CN115786947A

CN115786947A - Electrolytic chlorine making tank of sodium hypochlorite generator

Info

Publication number: CN115786947A
Application number: CN202310069997.5A
Authority: CN
Inventors: 李凯; 孙继东; 李明; 宋布杰
Original assignee: Shandong Hechengzhiyun Environmental Protection Equipment Co ltd
Current assignee: Shandong Hechengzhiyun Environmental Protection Equipment Co ltd
Priority date: 2023-02-07
Filing date: 2023-02-07
Publication date: 2023-03-14

Abstract

The invention relates to the field of sodium hypochlorite processing and production, in particular to a chlorine preparation tank by electrolysis of a sodium hypochlorite generator. The method comprises the following steps: the upper surface of the back plate is provided with a processing tank for electrolyzing saline water or seawater to generate sodium hypochlorite, the side wall of the back plate is provided with a cleaning hole and a material injection hole, valves are arranged at the cleaning hole and the material injection hole, the cleaning hole is connected with a self-suction sewage pump, and the material injection hole is connected with a raw material input pump; the cover plate is fixedly arranged at the upper end of the back plate and can prevent sundries from entering the processing tank; the homodyne mechanism comprises a containing box and a supporting platform, wherein the containing box is fixedly arranged at one end of the back plate, which is provided with the cleaning hole, and the supporting platform is fixedly arranged in the containing box; three reciprocating mechanisms which can be independently controlled; the vibration descaling mechanism is connected with the middle reciprocating mechanism and comprises a vibration scraper blade capable of breaking dirt, and the two cleaning descaling mechanisms are connected with the reciprocating mechanisms on two sides and comprise cleaning brushes capable of cleaning dirt.

Description

Electrolytic chlorine making tank of sodium hypochlorite generator

Technical Field

The invention relates to the field of sodium hypochlorite processing and production, in particular to a chlorine preparation tank by electrolysis of a sodium hypochlorite generator.

Background

The sodium hypochlorite generator is an electrolysis device for generating sodium hypochlorite by electrolyzing saline water or seawater, an electrolytic tank commonly used by the sodium hypochlorite generator is generally a tubular electrolytic tank, electrodes are generally plate-type, electrode plates are arranged in the tubular electrolytic tank in parallel, a plurality of electrode plates are arranged in parallel to form a square or rectangular electrode group, and the electrolytic tank is generally composed of a back plate, a tank body and a cover plate.

In the process of producing sodium hypochlorite by adopting an electrolysis method, alkaline dirt appears during electrolysis, and the electrolysis effect is influenced. In the prior art, the acid cleaning is generally carried out in a manual mode, the acid is required to be manually prepared, and then the acid is required to be manually conveyed to an electrolytic tank, so that the working efficiency is low, and on the electrolytic tank of high-power equipment, the scaling can not be completely and effectively removed after the acid cleaning, the whole electrolytic tank is required to be disassembled for descaling, the labor intensity of workers is high, and the electrode is easily damaged by the descaling.

In view of the above, the invention disclosed in CN113463122a adopts an electrolytic cell with a quick release structure and a scraping structure, which can replace manual cleaning of the electrolytic cell, but the invention still has the defects that not only the discharge of the dirt is impossible, but also the generation of the alkaline dirt is random during electrolysis, and the alkaline dirt adheres to the electrolytic cell, so that the dirt cannot be completely removed by a simple reciprocating scraping structure.

In view of the above, there is a need for a sodium hypochlorite generator electrolytic chlorine generating cell that can remove alkaline contaminants completely without disassembly.

Disclosure of Invention

In view of the above, it is necessary to provide a sodium hypochlorite generator electrolytic chlorine generating tank for solving the problems in the prior art.

In order to solve the problems of the prior art, the invention adopts the technical scheme that:

a sodium hypochlorite generator electrolytic chlorine making tank comprises:

the device comprises a back plate, a cleaning hole and a material injection hole, wherein the back plate is arranged in a horizontal state, a processing groove for electrolyzing saline water or seawater to generate sodium hypochlorite is formed in the upper surface of the back plate, the side wall of the back plate is provided with the cleaning hole and the material injection hole, valves are arranged at the cleaning hole and the material injection hole, the cleaning hole is connected with a self-suction sewage pump, and the material injection hole is connected with a raw material input pump;

the cover plate is fixedly arranged at the upper end of the back plate and can prevent sundries from entering the processing tank;

the homodyne mechanism comprises a containing box and a supporting platform, the containing box is fixedly arranged at one end of the back plate, which is provided with the cleaning hole, and the supporting platform is fixedly arranged inside the containing box;

the three reciprocating mechanisms are arranged at the upper end of the supporting platform at equal intervals and can be independently controlled;

the vibration descaling mechanism is connected with the reciprocating mechanism in the middle and comprises a vibration scraper blade which can break up dirt on the wall of the processing tank;

and the two cleaning and descaling mechanisms are connected with the reciprocating moving mechanisms positioned on two sides, and comprise cleaning brushes which can remove scattered dirt on the processing tank.

