CN211872102U - Novel electrolytic tank of sodium hypochlorite generator - Google Patents

Abstract

The utility model relates to a novel electrolysis trough of sodium hypochlorite generator, including the electrolysis trough body, the cell wall of electrolysis trough body sets up to the cavity structure by inner wall and outer wall formation, and cavity structure internal connection has a cooling structure, and electrolysis trough body internal connection has the temperature sensor who is connected with the cooling structure electricity. This electrolysis trough can carry out the heat dissipation rapidly to the liquid in the electrolysis trough in the use and handle, makes the concentration of the sodium hypochlorite solution that the electrolysis produced be convenient for control, easy operation moreover, staff's low in labor strength, work efficiency is high.

Description

Novel electrolytic tank of sodium hypochlorite generator

Technical Field

The utility model relates to the technical field of water treatment devices, in particular to a novel electrolytic tank of a sodium hypochlorite generator.

Background

The molecular formula of the sodium hypochlorite is NaCl0, belongs to strong base and weak acid salt, is clear and transparent, and is a liquid capable of being completely dissolved in water. The process of generation of sodium hypochlorite can be expressed by the chemical reaction formula: NaCl + H20 → NaClO + H2 × (r), prepares sodium hypochlorite solution through electrolysis 3% concentration salt solution, and industry such as drinking water disinfection, hospital waste water treatment, food household utensils disinfection, waste water decoloration, industrial life waste water sterilization, plant disinfection are applied to rapidly to sodium hypochlorite solution, and it can improve waters ecological environment, plays the effect of environmental protection.

The electrolytic cell is composed of a cell body, an anode and a cathode, and is classified into an aqueous solution electrolytic cell, a molten salt electrolytic cell and a non-aqueous solution electrolytic cell according to the difference of the electrolyte. During the use process, firstly, dilute brine is metered into an electrolytic cell, and a cathode and anode direct current power supply is connected through a silicon rectifier to electrolyze to generate sodium hypochlorite. According to the theory of electrolysis, when the electrodes are inserted, under a certain voltage, the electrolyte solution generates a conductive action due to the movement of ions and electrode reactions, and then negative ions such as CL-, OH-and the like move to the anode, and positive ions such as Na +, H + and the like move to the cathode and generate discharge on the corresponding electrodes, so that the redox reaction is carried out to generate corresponding substances.

Because a great deal of heat is released in a short time by the redox reaction, the electrolytic cell of the traditional sodium hypochlorite generator only naturally dissipates heat through the temperature and the external environment, and the internal temperature is often too high in the actual use process, so that the reaction rate is accelerated, the output of sodium hypochlorite in a certain time has great deviation, and the control of the concentration of a subsequent sodium hypochlorite solution is not facilitated; moreover, the existing electrolytic cell is usually communicated with an external liquid tank only through a water inlet, and the liquid is unevenly distributed after entering the electrolytic cell, so that the subsequent electrolytic effect is influenced to a certain extent, and the electrolytic efficiency is low.

SUMMERY OF THE UTILITY MODEL

To the problem that relates to in the background art, this application has provided a novel electrolysis trough of sodium hypochlorite generator, and this electrolysis trough can carry out the heat dissipation rapidly to the liquid in the electrolysis trough in the use and handle, makes the concentration of the sodium hypochlorite solution that the electrolysis produced be convenient for control, easy operation moreover, staff's low in labor strength, work efficiency is high.

In order to realize the aim, the utility model provides a novel electrolysis trough of sodium hypochlorite generator, including the electrolysis trough body, the cell wall of electrolysis trough body sets up the cavity structure that forms into by inner wall and outer wall, cavity structure internal connection has cooling structure, electrolysis trough body internal connection have with the temperature sensor that the cooling structure electricity is connected.

The working principle and the process of the technical scheme are as follows: when the sodium hypochlorite generator provided with the novel electrolytic cell is used, a worker firstly sets the optimum temperature in the liquid electrolysis process on the temperature sensor, then opens the cooling structure while starting an electrolysis program, so that the heat generated in the electrolysis process can be cooled through the cooling structure, the temperature sensor connected inside the electrolytic cell body senses the temperature of liquid inside the electrolytic cell body, then transmits a signal to the cooling structure, when the temperature inside the electrolytic cell body is within the range of the appropriate electrolysis temperature, the signal can be transmitted to the cooling structure through the temperature sensor, and the cooling structure is closed; when the temperature in the electrolytic bath body is higher than the proper electrolysis temperature range, a signal can be transmitted to the cooling structure through the temperature sensor, and the cooling structure is opened, so that the cooling treatment effect on the liquid in the electrolytic bath is realized.

