Electrolyte production is with configuration equipment
Technical Field
The utility model relates to the technical field of electrolyte production, in particular to configuration equipment for electrolyte production.
Background
The battery refers to a part of space of a cup, a tank or other container or a composite container which is filled with electrolyte solution and metal electrodes to generate current, and can convert chemical energy into electric energy. The electrolyte is generally prepared by mixing distilled water and sulfuric acid, and the concentration ratio between the distilled water and the sulfuric acid is strict because the strength of the final battery storage characteristics is affected.
In the preparation process of the electrolyte, because sulfuric acid has strong corrosivity, a large amount of heat can be generated when the electrolyte is mixed and stirred with water, the equipment is easily damaged in the subsequent operation and stirring process due to overhigh heat, more impurities are likely to be generated due to impure raw materials when the sulfuric acid is mixed with the water, and the use effect of the battery electrolyte can be seriously influenced due to the generation of the impurities.
SUMMERY OF THE UTILITY MODEL
The utility model aims to provide a preparation device for electrolyte production, which aims to solve the problems that heat damages the device and impurities influence the quality during the preparation of the electrolyte.
In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides an electrolyte production is with configuration equipment, includes the equipment body, inside mixing chamber and the cooling chamber of being provided with of equipment body, the inboard symmetry of mixing chamber is provided with the alternating current board, and the liquid that gets into the mixing chamber inside from annotating the material pipe carries out first mixing through the alternating current board direction, install the motor on the equipment body, the axis of rotation of motor is fixed with the actuating lever, the actuating lever is located the mixing chamber inboard, be provided with the stirring rake on the actuating lever, the motor drives the actuating lever and rotates with the stirring rake and can carry out the intensive mixing stirring to the inside electrolyte of mixing chamber, the symmetry is provided with notes material pipe on the equipment body, install the drain valve on the equipment body.
Preferably, cooling chamber upper end symmetry is provided with the thermovent, and the thermovent is used for the heat dissipation of cooling intracavity cooling liquid, cooling pipe is installed to cooling chamber inboard, and cooling pipe adopts corrosion-resistant stainless steel thin wall pipe preparation to form its shape for snakelike, and electrolyte is when passing through cooling pipe, through cooling intracavity cooling liquid rapid cooling, and the one end of cooling pipe is connected with the hybrid chamber, and the other end of cooling pipe is connected with the water pump, and the conveyer pipe is installed to the delivery port of water pump, and the one end of conveyer pipe is connected with the filter tube.
Preferably, the lower extreme threaded connection of filter tube has the filter seat, filters seat threaded connection on the filter tube, will filter the seat and dismantle and to take out the filter screen and clear up, is provided with the filter screen between filter seat and the filter tube, filters the electrolyte through filtering the seat through the filter screen.
Preferably, the filter tube inner wall is provided with the buffer board, and the buffer board is stainless steel material, and the buffer board cushions getting into the intraductal electrolyte of filter, avoids the direct impact to the filter screen, the outside of filter tube is connected with the mount, and the one end of mount is installed on the equipment body.
Preferably, the filter pipe is provided with a sealing ring, the surface of the sealing ring is abutted to the filter seat, and the sealing ring is arranged to prevent the gap between the filter pipe and the filter seat from leaking.
Preferably, the top end of the cooling cavity is fixedly provided with a mounting frame which is of a frame structure, a fan is mounted on the mounting frame, and the fan is operated to blow cooling liquid in the cooling cavity.
Preferably, the cooling pipe is provided with an electromagnetic valve, and the electromagnetic valve opens the electrolyte in the mixing cavity and conveys the electrolyte into the filter pipe through the cooling pipe via the water pump and the conveying pipe.
Compared with the prior art, the utility model has the beneficial effects that: when the device is used, the alternating current plate and the stirring paddle driven by the motor to rotate can improve the mixing effect of the electrolyte; when the electrolyte passes through the cooling pipe, the cooling liquid in the cooling cavity absorbs heat to quickly cool and reduce the influence on equipment; the quality of electrolyte can be improved through filtering impurity through the filter screen when crossing the filter seat.
Drawings
FIG. 1 is a cross-sectional view of the overall structure of the present invention;
fig. 2 is a schematic view of the overall structure of the present invention.
In the figure: 1 equipment body, 11 mixing chamber, 12 cooling chamber, 13 drain valves, 14 notes material pipes, 15 alternating current boards, 16 thermovents, 2 motor, 21 actuating levers, 22 stirring rake, 3 mounting bracket, 31 fan, 4 water pump, 41 cooling tube, 42 solenoid valve, 43 conveyer pipe, 5 filter tube, 51 filter seat, 52 mount, 53 buffer board, 54 filter screen, 56 sealing ring.