Further, the coherent mechanism further comprises a first motor, a first support, a transmission shaft, a first driving bevel gear, a transfer bevel gear, a first driven bevel gear, a first gear and a first rotating shaft, wherein the first rotating shaft penetrates through the accommodating box in a horizontal state, one end of the first rotating shaft is rotatably connected with the side wall of the accommodating box through a bearing, the first driven bevel gear is fixedly coupled with the other end of the first rotating shaft, the transfer bevel gear is arranged beside the first driven bevel gear and is meshed with the first driven bevel gear, the first driving bevel gear and the first driven bevel gear are coaxially arranged and are meshed with the transfer bevel gear, one end of the transmission shaft is fixedly coupled with the first driving bevel gear, the output end of the first motor is connected with the other end of the transmission shaft through a coupler, the first support is arranged at one end of the first motor close to the first driving bevel gear, the first motor is fixedly connected with the first support, the first gear is arranged on one side of the accommodating box, which is far away from the first motor, the first gear is fixedly arranged outside the first rotating shaft, and the first gear is connected with a reciprocating mechanism.

Further, the coherent mechanism further comprises a second rotating shaft, a second support, a second driving bevel gear, a second driven bevel gear and a second gear, the second driving bevel gear is arranged below the first driving bevel gear and is rotatably connected with the first support through a pin shaft, the second driven bevel gear is arranged on one side, close to the containing box, of the first driven bevel gear and is meshed with the second driving bevel gear, the second support is arranged on one side, close to the containing box, of the second driven bevel gear, the second support is slidably connected with the second driven bevel gear, the upper end of the second support is rotatably connected with the first support through a pin shaft, the lower end of the second support is rotatably connected with the first support through a pin shaft, the second rotating shaft is coaxially and rotatably sleeved outside the first rotating shaft, one end of the second rotating shaft is fixedly connected with the second driven bevel gear, the second gear is fixedly sleeved with the other end of the second rotating shaft, and the second gear is connected with a reciprocating mechanism.

Furthermore, the coherent mechanism further comprises a third driving gear, a third rotating shaft, a reduction gear, a power gear, a second motor, a third rotating shaft and a third gear, wherein the third driving gear is arranged between the second support and the outer wall of the accommodating box, the third driving gear is fixedly connected with the second support in a coaxial line manner, the third rotating shaft is sleeved outside the second rotating shaft in a rotating manner in a coaxial line manner, one end of the third rotating shaft is fixedly connected with the third driving gear, the other end of the third rotating shaft penetrates through the accommodating box and is rotatably connected with the side wall of the accommodating box, the third gear is fixedly sleeved outside the third rotating shaft and is connected with a reciprocating mechanism, the reduction gear is arranged beside the third driving gear and is meshed with the third driving gear, the power gear is arranged beside the reduction gear and is meshed with the reduction gear, the second motor is arranged in a coaxial line manner with the power gear through a motor frame, and the output end of the second motor is fixedly connected with the power gear in a shaft manner.

Further, the reciprocating mechanism comprises a driving rack, a positioning support, a driving belt, a driving motor, two driving gears, two driving rotating shafts and two driving belt wheels, the driving rack in the three reciprocating mechanism is respectively meshed with the first gear, the second gear and the third gear, the positioning support is fixedly arranged at the lower end of the driving rack, three limit grooves which are arranged at equal intervals are formed in the supporting platform, the positioning support is connected with the limit grooves in a sliding mode, a containing cavity is formed in the driving rack, the two driving rotating shafts respectively penetrate through two ends of the driving rack in a horizontal state, the two driving gears are respectively fixedly sleeved at two ends of the two driving rotating shafts, the two driving belt wheels are arranged in the containing cavity and are respectively fixedly sleeved with the two driving rotating shafts, two ends of the driving belt are respectively in transmission connection with the two driving belt wheels, the driving motor is arranged at one end, far away from the back plate, and the output end of the driving motor is fixedly coupled with the driving rotating shafts.