Compare with traditional hypochlorite generator's electrolysis trough, hypochlorite generator's electrolysis trough in this application can carry out real-time control to the liquid temperature in the electrolysis trough in the use, avoid the too high condition that causes the inhomogeneous condition of hypochlorite liquid concentration that the electrolysis produced of liquid temperature in the electrolysis trough, simultaneously with the temperature sensor electricity in cooling structure and the electrolysis trough be connected, can realize automated control's effect, staff's work load has been reduced, staff's work efficiency has been improved, and such setting only needs cooling structure to open when needs cool off the liquid in the electrolysis trough, can close when not needing to cool off, resource-saving's effect has been realized.

Further, the cooling structure is including connecting the inside condenser tube at cavity structure, condenser tube spiral winding is on the inner wall of electrolysis trough body, condenser tube one end is connected with the cooling water supply tank, and the other end is provided with the delivery port, the last hydraulic pump that is connected with of condenser tube, the hydraulic pump with the temperature sensor electricity is connected. Cooling structure in this application is when cooling off the electrolysis trough, the hydraulic pump that will be connected with the temperature sensor electricity is opened, can extract the cooling water pipe through the power supply that the hydraulic pump provided with the water in with the cooling water supply tank, carry out the heat exchange processing through the water in the cooling water pipe and the water of the inside electrolyte of electrolysis trough body, can realize the cooling treatment to the inside electrolyte of electrolysis trough body, when the temperature of electrolyte reduces to suitable temperature, temperature sensor transmits the temperature signal of perception for the hydraulic pump, close the hydraulic pump can, and convenient for operation, high durability and convenient use are realized, and the degree of automation is high.

Furthermore, a return pipe is connected between the water outlet and the cooling water supply tank, and a water pump is connected to the return pipe. This application is through the back flow of connecting with the cooling water supply tank intercommunication in delivery port department, can make the water after handling the electrolyte cooling to this internal electrolysis trough backward flow cooling water supply tank in, make the water that enters into the cooling water supply tank carry out the natural cooling, perhaps add the ice-cube in the cooling water supply tank, make the hydroenergy quick cooling that flows backward in the cooling water supply tank, realized the effect to the recycle of water, the extravagant condition of resource has been reduced, accord with the environmental protection production.

Furthermore, the inner wall of the electrolytic cell body is made of heat conducting materials. This application adopts the heat conduction material preparation with electrolysis trough body inner wall, can make the cooling water in the cooling water pipe and this internal electrolyte's of electrolysis trough heat exchange speed faster, improves refrigerated efficiency.

Furthermore, a spiral groove is formed in the inner wall of the electrolytic cell body, and the cooling water pipe is connected to the inner portion of the spiral groove. This application sets up spiral groove on the inner wall of electrolysis trough body, makes condenser tube connect inside spiral groove, is condenser tube fixed more stable on the inner wall of electrolysis trough body on the one hand, and on the other hand makes condenser tube and the inside electrolyte distance of electrolysis trough nearer, has further improved refrigerated efficiency.

Furthermore, the outer wall of the electrolytic cell body is provided with ventilation and heat dissipation holes, and the ventilation and heat dissipation holes are of a shutter structure. This application sets up the ventilation louvre on the outer wall of electrolysis trough body, can be further quick give off the heat that the inside electrolyte of electrolysis trough produced, further improved the radiating efficiency to the inside electrolyte of electrolysis trough body.

Furthermore, a water distribution structure is connected in the electrolytic cell. This application is through at electrolysis trough internal connection water distribution structure, can distribute more evenly through the electrolyte that the water distribution structure will enter into in the electrolysis trough, and the electrolytic efficiency of electrolyte is higher, has also reduced the consumption of the energy when having improved electrolytic efficiency.

Furthermore, the water distribution structure comprises a water inlet pipe connected inside the electrolytic cell, a plurality of water outlet branch pipes are connected to the water inlet pipe at intervals, a water pump is connected to the water inlet pipe, and the water inlet pipe extends to the outside of the electrolytic cell and is communicated with the liquid storage tank. When needing to let in electrolyte to electrolysis trough body inside, open the water pump of connection on the inlet tube, can let in the water inlet pipe with the electrolyte in the liquid storage tank, then inside entering into the electrolysis trough body through the play water branch pipe of connection on the inlet tube, can ensure that electrolyte gets into the inside homogeneity that distributes of electrolysis trough body.

