrolytic cell capable of reducing energy consumption based on cell control system - Google Patents

Abstract

The invention discloses an electrolytic cell capable of reducing energy consumption based on a cell control system, which comprises a base frame, a workbench and an electrolytic cell mechanism, wherein a PLC (programmable logic controller) is installed on one side of the workbench, and the electrolytic cell mechanism comprises a first electrolytic shell, two alkali liquor water pumps, two salt liquor water pumps, an ion exchange membrane, an anode plate, a second electrolytic shell, four cathode plates, four machine frames and eight ball screws. According to the invention, the vertical angle of the cathode plate is adjusted through the gear train consisting of the worm wheel and the worm, and the distance adjustment is realized through the matching of eight groups of ball screws and the device such as the rack and the connecting block, so that the adjustability of the distance between two poles is realized in the actual production process, the self-adaptive adjustment can be realized according to different actual production requirements, and meanwhile, the oxidation effect of hypochlorite ions on the surface of the cathode or the anode is relieved, thereby improving the current efficiency in the electrolytic process and effectively reducing the energy consumption.

Description

Electrolytic cell capable of reducing energy consumption based on cell control system

The technical field is as follows:

the invention relates to the technical field of electrolytic cells, in particular to an electrolytic cell capable of reducing energy consumption based on a cell control system.

Background art:

the electrolytic cell consists of a cell body, an anode and a cathode, and an anode chamber and a cathode chamber are mostly separated by a diaphragm. When direct current passes through the electrolytic cell, oxidation reaction occurs at the interface of the anode and the solution, and reduction reaction occurs at the interface of the cathode and the solution, so as to prepare a required product;

the distance between the cathode and the anode is one of important factors influencing the voltage of the cell, and as the distance between the two electrodes is increased, the ohmic voltage drop in the cell is increased, the voltage of the cell is increased, and particularly when a large current works, the voltage loss is more serious; meanwhile, the residence time of the electrolyte in the electrolytic cell not only affects the production capacity of the equipment, but also affects the current efficiency of the electrolytic process under certain conditions, such as sodium chlorate production by electrolysis, because the chemical reaction speed between the intermediate product hypochlorous acid (HClO) and hypochlorite ions (ClO3) is very slow, such as long-time retention in the electrolytic cell, the utilization rate of the electrolytic cell is reduced, and the hypochlorite ions are oxidized on the surface of the anode or reduced on the surface of the cathode, the current efficiency is reduced and unnecessary energy consumption is increased;

therefore, how to reasonably design the anode and the cathode and regulate and control related mechanisms to enable the electrolyte to flow through the electrodes quickly is the best choice for solving the problems of low utilization rate and high energy consumption.

Therefore, the electrolytic cell based on the cell control system for reducing the energy consumption is provided.

The invention content is as follows:

the invention aims to provide an electrolytic cell for reducing energy consumption based on a cell control system, so as to solve the problems in the background technology.

The invention is implemented by the following technical scheme: an electrolytic cell capable of reducing energy consumption based on a cell control system comprises a base frame, a workbench and an electrolytic cell mechanism, wherein a PLC (programmable logic controller) is installed on one side of the workbench, the electrolytic cell mechanism comprises a first electrolytic shell, two alkali liquor water pumps, two salt liquor water pumps, an ion exchange membrane, an anode plate, a second electrolytic shell, four cathode plates, four machine frames, eight ball screws, four connecting rollers, four worm gears, four worms, four first stepping motors and eight second stepping motors, the two alkali liquor water pumps are respectively installed on the upper surface and the lower surface of the first electrolytic shell, the two salt liquor water pumps are respectively installed on the upper surface and the lower surface of the first electrolytic shell, the outer surface of the ion exchange membrane is fixedly connected to the inner side wall of the first electrolytic shell, the outer surface of the anode plate is fixedly connected to the front inner side wall of the first electrolytic shell, the outer surface of the second electrolytic shell is connected with the inner side wall of the first electrolytic shell in a sliding mode, the inner side wall of the rack is rotatably connected with the outer surface of the connecting roller through a bearing, the outer surface of the connecting roller is welded with the worm, gear teeth of the worm are meshed with gear teeth of the worm wheel, two hinge brackets are welded on the rear surface of the cathode plate, a gear shaft of the worm wheel is welded with the inner side walls of the hinge brackets, two connecting blocks are symmetrically welded on two side surfaces of the rack, the inner side walls of the connecting blocks are welded with a moving nut of the ball screw, an output shaft of the first stepping motor is welded with the connecting roller, and an output shaft of the second stepping motor is welded with a threaded rod of the ball screw;