Further, reciprocating motion mechanism still includes turns over a rack, two turns over a gear, two first laser positioning appearance, two second laser positioning appearance and two protection cover shells, it sets up the one end that is close to the backplate at the drive rack to turn over a rack, the backplate is close to the one end shaping that holds the case and has three hole of dodging, two protection cover shells are the both ends that symmetrical state set up at the drive rack, two protection cover shells and the hole sliding connection of dodging, two first laser positioning appearance set up respectively in the inside of two protection cover shells, it sets up the one end that is close to the backplate at the drive rack to turn over a rack, it is articulated mutually with the drive rack to turn over a rack, two are turned over a gear and are fixed respectively setting in the both sides of turning over a rack and mesh with two drive gears respectively through the round pin axle, second laser positioning appearance sets up respectively at the both ends of turning over a rack.

Furthermore, a fixing part is formed at one end, far away from the driving rack, of the turnover rack, the vibration descaling mechanism further comprises a vibration motor, the two cleaning descaling mechanisms further comprise cleaning motors, the vibration motor and the two cleaning motors are respectively connected with the fixing parts corresponding to the vibration motor and the cleaning motors, the vibration scraper is fixedly connected with the output end of the vibration motor, and the cleaning brush is fixedly connected with the output end of the cleaning motors.

Further, the shaping has scrapes the tooth on the lateral wall of vibrations scraper blade, and the bottom shaping has damaged tooth 49, and the cleaning brush includes lateral wall brush and chassis brush, and the dirt of machining tank bottom portion can be clear away to damaged tooth 49 and chassis brush, scrapes the dirt that tooth and lateral wall brush can clear away the machining tank lateral wall.

Compared with the prior art, the invention has the beneficial effects that:

one is as follows: this device accessible is coherent the mechanism and is realized the independent control to three reciprocating motion mechanism, and the degree of freedom is high, can thoroughly clear away the dirt on the processing tank inner wall, compares in the repeated cleanness of traditional artifical cleanness and mechanical type, and this device is through the cleanness of dirt including beating the bits of broken glass and brushing-off, very big improvement cleaning efficiency and work efficiency.

And the second step is as follows: the device can be used without separating the back plate from the cover plate, the vibration scraper blade and the cleaning brush can be turned upwards to avoid a processing tank after cleaning work is finished, dirt is prevented from being attached to the vibration scraper blade and the cleaning brush in an electrolytic reaction process, and the integration degree is high.

Drawings

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

FIG. 2 is an exploded perspective view of the present invention;

FIG. 3 is an enlarged view of the structure at A in FIG. 2;

FIG. 4 is an enlarged view of the structure at B in FIG. 2;

FIG. 5 is an exploded perspective view of the homodyne mechanism of the present invention;

FIG. 6 is a schematic perspective view of the reciprocating mechanism and the vibrating descaling mechanism according to the present invention;

FIG. 7 is an exploded perspective view of the reciprocating mechanism of the present invention;

fig. 8 is a sectional view showing the internal structure of the driving rack in the present invention.

The reference numbers in the figures are:

1. a back plate; 2. processing a tank; 3. avoiding holes; 4. cleaning the hole; 5. a material injection hole; 6. a cover plate; 7. a coherent mechanism; 8. an accommodating box; 9. a support platform; 10. a limiting groove; 11. a first motor; 12. a first bracket; 13. a drive shaft; 14. a first active bevel gear; 15. the umbrella teeth are connected in a switching way; 16. a first driven bevel gear; 17. a first rotating shaft; 18. a first gear; 19. a second rotating shaft; 20. a second bracket; 21. a second active bevel gear; 22. a second driven bevel gear; 23. a second gear; 24. a third driving gear; 25. a third rotating shaft; 26. a reduction gear; 27. a power gear; 28. a second motor; 29. a third gear; 30. a reciprocating mechanism; 31. a drive rack; 32. an accommodating chamber; 33. positioning a support; 34. a first laser positioning instrument; 35. a protective cover shell; 36. a drive gear; 37. driving the rotating shaft; 38. a drive pulley; 39. a drive belt; 40. a drive motor; 41. folding the rack; 42. a fixed part; 43. a turnover gear; 44. a second laser positioning instrument; 45. vibrating the descaling mechanism; 46. a vibration motor; 47. vibrating the scraper plate; 48. scraping teeth; 49. breaking the teeth; 50. cleaning the descaling mechanism; 51. cleaning the motor; 52. a cleaning brush; 53. a side wall brush; 54. a chassis brush.

Detailed Description

For further understanding of the features and technical means of the present invention, as well as the specific objects and functions attained by the present invention, the present invention will be described in further detail with reference to the accompanying drawings and detailed description.