Furthermore, the spacing distance between the water outlet branch pipes is 2-4 cm. The application sets up the interval distance between the outlet branch pipe to 2-4 centimetres, and in this interval distance within range, the homogeneity that electrolyte distributes in the electrolysis trough body inside can all be guaranteed to the water of export in the outlet branch pipe.

To sum up, the utility model discloses compare in prior art's beneficial effect and be:

(1) the utility model provides a liquid temperature of sodium hypochlorite generator in the use can carry out real-time control to the electrolysis trough, avoid the liquid temperature in the electrolysis trough too high to cause the inhomogeneous condition of sodium hypochlorite liquid concentration that the electrolysis produced, simultaneously with the temperature sensor electricity in cooling structure and the electrolysis trough, can realize automated control's effect, staff's work load has been reduced, staff's work efficiency has been improved, and such setting only needs cooling structure to open when needs cool off the liquid in the electrolysis trough, can close when not needing to cool off, resource-saving's effect has been realized.

(2) Cooling structure in this application is when cooling off the electrolysis trough, the hydraulic pump that will be connected with the temperature sensor electricity is opened, can extract the cooling water pipe through the power supply that the hydraulic pump provided with the water in with the cooling water supply tank, carry out the heat exchange processing through the water in the cooling water pipe and the water of the inside electrolyte of electrolysis trough body, can realize the cooling treatment to the inside electrolyte of electrolysis trough body, when the temperature of electrolyte reduces to suitable temperature, temperature sensor transmits the temperature signal of perception for the hydraulic pump, close the hydraulic pump can, and convenient for operation, high durability and convenient use are realized, and the degree of automation is high.

(3) This application is through the back flow of connecting with the cooling water supply tank intercommunication in delivery port department, can make the water after handling the electrolyte cooling to this internal electrolysis trough backward flow cooling water supply tank in, make the water that enters into the cooling water supply tank carry out the natural cooling, perhaps add the ice-cube in the cooling water supply tank, make the hydroenergy quick cooling that flows backward in the cooling water supply tank, realized the effect to the recycle of water, the extravagant condition of resource has been reduced, accord with the environmental protection production.

(4) This application adopts the heat conduction material preparation with electrolysis trough body inner wall, can make the cooling water in the cooling water pipe and this internal electrolyte's of electrolysis trough heat exchange speed faster, improves refrigerated efficiency.

(5) This application sets up spiral groove on the inner wall of electrolysis trough body, makes condenser tube connect inside spiral groove, is condenser tube fixed more stable on the inner wall of electrolysis trough body on the one hand, and on the other hand makes condenser tube and the inside electrolyte distance of electrolysis trough nearer, has further improved refrigerated efficiency.

(6) This application sets up the ventilation louvre on the outer wall of electrolysis trough body, can be further quick give off the heat that the inside electrolyte of electrolysis trough produced, further improved the radiating efficiency to the inside electrolyte of electrolysis trough body.

(7) This application is through at electrolysis trough internal connection water distribution structure, can distribute more evenly through the electrolyte that the water distribution structure will enter into in the electrolysis trough, and the electrolytic efficiency of electrolyte is higher, has also reduced the consumption of the energy when having improved electrolytic efficiency.

Drawings

FIG. 1 is a schematic diagram of the structure of a novel electrolytic cell of a sodium hypochlorite generator of the present invention.

Labeled as: 1-cooling water supply tank, 2-cooling water pipe, 3-hydraulic pump, 4-electrolytic tank body, 5-inner wall, 6-outer wall, 7-ventilation and heat dissipation hole, 8-water outlet branch pipe, 9-water inlet pipe and 10-return pipe.

Detailed Description

All features disclosed in this specification may be combined in any combination, except features and/or steps that are mutually exclusive.

In order to make those skilled in the art better understand the technical solution of the present invention, the present invention will be further described in detail with reference to fig. 1 and the specific embodiment.

Example 1

Referring to fig. 1, the utility model provides a novel electrolysis trough of sodium hypochlorite generator, including electrolysis trough body 4, the cell wall of electrolysis trough body 4 sets up to the cavity structure that is formed by inner wall 5 and outer wall 6, and cavity structure internal connection has a cooling structure, and electrolysis trough body 4 internal connection has the temperature sensor who is connected with the cooling structure electricity.