the upper surface of the base frame is symmetrically welded with two connecting frames, the outer surfaces of the connecting frames are connected with a fixed frame through bolt threads, the rear surface of the fixed frame is provided with a hydraulic cylinder, a piston rod of the hydraulic cylinder is fixedly connected with a supporting frame, two protective plates are symmetrically welded on two side surfaces of the connecting frames, and the upper surface of the connecting frame is welded with a top plate;

and the electrical output end of the PLC is electrically connected with the electrical input ends of the alkali liquor water pump, the salt liquor water pump, the first stepping motor, the second stepping motor and the hydraulic cylinder.

As further preferable in the present technical solution: the electrolytic cell comprises a first electrolytic shell, a second electrolytic shell and a third electrolytic shell, wherein the first electrolytic shell is provided with an inner side wall and an outer side wall, the inner side wall of the first electrolytic shell is integrally formed with four flanges, the outer surface of the second electrolytic shell is provided with four concave grooves, and the inner side wall of each concave groove is in sliding connection with the outer surfaces of the flanges.

As further preferable in the present technical solution: the inner side wall of the first electrolysis shell is welded with four sealing flanges, the inner side wall of one sealing flange is communicated with a water inlet of one alkali liquor pump, and the inner side wall of the other sealing flange is communicated with a water outlet of the other alkali liquor pump; the inner side wall of the other sealing flange is communicated with the water inlet of one salt solution water pump, and the inner side wall of the other sealing flange is communicated with the water outlet of the other salt solution water pump.

As further preferable in the present technical solution: the front surface welding of frame has two backup pads, the inside wall of backup pad pass through the bearing with the gear shaft of worm wheel is rotated and is connected.

As further preferable in the present technical solution: the rear surface symmetry integrated into one piece of negative plate has two spouts, the inside wall of spout with ball screw's threaded rod sliding connection.

As further preferable in the present technical solution: the inside wall welding of second electrolysis casing has the division board, the surface of division board with the surface looks adaptation of negative plate.

As further preferable in the present technical solution: the front surface of the second stepping motor is in threaded connection with the rear surface of the support frame through a bolt, and the front surface of the first stepping motor is in threaded connection with the rear surface of the support frame through a bolt.

As further preferable in the present technical solution: two clamping plates are symmetrically connected to two side faces of the supporting frame through bolts in a threaded mode, the outer surfaces of the clamping plates are connected with the outer surface of the connecting frame in a sliding mode, the two side faces of the supporting frame are rotatably connected with the inner side walls of the four idler wheels through bearings, and the outer surfaces of the idler wheels are attached to the upper surface of the connecting frame. .

The invention has the advantages that:

1. according to the invention, the vertical angle of the cathode plate is adjusted through the gear train consisting of the worm wheel and the worm, and the distance adjustment is realized through the matching of eight groups of ball screws and the device such as the rack and the connecting block, so that the adjustability of the distance between two poles is realized in the actual production process, the self-adaptive adjustment can be realized according to different actual production requirements, and meanwhile, the oxidation effect of hypochlorite ions on the surface of the cathode or the anode is relieved, thereby improving the current efficiency in the electrolytic process and effectively reducing the energy consumption.