Referring to fig. 1 to 8, a sodium hypochlorite generator electrolytic chlorine generating cell includes:

the device comprises a back plate 1 which is arranged in a horizontal state, wherein a processing tank 2 for electrolyzing saline water or seawater to generate sodium hypochlorite is arranged on the upper surface of the back plate 1, a cleaning hole 4 and a material injection hole 5 are formed in the side wall of the back plate 1, valves are arranged at the cleaning hole 4 and the material injection hole 5, the cleaning hole 4 is connected with a self-suction sewage pump, and the material injection hole 5 is connected with a raw material input pump;

the cover plate 6 is fixedly arranged at the upper end of the back plate 1 and can prevent sundries from entering the processing tank 2;

the coherent mechanism 7 comprises an accommodating box 8 and a supporting platform 9, wherein the accommodating box 8 is fixedly arranged at one end of the back plate 1, which is provided with the cleaning hole 4, and the supporting platform 9 is fixedly arranged inside the accommodating box 8;

the three reciprocating mechanisms 30 are arranged at the upper end of the supporting platform 9 at equal intervals, and the three reciprocating mechanisms 30 can be independently controlled;

the vibration descaling mechanism 45 is connected with the reciprocating mechanism 30 positioned in the middle, the vibration descaling mechanism 45 comprises a vibration scraper 47, and the vibration scraper 47 can scatter dirt on the wall of the processing tank 2;

and the two cleaning and descaling mechanisms 50 are connected with the reciprocating mechanism 30 positioned on two sides, each cleaning and descaling mechanism 50 comprises a cleaning brush 52, and the cleaning brushes 52 can clean the scattered dirt on the processing tank 2.

The coherent mechanism 7 further comprises a first motor 11, a first support 12, a transmission shaft 13, a first driving bevel gear 14, a transfer bevel gear 15, a first driven bevel gear 16, a first gear 18 and a first rotation shaft 17, wherein the first rotation shaft 17 penetrates through the accommodating box 8 in a horizontal state, one end of the first rotation shaft 17 is rotatably connected with the side wall of the accommodating box 8 through a bearing, the first driven bevel gear 16 is fixedly coupled with the other end of the first rotation shaft 17, the transfer bevel gear 15 is arranged beside and meshed with the first driven bevel gear 16, the first driving bevel gear 14 and the first driven bevel gear 16 are coaxially arranged and meshed with the transfer bevel gear 15, one end of the transmission shaft 13 is fixedly coupled with the first driving bevel gear 14, the output end of the first motor 11 is connected with the other end of the transmission shaft 13 through a coupler, the first support 12 is arranged at one end of the first motor 11 close to the first driving bevel gear 14, the first motor 11 is fixedly connected with the first support 12, the first gear 18 is arranged at one side of the accommodating box 8 far away from the first motor 11, the first gear 18 is fixedly sleeved on the first rotation shaft 18, and the first rotation shaft 17 is connected with a reciprocating mechanism. When the device operates, the first motor 11 is started, the first motor 11 drives the first driving bevel gear 14 to rotate through the transmission shaft 13, the rotation of the first driving bevel gear 14 can drive the switching bevel gear 15 which is meshed with the first driving bevel gear to rotate, the rotation of the switching bevel gear 15 can drive the first driven bevel gear 16 which is meshed with the switching bevel gear to rotate, the rotation of the first driven bevel gear 16 can drive the first rotating shaft 17 which is fixedly connected with the first driven bevel gear to rotate, the first rotating shaft 17 can drive the first gear 18 to rotate, and the rotation of the first gear 18 can drive the reciprocating mechanism 30 which is connected with the first driven bevel gear to move.

The homodyne mechanism 7 further comprises a second rotating shaft 19, a second support 20, a second driving bevel gear 21, a second driven bevel gear 22 and a second gear 23, the second driving bevel gear 21 is arranged below the first driving bevel gear 14, the second driving bevel gear 21 is rotatably connected with the first support 12 through a pin shaft, the second driven bevel gear 22 is arranged on one side, close to the accommodating box 8, of the first driven bevel gear 16, the second driven bevel gear 22 is meshed with the second driving bevel gear 21, the second support 20 is arranged on one side, close to the accommodating box 8, of the second driven bevel gear 22, the second support 20 is slidably connected with the second driven bevel gear 22, the upper end of the second support 20 is rotatably connected with the switching bevel gear 15 through a pin shaft, the lower end of the second support is rotatably connected with the first support 12 through a pin shaft, the second rotating shaft 19 is rotatably and coaxially sleeved outside the first rotating shaft 17, one end of the second rotating shaft 19 is fixedly connected with the second driven bevel gear 22, the second gear 23 is fixedly sleeved with the other end of the second rotating shaft 19, and the second gear 23 is connected with a reciprocating mechanism 30. When the device is operated, when dirt on the inner groove wall of the processing groove 2 needs to be vibrated and smashed, an operator can rotate the first support 12 in the horizontal direction, the first support 12 rotates to drive the second driving umbrella teeth 21 to rotate, the second driving umbrella teeth 21 rotate to drive the second driven umbrella teeth 22 meshed with the second driving umbrella teeth to rotate, the second driven umbrella teeth 22 rotate to drive the second rotating shaft 19 connected with the second driven umbrella teeth to rotate, the second rotating shaft 19 rotates to drive the second gear 23 connected with the second rotating shaft to rotate, and the second gear 23 rotates to drive the reciprocating mechanism 30 connected with the second rotating shaft to move.