The working principle and the process of the technical scheme are as follows: when the sodium hypochlorite generator provided with the novel electrolytic cell is used, a worker firstly sets the optimum temperature in the liquid electrolysis process on the temperature sensor, then opens the cooling structure while starting an electrolysis program, so that the heat generated in the electrolysis process can be cooled through the cooling structure, the temperature sensor connected to the inside of the electrolytic cell body 4 senses the temperature of the liquid in the electrolytic cell body 4 and transmits a signal to the cooling structure, when the temperature in the electrolytic cell body 4 is within the appropriate electrolysis temperature range, the signal can be transmitted to the cooling structure through the temperature sensor, and the cooling structure is closed; when the temperature in the electrolytic bath body 4 is higher than the proper electrolysis temperature range, a signal can be transmitted to the cooling structure through the temperature sensor, and the cooling structure is opened, so that the cooling treatment effect on the liquid in the electrolytic bath is realized.

Compare with traditional hypochlorite generator's electrolysis trough, hypochlorite generator's electrolysis trough in this application can carry out real-time control to the liquid temperature in the electrolysis trough in the use, avoid the too high condition that causes the inhomogeneous condition of hypochlorite liquid concentration that the electrolysis produced of liquid temperature in the electrolysis trough, simultaneously with the temperature sensor electricity in cooling structure and the electrolysis trough be connected, can realize automated control's effect, staff's work load has been reduced, staff's work efficiency has been improved, and such setting only needs cooling structure to open when needs cool off the liquid in the electrolysis trough, can close when not needing to cool off, resource-saving's effect has been realized.

Example 2

Based on embodiment 1, referring to fig. 1, the cooling structure of this embodiment includes a cooling water pipe 2 connected inside the cavity structure, the cooling water pipe 2 is spirally wound on an inner wall 5 of an electrolytic bath body 4, one end of the cooling water pipe 2 is connected with a cooling water supply tank 1, the other end is provided with a water outlet, the cooling water pipe 2 is connected with a hydraulic pump 3, and the hydraulic pump 3 is electrically connected with a temperature sensor.

Cooling structure in this application is when cooling off the electrolysis trough, hydraulic pump 3 with the temperature sensor electricity is connected is opened, can extract condenser tube 2 through the water of the power supply that hydraulic pump 3 provided in with cooling water supply tank 1 in, carry out the heat exchange processing through the water of the water in condenser tube 2 and the inside electrolyte of electrolysis trough body 4, can realize the cooling treatment to the inside electrolyte of electrolysis trough body 4, when the temperature of electrolyte reduces to suitable temperature, temperature sensor transmits the temperature signal of perception for hydraulic pump 3, close hydraulic pump 3 can, high durability and convenient operation, high durability and convenient use, and high automation degree.

Example 3

Referring to fig. 1, according to embodiment 2, a return pipe 10 is connected between a water outlet and a cooling water supply tank 1, and a water pump is connected to the return pipe 10.

This application is through the back flow 10 of connecting with cooling water supply tank 1 intercommunication in delivery port department, can make the water after the electrolyte cooling treatment to electrolysis trough body 4 flow back to in cooling water supply tank 1, make the water that enters into in cooling water supply tank 1 carry out the natural cooling, perhaps add the ice-cube in cooling water supply tank 1, make the hydroenergy quick cooling that flows back in cooling water supply tank 1, the effect to the recycle of water has been realized, the extravagant condition of resource has been reduced, accord with environmental protection production.

Example 4

Referring to fig. 1 based on example 1, the inner wall 5 of the electrolytic cell body 4 of this example is made of a heat conductive material.

This application adopts the heat conduction material preparation with 4 inner walls of electrolysis trough body 5, can make the cooling water in condenser tube 2 faster with the heat exchange rate of the electrolyte in the electrolysis trough body 4, improves refrigerated efficiency.

Example 5

Based on example 1, referring to fig. 1, the inner wall 5 of the electrolytic bath body 4 of this example is provided with a spiral groove, and the cooling water pipe 2 is connected inside the spiral groove.

This application sets up spiral groove on the inner wall 5 of electrolysis trough body 4, makes condenser tube 2 connect inside spiral groove, is condenser tube 2 fixed more stable on the inner wall 5 of electrolysis trough body 4 on the one hand, and on the other hand makes condenser tube 2 and the inside electrolyte distance of electrolysis trough nearer, has further improved refrigerated efficiency.

Example 6

Based on embodiment 1, referring to fig. 1, the outer wall 6 of the electrolytic bath body 4 of this embodiment is provided with ventilation and heat radiation holes 7, and the ventilation and heat radiation holes 7 are provided in a louver structure.

This application sets up ventilation louvre 7 on the outer wall 6 of electrolysis trough body 4, can further quick give off the heat that the inside electrolyte of electrolysis trough produced, further improved the radiating efficiency to the inside electrolyte of electrolysis trough body 4.