Detailed Description
Referring to fig. 1, a configuration device for electrolyte production includes a device body 1, a mixing chamber 11 and a cooling chamber 12 are arranged inside the device body 1, an alternating current plate 15 is symmetrically arranged on the inner side of the mixing chamber 11, a liquid entering the mixing chamber 11 from an injection pipe 14 is guided by the alternating current plate 15 to be primarily mixed, a motor 2 is mounted on the device body 1, a driving rod 21 is fixed to a rotating shaft of the motor 2, the driving rod 21 is located on the inner side of the mixing chamber 11, a stirring paddle 22 is arranged on the driving rod 21, the motor 2 drives the driving rod 21 and the stirring paddle 22 to rotate so as to fully mix and stir the electrolyte inside the mixing chamber 11, the injection pipe 14 is symmetrically arranged on the device body 1, and a drain valve 13 is mounted on the device body 1.
Please refer to fig. 1 and 2, the upper end of the cooling chamber 12 is symmetrically provided with the heat dissipating ports 16, the heat dissipating ports 16 are used for dissipating heat of the cooling liquid in the cooling chamber 12, the cooling pipe 41 is installed on the inner side of the cooling chamber 12, when the electrolyte passes through the cooling pipe 41, because the cooling pipe 41 can increase the internal time of the cooling pipe 41 for the serpentine shape, and the cooling pipe 41 is located on the inner side of the cooling liquid in the cooling chamber 12, the cooling liquid can cool down the electrolyte in the cooling pipe 41 rapidly through the cooling liquid in the cooling chamber 12, one end of the cooling pipe 41 is connected with the mixing chamber 11, the other end of the cooling pipe 41 is connected with the water pump 4, the delivery pipe 43 is installed at the water outlet of the water pump 4, one end of the delivery pipe 43 is connected with the filter pipe 5.
Referring to fig. 1, a filter base 51 is screwed to the lower end of the filter pipe 5, the filter base 51 is screwed to the filter pipe 5, the filter base 51 is disassembled to take out the filter screen 54 for cleaning, the filter screen 54 is disposed between the filter base 51 and the filter pipe 5, and the electrolyte passing through the filter base 51 is filtered by the filter screen 54.
Referring to fig. 1, a buffer plate 53 is disposed on an inner wall of the filtering pipe 5, the buffer plate 53 is made of stainless steel, the buffer plate 53 buffers the electrolyte entering the filtering pipe 5 to avoid direct impact on the filter screen 54, a fixing frame 52 is connected to an outer side of the filtering pipe 5, and one end of the fixing frame 52 is mounted on the device body 1.
Referring to fig. 1 and 2, a sealing ring 56 is disposed on the filtering pipe 5, the surface of the sealing ring 56 abuts against the filtering base 51, and the sealing ring 56 prevents the gap between the filtering pipe 5 and the filtering base 51 from leaking.
Referring to fig. 1 and 2, a mounting frame 3 is fixed at the top end of the cooling chamber 12, the mounting frame 3 is a frame structure, a fan 31 is installed on the mounting frame 3, and the fan 31 operates to blow cooling liquid in the cooling chamber 12.
Referring to fig. 1 and 2, an electromagnetic valve 42 is installed on the cooling pipe 41, and the electromagnetic valve 42 opens the electrolyte in the mixing chamber 11 and transmits the electrolyte to the filtering pipe 5 through the cooling pipe 41 via the water pump 4 and the transmission pipe 43.
The utility model is implemented as follows: when the device is used, the configured liquid falls downwards onto the cross flow plate 15 from the two material injection pipes 14, then is obliquely converged downwards for primary mixing, then enters the mixing cavity 11, and then drives the driving rod 21 and the stirring paddle 22 to rotate through the motor 2 to stir the electrolyte again, so that the mixing effect of the electrolyte can be improved; after the electrolyte is stirred, the electromagnetic valve 42 is opened, the water pump 4 is operated, the electrolyte in the mixing cavity 11 downwards enters the inner side of the cooling pipe 41, the lower end of the cooling pipe 41 is positioned at the inner side of the cooling liquid in the cooling cavity 12, and the cooling liquid in the cooling cavity 12 absorbs heat to quickly cool the electrolyte in the cooling pipe 41, so that the damage to equipment caused by overheating of the electrolyte is avoided; the electrolyte cooling back water pump 4 can be inboard with its transport to filter tube 5, then can improve the quality of electrolyte through filter screen 54 filtration impurity downwards through the buffer board 53 buffering.