The coherent mechanism 7 further comprises a third driving gear 24, a third rotating shaft 25, a reduction gear 26, a power gear 27, a second motor 28, a third rotating shaft 25 and a third gear 29, the third driving gear 24 is arranged between the second support 20 and the outer wall of the accommodating box 8, the third driving gear 24 is fixedly connected with the second support 20 coaxially, the third rotating shaft 25 is sleeved outside the second rotating shaft 19 in a rotating manner, one end of the third rotating shaft 25 is fixedly connected with the third driving gear 24, the other end of the third rotating shaft passes through the accommodating box 8 and is rotatably connected with the side wall of the accommodating box 8, the third gear 29 is fixedly sleeved outside the third rotating shaft 25, the third gear 29 is connected with a reciprocating mechanism 30, the reduction gear 26 is arranged beside the third driving gear 24 and is meshed with the same, the power gear 27 is arranged beside the reduction gear 26 and is meshed with the same, the second motor 28 is coaxially arranged with the power gear 27 through a motor frame, and the output end of the second motor 28 is fixedly connected with the power gear 27. When the device is operated, the second motor 28 is started and drives the power gear 27 connected with the output end of the second motor to rotate, the power gear 27 rotates to drive the reduction gear 26 engaged with the power gear to rotate, the reduction gear 26 rotates to drive the third driving gear 24 engaged with the reduction gear to rotate, the third driving gear 24 rotates to drive the second support 20 fixedly connected with the third driving gear to rotate, the rotation of the second support 20 drives the third rotating shaft 25 to rotate, and the rotation of the third rotating shaft 25 drives the third gear 29 fixedly connected with the third rotating shaft to rotate.

The reciprocating mechanism 30 comprises a driving rack 31, a positioning support 33, a driving belt 39, a driving motor 40, two driving gears 36, two driving rotating shafts 37 and two driving pulleys 38, the driving rack 31 in the three reciprocating mechanisms 30 is respectively meshed with the first gear 18, the second gear 23 and the third gear 29, the positioning support 33 is fixedly arranged at the lower end of the driving rack 31, three limit grooves 10 which are arranged at equal intervals are formed on the supporting platform 9, the positioning support 33 is in sliding connection with the limit grooves 10, an accommodating cavity 32 is formed inside the driving rack 31, the two driving rotating shafts 37 respectively penetrate through two ends of the driving rack 31 in a horizontal state, the two driving gears 36 are respectively and fixedly sleeved at two ends of the two driving rotating shafts 37, the two driving pulleys 38 are arranged in the accommodating cavity 32 and respectively and fixedly sleeved with the two driving rotating shafts 37, two ends of the driving belt 39 are respectively in transmission connection with the two driving pulleys 38, the driving motor 40 is arranged at one end of the driving rack 31 far away from the back plate 1, and an output end of the driving motor 40 is fixedly shaft connected with the driving rotating shafts 37 at the position. When the device operates, the driving racks 31 can move back and forth along with the rotation of the first gear 18, the second gear 23 and the third gear 29, at this time, the driving motor 40 corresponding to each driving rack 31 is started, the driving motor 40 is started to drive the driving rotating shaft 37 connected with the output end of the driving motor to rotate, the driving rotating shaft 37 rotates to drive the driving belt wheel 38 fixedly connected with the driving rotating shaft to rotate, the driving belt wheel 38 rotates to drive the other driving belt wheel 38 to rotate through the driving belt 39, the other driving belt wheel 38 rotates to drive the driving rotating shaft 37 fixedly connected with the driving belt wheel to rotate, and the driving rotating shaft 37 rotates to drive the two driving gears 36 fixedly connected with the driving rotating shaft 37 to rotate.