2. The invention uses the electrolytic cell mechanism to match with the filter press device composed of the base frame, the support frame and the connecting frame, and the like, and uses the diaphragm electrolytic cell to match with the ion membrane method to greatly improve the production efficiency and the practicability.

Description of the drawings:

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

FIG. 1 is a schematic view of a perspective structure according to the present invention;

FIG. 2 is a schematic perspective view of another embodiment of the present invention;

FIG. 3 is a schematic perspective view of the electrolyzer mechanism of the invention;

FIG. 4 is a schematic perspective view of a first electrolytic case according to the present invention;

FIG. 5 is a schematic perspective view of an anode plate according to the present invention;

FIG. 6 is a perspective view of a second electrolytic case according to the present invention;

FIG. 7 is a schematic perspective view of a cathode plate according to the present invention;

fig. 8 is a schematic perspective view of the ball screw according to the present invention.

FIG. 9 is a perspective view of the worm gear of the present invention;

FIG. 10 is a wiring diagram of a PLC controller of the present invention;

fig. 11 is an electrical control schematic of the present invention.

In the figure: 1. a base frame; 2. a work table; 3. a PLC controller; 4. an electrolyzer mechanism; 401. a first electrolytic housing; 4011. a flange; 4012. sealing the flange; 402. an alkali liquor pump; 403. a salt solution water pump; 404. an ion exchange membrane; 405. an anode plate; 406. a second electrolytic case; 4061. a recess groove; 407. a cathode plate; 4071. a chute; 4072. hinging frame; 408. a frame; 4081. connecting blocks; 409. a ball screw; 410. connecting rollers; 411. a support plate; 412. a worm gear; 413. a worm; 414. a first stepper motor; 415. a second stepping motor; 416. a partition plate; 5. a support frame; 501. clamping a plate; 502. a roller; 6. a hydraulic cylinder; 7. a connecting frame; 8. a fixed mount; 9. a guard plate; 10. a top plate.

The specific implementation mode is as follows:

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.

Examples

Referring to fig. 1-11, the present invention provides a technical solution: an electrolytic cell for reducing energy consumption based on a cell control system comprises a base frame 1, a workbench 2 and an electrolytic cell mechanism 4, wherein a PLC (programmable logic controller) 3 is installed on one side of the workbench 2, the electrolytic cell mechanism 4 comprises a first electrolytic shell 401, two alkali liquor water pumps 402, two salt liquor water pumps 403, an ion exchange membrane 404, an anode plate 405, a second electrolytic shell 406, four cathode plates 407, four machine frames 408, eight ball screws 409, four connecting rollers 410, four worm gears 412, four worms 413, four first stepping motors 414 and eight second stepping motors 415, the two alkali liquor water pumps 402 are respectively installed on the upper surface and the lower surface of the first electrolytic shell 401, the two salt liquor water pumps are respectively installed on the upper surface and the lower surface of the first electrolytic shell 401, the outer surface of the ion exchange membrane 404 is fixedly connected to the inner side wall of the first electrolytic shell 401, the outer surface of the anode plate 405 is fixedly connected to the front part of the inner side wall 403 of the first electrolytic, the outer surface of the second electrolytic shell 406 is connected with the inner side wall of the first electrolytic shell 401 in a sliding mode, the inner side wall of the rack 408 is rotatably connected with the outer surface of the connecting roller 410 through a bearing, the outer surface of the connecting roller 410 is welded with the worm 413, gear teeth of the worm 413 are meshed with gear teeth of the worm wheel 412, two hinge brackets 4072 are welded on the rear surface of the cathode plate 407, a gear shaft of the worm wheel 412 is welded with the inner side wall of the hinge brackets 4072, two connecting blocks 4081 are symmetrically welded on two side surfaces of the rack 408, the inner side wall of the connecting blocks 4081 is welded with a moving nut of the ball screw 409, an output shaft of the first stepping motor 414 is welded with the connecting roller 410, and an output shaft of;