Example 7

Based on the embodiment 1, referring to fig. 1, a water distribution structure is connected in the electrolytic cell of the embodiment.

This application is through at electrolysis trough internal connection water distribution structure, can distribute more evenly through the electrolyte that the water distribution structure will enter into in the electrolysis trough, and the electrolytic efficiency of electrolyte is higher, has also reduced the consumption of the energy when having improved electrolytic efficiency.

Example 8

Based on embodiment 7, referring to fig. 1, the water distribution structure of this embodiment includes a water inlet pipe 9 connected inside the electrolytic cell, a plurality of water outlet branch pipes 8 are connected to the water inlet pipe 9 at intervals, a water pump is connected to the water inlet pipe 9, and the water inlet pipe 9 extends to the outside of the electrolytic cell and is communicated with a liquid storage tank.

When needing to let in electrolyte to electrolysis trough body 4 inside, open the water pump of connection on inlet tube 9, can let in inlet tube 9 with the electrolyte in the liquid storage tank in, then inside entering electrolysis trough body 4 through the water outlet branch pipe 8 of connection on inlet tube 9, can ensure that electrolyte gets into the inside homogeneity that distributes of electrolysis trough body 4.

Example 9

Based on the embodiment 8, referring to fig. 1, the spacing distance between the outlet branch pipes 8 of the embodiment is 2-4 cm.

The interval distance between the water outlet branch pipes 8 is set to be 2-4 cm, and the uniformity of the electrolyte distributed in the electrolytic cell body 4 can be ensured by the water output from the water outlet branch pipes 8 within the interval distance range.

It should be understood by those skilled in the art that the hydraulic pump of the present embodiment is well known in the art, and that products of different models and specifications can be purchased on the market according to specific needs.

The above-mentioned embodiments only express the specific embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for those skilled in the art, without departing from the technical idea of the present application, several changes and modifications can be made, which are all within the protection scope of the present application.

Claims (9)

1. The utility model provides a novel electrolysis trough of sodium hypochlorite generator, includes electrolysis trough body (4), its characterized in that, the cell wall of electrolysis trough body (4) sets up the cavity structure that is formed by inner wall (5) and outer wall (6), cavity structure internal connection has cooling structure, electrolysis trough body (4) internal connection have with the temperature sensor that cooling structure electricity is connected.

2. The novel electrolytic tank of sodium hypochlorite generator as claimed in claim 1, characterized in that the cooling structure comprises a cooling water pipe (2) connected inside the cavity structure, the cooling water pipe (2) is spirally wound on the inner wall (5) of the electrolytic tank body (4), one end of the cooling water pipe (2) is connected with a cooling water supply tank (1), the other end is provided with a water outlet, a hydraulic pump (3) is connected to the cooling water pipe (2), and the hydraulic pump (3) is electrically connected with the temperature sensor.

3. The electrolytic cell of sodium hypochlorite generator as claimed in claim 2, wherein a return pipe (10) is connected between the water outlet and the cooling water supply tank (1), and a water pump is connected to the return pipe (10).

4. The new type of electrolytic cell for sodium hypochlorite generator as claimed in claim 1, characterized in that the inner wall (5) of the said electrolytic cell body (4) is made of heat conductive material.

5. The new type of electrolyzer for sodium hypochlorite generator as claimed in claim 2, characterized in that the inner wall (5) of the electrolyzer body (4) is provided with a spiral groove, inside which the cooling water pipe (2) is connected.

6. The novel electrolytic cell of sodium hypochlorite generator as claimed in claim 1, characterized in that the outer wall (6) of the electrolytic cell body (4) is provided with ventilation and heat dissipation holes (7), and the ventilation and heat dissipation holes (7) are arranged in a shutter structure.

7. The electrolytic cell of sodium hypochlorite generator as claimed in claim 1, wherein a water distribution structure is connected in the electrolytic cell.

8. The novel electrolytic cell of sodium hypochlorite generator as claimed in claim 7, wherein the water distribution structure comprises a water inlet pipe (9) connected inside the electrolytic cell, a plurality of water outlet branch pipes (8) are connected to the water inlet pipe (9) at intervals, a water pump is connected to the water inlet pipe (9), and the water inlet pipe (9) extends to the outside of the electrolytic cell and is communicated with a liquid storage tank.

9. The electrolytic cell for sodium hypochlorite generator as set forth in claim 8, wherein the branch pipes are spaced apart by 2-4 cm.

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