The reciprocating mechanism 30 further comprises a turnover rack 41, two turnover gears 43, two first laser positioning instruments 34, two second laser positioning instruments 44 and two protection sleeves 35, the turnover rack 41 is arranged at one end of the driving rack 31 close to the back plate 1, three avoidance holes 3 are formed at one end of the back plate 1 close to the containing box 8, the two protection sleeves 35 are symmetrically arranged at two ends of the driving rack 31, the two protection sleeves 35 are slidably connected with the avoidance holes 3, the two first laser positioning instruments 34 are respectively arranged inside the two protection sleeves 35, the turnover rack 41 is arranged at one end of the driving rack 31 close to the back plate 1, the turnover rack 41 is hinged to the driving rack 31, the two turnover gears 43 are respectively fixedly arranged at two sides of the turnover rack 41 through a pin shaft and are respectively meshed with the two driving gears 36, and the second laser positioning instruments 44 are respectively arranged at two ends of the turnover rack 41. When the device is operated, as the two driving gears 36 rotate, the two turnover gears 43 engaged with the two driving gears 36 rotate, and the rotation of the two turnover gears 43 drives the turnover rack 41 fixedly connected with the turnover gears to rotate. When the device is not in operation, the turnover gear 43 is vertically stacked with the driving rack 31 and meshed with the driving rack through teeth, and along with the operation of the device, the turnover gear 43 performs arc displacement and keeps the same horizontal line with the driving rack 31, when the positioning is successful, the laser emitted by the first laser positioning instrument 34 and the laser emitted by the second laser positioning instrument 44 perform opposite emission, at the moment, the signals are transmitted to the controller by the two, the controller controls the driving motor 40 to stop working, and at the moment, the turnover of the turnover rack 41 is completed.

The fixing portion 42 is formed at one end, away from the driving rack 31, of the turnover rack 41, the vibration descaling mechanism 45 further comprises a vibration motor 46, the two cleaning descaling mechanisms 50 further comprise cleaning motors 51, the vibration motor 46 and the two cleaning motors 51 are respectively connected with the corresponding fixing portions 42, the vibration scraper 47 is fixedly connected with the output end of the vibration motor 46, and the cleaning brush 52 is fixedly connected with the output end of the cleaning motors 51. When wasing processing groove 2 inner wall adnexed dirt, operating personnel should start shock dynamo 46 earlier, and shock dynamo 46 drives vibrations scraper blade 47 and smashes stubborn dirt and tentatively strike off, turns over a rack 41 and turns over upwards to turn over afterwards and break away from processing groove 2 with vibrations scraper blade 47, and operating personnel restarts cleaning motor 51 afterwards, and cleaning motor 51 drives cleaning brush 52 and rotates, clears away the dirt of processing groove 2 inside totally.

Scraping teeth 48 are formed on the side wall of the vibrating scraper 47, broken teeth 49 are formed at the bottom of the vibrating scraper 47, the cleaning brush 52 comprises a side wall brush 53 and a chassis brush 54, the broken teeth 49 and the chassis brush 54 can clean dirt at the bottom of the processing tank 2, and the scraping teeth 48 and the side wall brush 53 can clean dirt on the side wall of the processing tank 2. When the device is operated, along with the work of the vibrating scraper 47 and the cleaning brush 52, the damaged teeth 49 and the scraping teeth 48 can preliminarily crush stubborn dirt attached to the processing tank 2, so that the subsequent cleaning brush 52 can further remove the dirt through the side wall brush 53 and the chassis brush 54.

The working principle is as follows: when an operator removes the scale from the processing tank 2, the operator firstly rotates the first support 12, and knows that the rotation of the first support 12 drives the second gear 23 to rotate and finally drives the vibration scraper 47 to reciprocate, and in the process of reciprocating the vibration scraper 47, the vibration scraper 47 can crush the scale attached to the inner wall of the processing tank 2 through vibration, so as to ensure that the scale can fall off from the inner wall of the processing tank 2, and then the operator restarts the first motor 11 and the second motor 28, and knows that the first gear 18 and the third gear 29 rotate at this time, and respectively drives the corresponding cleaning brush 52 to scrub the wall of the processing tank 2. In this process, since the vibration scraper 47 has already crushed the dirt, the difficulty of cleaning is greatly reduced.

In the descaling process, an operator can also control the turnover racks 41 in the three reciprocating mechanisms 30 through the driving motor 40, and the change of the positions of the turnover racks 41 can drive the vibration scraper 47 and the cleaning brush 52 to move, that is, when the sodium hypochlorite generator works, the vibration scraper 47 and the two cleaning brushes 52 can be turned upwards to avoid contacting with the electrolytic raw material, so that the dirt is formed on the vibration scraper 47 and the two cleaning brushes 52.