two connecting frames 7 are symmetrically welded on the upper surface of the base frame 1, the outer surfaces of the connecting frames 7 are connected with a fixed frame 8 through bolt threads, a hydraulic cylinder 6 is installed on the rear surface of the fixed frame 8, a piston rod of the hydraulic cylinder 6 is fixedly connected with a supporting frame 5, two protective plates 9 are symmetrically welded on two side surfaces of the connecting frames 7, and a top plate 10 is welded on the upper surface of the connecting frame 7;

the electrical output end of the PLC 3 is electrically connected with the electrical input ends of the alkali liquor pump 402, the salt liquor pump 403, the first stepping motor 414, the second stepping motor 415 and the hydraulic cylinder 6.

In this embodiment, specifically: four flanges 4011 are integrally formed on the inner side wall of the first electrolytic shell 401, four concave grooves 4061 are formed on the outer surface of the second electrolytic shell 406, and the inner side wall of each concave groove 4061 is in sliding connection with the outer surface of the flange 4011; with flange 4011 engaging groove 4061, a smoother engagement requirement is provided for the second electrolytic housing 406 to slide on the inner side wall of first electrolytic housing 401.

In this embodiment, specifically: the inner side wall of the first electrolytic shell 401 is welded with four sealing flanges 4012, the inner side wall of one sealing flange 4012 is communicated with a water inlet of one alkali liquor water pump 402, and the inner side wall of the other sealing flange 4012 is communicated with a water outlet of the other alkali liquor water pump 402; the inner side wall of the other sealing flange 4012 is communicated with a water inlet of one saline solution water pump 403, and the inner side wall of the other sealing flange 4012 is communicated with a water outlet of the other saline solution water pump 403; the lye pump 402 and the salt pump 403 are used for inputting and outputting the electrolyte.

In this embodiment, specifically: two supporting plates 411 are welded on the front surface of the frame 408, and the inner side walls of the supporting plates 411 are rotatably connected with a gear shaft of the worm gear 412 through bearings; the support plate 411 is used to support the worm wheel 412 so that it satisfies the normal operation of the train system.

In this embodiment, specifically: the rear surface of the cathode plate 407 is symmetrically and integrally formed with two sliding grooves 4071, and the inner side wall of each sliding groove 4071 is in sliding connection with a threaded rod of the ball screw 409; when the angle of the cathode plate 407 is adjusted by the worm gear 412, the chute 4071 keeps the cathode plate 407 engaged with the threaded rod of the ball screw 409 during the tilting process, and the chute 4071 itself engages with the other end of the threaded rod of the ball screw 409 to assist in the normal operation of the ball screw 409.

In this embodiment, specifically: the inner side wall of the second electrolytic shell 406 is welded with a separator 416, and the outer surface of the separator 416 is matched with the outer surface of the cathode plate 407; the separator 416 serves to separate the four sets of cathode plates 407 and prevent the four sets of cathode plates 407 from interfering with each other.

In this embodiment, specifically: the front surface of the second stepping motor 415 is in threaded connection with the rear surface of the support frame 5 through a bolt, and the front surface of the first stepping motor 414 is in threaded connection with the rear surface of the support frame 5 through a bolt; the support frame 5 fixedly matches and supports all the second stepping motors 415 and the first stepping motors 414 to meet the normal operation.

In this embodiment, specifically: two clamping plates 501 are symmetrically connected to two side surfaces of the support frame 5 through bolts in a threaded manner, the outer surfaces of the clamping plates 501 are connected with the outer surface of the connecting frame 7 in a sliding manner, the two side surfaces of the support frame 5 are rotatably connected with the inner side walls of the four idler wheels 502 through bearings, and the outer surfaces of the idler wheels 502 are attached to the upper surface of the connecting frame 7; support frame 5 is in the promotion in-process by pneumatic cylinder 6, coordinates through cardboard 501 to link 7 and slides, relies on gyro wheel 502 to coordinate with link 7 simultaneously, for the supplementary realization removal demand of support frame 5.