After the device operation is finished, the vibration scraper 47 and the two cleaning brushes 52 are turned upwards, the valves at the positions of the cleaning holes 4 and the material injection holes 5 are opened and closed in turn at the moment, and the dirt scraped from the wall of the processing tank 2 is taken away, so that the descaling of the sodium hypochlorite generator electrolytic chlorine production tank is finished.

The above examples, which are intended to represent only one or more embodiments of the present invention, are described in greater detail and with greater particularity, and are not to be construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A sodium hypochlorite generator electrolysis chlorine making tank is characterized by comprising:

the device comprises a back plate (1) which is arranged in a horizontal state, wherein a processing tank (2) for electrolyzing saline water or seawater to generate sodium hypochlorite is arranged on the upper surface of the back plate (1), a cleaning hole (4) and a material injection hole (5) are formed in the side wall of the back plate (1), valves are arranged at the cleaning hole (4) and the material injection hole (5), the cleaning hole (4) is connected with a self-suction sewage pump, and the material injection hole (5) is connected with a raw material input pump;

the cover plate (6) is fixedly arranged at the upper end of the back plate (1) and can prevent sundries from entering the processing tank (2);

the coherent mechanism (7) comprises an accommodating box (8) and a supporting platform (9), the accommodating box (8) is fixedly arranged at one end of the back plate (1) where the cleaning hole (4) is formed, and the supporting platform (9) is fixedly arranged in the accommodating box (8);

the three reciprocating mechanisms (30) are arranged at the upper end of the supporting platform (9) at equal intervals, and the three reciprocating mechanisms (30) can be independently controlled;

the vibration descaling mechanism (45) is connected with the reciprocating mechanism (30) positioned in the middle, the vibration descaling mechanism (45) comprises a vibration scraper (47), and the vibration scraper (47) can break up dirt on the wall of the processing tank (2);

the two cleaning and descaling mechanisms (50) are connected with the reciprocating moving mechanisms (30) positioned on two sides, each cleaning and descaling mechanism (50) comprises a cleaning brush (52), and the cleaning brushes (52) can remove scattered dirt on the processing tank (2).

2. The chlorine cell produced by electrolysis of a sodium hypochlorite generator according to claim 1, characterized in that the concordance mechanism (7) further comprises a first motor (11), a first bracket (12), a transmission shaft (13), a first driving bevel gear (14), a transfer bevel gear (15), a first driven bevel gear (16), a first gear (18) and a first rotating shaft (17), the first rotating shaft (17) horizontally penetrates through the accommodating box (8), one end of the first rotating shaft is rotatably connected with the side wall of the accommodating box (8) through a bearing, the first driven bevel gear (16) is fixedly coupled with the other end of the first rotating shaft (17), the transfer bevel gear (15) is arranged beside and engaged with the first driven bevel gear (16), the first driving bevel gear (14) and the first driven bevel gear (16) are coaxially arranged and engaged with the transfer bevel gear (15), one end of the transmission shaft (13) is fixedly coupled with the first driving bevel gear (14), the output end of the first motor (11) is connected with the other end of the transmission shaft (13) through a coupler, one end of the first motor (11) is arranged close to the first motor (11) and is arranged outside the first rotating shaft (17), the first motor (11) and the first rotating shaft (17) is arranged outside the first rotating shaft (11), the first gear (18) is connected to a reciprocating mechanism (30).

3. Sodium hypochlorite generator electrolytic chlorine cell according to claim 2, characterized in that the coherent mechanism (7) further comprises a second rotating shaft (19), a second bracket (20), a second driving bevel gear (21), a second driven bevel gear (22) and a second gear (23), wherein the second driving bevel gear (21) is arranged below the first driving bevel gear (14), the second driving bevel gear (21) is rotatably connected with the first support (12) through a pin shaft, the second driven bevel gear (22) is arranged on one side, close to the accommodating box (8), of the first driven bevel gear (16), the second driven bevel gear (22) is meshed with the second driving bevel gear (21), the second support (20) is arranged on one side, close to the accommodating box (8), of the second driven bevel gear (22), the second support (20) is slidably connected with the second driven bevel gear (22), the upper end of the second support (20) is rotatably connected with the transfer bevel gear (15) through a pin shaft, the lower end of the second support is rotatably connected with the first support (12) through a pin shaft, the second rotating shaft (19) is coaxially rotatably sleeved outside the first rotating shaft (17), one end of the second rotating shaft (19) is fixedly connected with the second driven bevel gear (22), and the second gear (23) is fixedly connected with the second gear (23), and the other reciprocating mechanism (30) moves.