In this embodiment, specifically: the specific model of the PLC 3 is FX3 GA; the specific model of the alkali liquor water pump 402 and the nuclear salt liquor water pump 403 is ISW 50-160; the specific model of the first stepper motor 414 is 1TL 0001; the specific model of the second stepping motor 415 is HFF80B4B 5; the specific model of the hydraulic cylinder 6 is HSG 50.

Working principle or structural principle: firstly, electrolyte is injected through an alkali liquor water pump 402 and a salt liquor water pump 403, a cathode plate 407 and an anode plate 405 are separated by an ion exchange membrane 404, according to actual production requirements, a PLC (programmable logic controller) 3 controls a first stepping motor 414 to drive ball screws 409, each two groups of ball screws 409 drive a connecting block 4081 and a rack 408 to move, the cathode plate 407 is driven to adjust the distance between the cathode plate 407 and the anode plate 405, meanwhile, a second stepping motor 415 drives a connecting roller 410 to drive a worm 413 to mesh with a worm wheel 412, the worm wheel 412 drives a hinge frame 4072 to drive the cathode plate 407 to adjust the angle, and according to actual production conditions and electrolysis voltage regulation requirements, the four groups of cathode plates 407 can be matched with the anode plate 405 at different distances under the separation of;

in the device, the hydraulic cylinder 6 drives the support frame 5 to drive the second electrolysis shell 406 to be matched with the first electrolysis shell 401 for extrusion, so as to realize filter-pressing electrolysis, and, during the driving of the hydraulic cylinder 6, the first stepping motor 414 of each set of ball screws 409, when the signals of the PLC controller 3 and the hydraulic cylinder 6 are interacted, and the input pulse of the first stepping motor 414 is regulated and controlled according to the reference, so that in the process of shortening the distance between the support frame 5, the second electrolytic shell 406 and the first electrolytic shell 401, the distance between the cathode plate 407 and the anode plate 405 is kept unchanged, compared with the traditional filter-press type electrolytic device, the invention can realize self-adaptive adjustment according to different actual production requirements, meanwhile, the oxidation effect of hypochlorite ions on the surface of the cathode or the anode is relieved, so that the current efficiency in the electrolytic process is improved, and the energy consumption is effectively reduced.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (8)

1. The utility model provides an electrolysis trough of reduction energy consumption based on groove accuse control system, includes base frame (1), workstation (2) and electrolysis trough mechanism (4), its characterized in that: a PLC (programmable logic controller) controller (3) is installed on one side of the workbench (2), the electrolytic tank mechanism (4) comprises a first electrolytic shell (401), two alkali liquor water pumps (402), two salt liquor water pumps (403), an ion exchange membrane (404), an anode plate (405), a second electrolytic shell (406), four cathode plates (407), four racks (408), eight ball screws (409), four connecting rollers (410), four worm gears (412), four worms (413), four first stepping motors (414) and eight second stepping motors (415), the two alkali liquor water pumps (402) are respectively installed on the upper surface and the lower surface of the first electrolytic shell (401), the two salt liquor water pumps (403) are respectively installed on the upper surface and the lower surface of the first electrolytic shell (401), the outer surface of the ion exchange membrane (404) is fixedly connected to the inner side wall of the first electrolytic shell (401), the outer surface of the anode plate (405) is fixedly connected to the front portion of the inner side wall of the first electrolytic shell (401), the outer surface of the second electrolytic shell (406) is connected with the inner side wall of the first electrolytic shell (401) in a sliding mode, the inner side wall of the rack (408) is connected with the outer surface of the connecting roller (410) in a rotating mode through a bearing, the outer surface of the connecting roller (410) is welded with the worm (413), the gear teeth of the worm (413) are meshed with the gear teeth of the worm wheel (412), the rear surface of the cathode plate (407) is welded with two hinge frames (4072), the gear shaft of the worm wheel (412) is welded with the inner side wall of the hinge frames (4072), two connecting blocks (4081) are symmetrically welded on two side faces of the rack (408), the inner side wall of each connecting block (4081) is welded with a moving nut of the ball screw (409), and the output shaft of the first stepping motor (414) is welded with the connecting, an output shaft of the second stepping motor (415) is welded with a threaded rod of the ball screw (409);