4. The electrolytic chlorine-making tank for sodium hypochlorite generators according to claim 3, characterized in that the coherent mechanism (7) further comprises a third driving gear (24), a third rotating shaft (25), a reduction gear (26), a power gear (27), a second motor (28), a third rotating shaft (25) and a third gear (29), the third driving gear (24) is arranged between the second support (20) and the outer wall of the accommodating box (8), the third driving gear (24) is fixedly connected with the second support (20) in a coaxial manner, the third rotating shaft (25) is rotatably sleeved outside the second rotating shaft (19) in a coaxial manner, one end of the third rotating shaft (25) is fixedly connected with the third driving gear (24), the other end of the third rotating shaft penetrates through the accommodating box (8) and is rotatably connected with the side wall of the accommodating box (8), the third gear (29) is fixedly sleeved outside the third rotating shaft (25), the third gear (29) is connected with a reciprocating mechanism (30), the reduction gear (26) is arranged on the third driving gear (24) and is meshed with the power gear, the power gear (27) is fixedly sleeved on the side of the second rotating shaft (27), and is connected with the motor (28) through the coaxial line.

5. The electrolytic chlorine production tank for the sodium hypochlorite generator as defined in claim 4, wherein the reciprocating mechanism (30) comprises a driving rack (31), a positioning support (33), a driving belt (39), a driving motor (40), two driving gears (36), two driving shafts (37) and two driving pulleys (38), the driving rack (31) of the three reciprocating mechanisms (30) is respectively engaged with the first gear (18), the second gear (23) and the third gear (29), the positioning support (33) is fixedly arranged at the lower end of the driving rack (31), three spacing grooves (10) are formed on the supporting platform (9) and are arranged at equal intervals, the positioning support (33) is slidably connected with the spacing grooves (10), an accommodating cavity (32) is formed inside the driving rack (31), the two driving shafts (37) respectively penetrate through two ends of the driving rack (31) in a horizontal state, the two driving gears (36) are respectively fixedly sleeved at two ends of the two driving shafts (37), the two driving pulleys (38) are arranged in the accommodating cavity (32) and are respectively sleeved with one end of the two driving shafts (37), one end of the driving belt (39) is respectively connected with the driving pulley (38), and the driving shaft (31) is far away from the driving motor (38), the output end of the driving motor (40) is fixedly coupled with the driving rotating shaft (37).

6. The tank for producing chlorine by sodium hypochlorite generator electrolysis according to claim 5, wherein the reciprocating mechanism (30) further comprises a turnover rack (41), two turnover gears (43), two first laser positioning instruments (34), two second laser positioning instruments (44) and two protection sleeves (35), the turnover rack (41) is disposed at one end of the driving rack (31) close to the back plate (1), the back plate (1) is molded with three avoiding holes (3) at one end close to the containing box (8), the two protection sleeves (35) are symmetrically disposed at two ends of the driving rack (31), the two protection sleeves (35) are slidably connected with the avoiding holes (3), the two first laser positioning instruments (34) are respectively disposed inside the two protection sleeves (35), the turnover rack (41) is disposed at one end of the driving rack (31) close to the back plate (1), the turnover rack (41) is hinged to the driving rack (31), the two turnover racks (43) are respectively fixedly disposed at two sides of the turnover rack (41) and respectively engaged with the two laser positioning instruments (36), and the second laser positioning instruments (41) are respectively disposed at two ends of the driving rack (41).

7. The sodium hypochlorite generator electrolytic chlorine making tank according to claim 6, characterized in that a fixing part (42) is formed at one end of the turnover rack (41) far away from the driving rack (31), the vibration descaling mechanism (45) further comprises a vibration motor (46), the two cleaning descaling mechanisms (50) further comprise cleaning motors (51), the vibration motor (46) and the two cleaning motors (51) are respectively connected with the corresponding fixing parts (42), the vibration scraper (47) is fixedly connected with the output end of the vibration motor (46), and the cleaning brush (52) is fixedly connected with the output end of the cleaning motors (51).

8. The sodium hypochlorite generator electrolytic chlorine generating tank as claimed in claim 7, wherein the vibrating scraper (47) is formed with scraping teeth (48) on the side wall thereof, and is formed with broken teeth (49) on the bottom thereof, the cleaning brush (52) comprises a side wall brush (53) and a bottom plate brush (54), the broken teeth (49) and the bottom plate brush (54) can remove the dirt on the bottom of the processing tank (2), and the scraping teeth (48) and the side wall brush (53) can remove the dirt on the side wall of the processing tank (2).