the upper surface of the base frame (1) is symmetrically welded with two connecting frames (7), the outer surfaces of the connecting frames (7) are connected with a fixed frame (8) through bolts and threads, the rear surface of the fixed frame (8) is provided with a hydraulic cylinder (6), a piston rod of the hydraulic cylinder (6) is fixedly connected with a supporting frame (5), two protective plates (9) are symmetrically welded on two side surfaces of the connecting frames (7), and the upper surface of the connecting frame (7) is welded with a top plate (10);

the electrical output end of the PLC (3) is electrically connected with the electrical input ends of the alkali liquor water pump (402), the salt liquor water pump (403), the first stepping motor (414), the second stepping motor (415) and the hydraulic cylinder (6).

2. The electrolytic cell with reduced energy consumption based on the cell control system according to claim 1, wherein: the inside wall integrated into one piece of first electrolysis casing (401) has four flanges (4011), four recess grooves (4061) have been seted up to the surface of second electrolysis casing (406), the inside wall of recess groove (4061) with the surface sliding connection of flange (4011).

3. The electrolytic cell with reduced energy consumption based on the cell control system according to claim 1, wherein: the inner side wall of the first electrolytic shell (401) is welded with four sealing flanges (4012), the inner side wall of one sealing flange (4012) is communicated with a water inlet of one alkali liquor water pump (402), and the inner side wall of the other sealing flange (4012) is communicated with a water outlet of the other alkali liquor water pump (402); the inner side wall of the other sealing flange (4012) is communicated with a water inlet of one salt solution water pump (403), and the inner side wall of the other sealing flange (4012) is communicated with a water outlet of the other salt solution water pump (403).

4. The electrolytic cell with reduced energy consumption based on the cell control system according to claim 1, wherein: two supporting plates (411) are welded on the front surface of the rack (408), and the inner side walls of the supporting plates (411) are rotatably connected with a gear shaft of the worm gear (412) through bearings.

5. The electrolytic cell with reduced energy consumption based on the cell control system according to claim 1, wherein: the rear surface of the cathode plate (407) is symmetrically and integrally formed with two sliding grooves (4071), and the inner side wall of each sliding groove (4071) is in sliding connection with the threaded rod of the ball screw (409).

6. The electrolytic cell with reduced energy consumption based on the cell control system according to claim 1, wherein: a separator plate (416) is welded on the inner side wall of the second electrolysis shell (406), and the outer surface of the separator plate (416) is matched with the outer surface of the cathode plate (407).

7. The electrolytic cell with reduced energy consumption based on the cell control system according to claim 1, wherein: the front surface of the second stepping motor (415) is in threaded connection with the rear surface of the support frame (5) through a bolt, and the front surface of the first stepping motor (414) is in threaded connection with the rear surface of the support frame (5) through a bolt.

8. The electrolytic cell with reduced energy consumption based on the cell control system according to claim 1, wherein: two side faces of the support frame (5) are connected with two clamping plates (501) through symmetrical threads of bolts, the outer surfaces of the clamping plates (501) are connected with the outer surface of the connecting frame (7) in a sliding mode, the two side faces of the support frame (5) are connected with the inner side walls of the four idler wheels (502) in a rotating mode through bearings, and the outer surfaces of the idler wheels (502) are attached to the upper surface of the connecting frame (7).

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