CN213886128U - Remote control equipment with ternary precursor testing device - Google Patents

Abstract

The utility model discloses a remote control equipment with ternary precursor test device belongs to ternary precursor technical field, including the base, base top fixed mounting has the shell, and shell top fixed mounting has the support frame, and support frame top fixed mounting has servo motor, and the servo motor bottom is rotated and is connected with the puddler, and the nested speed reducer that is provided with in the puddler outside. The utility model discloses when well staff need test mixed ternary precursor material, the staff opens the aspirator pump, the aspirator pump can discharge the air in the shell through the breathing pipe, the valve is opened again to the staff, the valve is delivered to the shell with the inert gas in the gas storage tank in, servo motor and speed reducer are opened to this moment staff, servo motor drives the puddler outside stirring leaf when mixing the stirring to raw and other materials, because original air discharges through the breathing pipe in the shell, can prevent that a large amount of oxygen from making the raw and other materials oxidation that ternary precursor material used in the shell, reach better anti-oxidation effect.

Description

Remote control equipment with ternary precursor testing device

Technical Field

The utility model belongs to the technical field of the ternary precursor, specifically be a remote control equipment with ternary precursor test device.

Background

The ternary precursor material is nickel-cobalt-manganese hydroxide NixCoyMn (1-x-y) (OH)2, the ternary composite anode material precursor product takes nickel salt, cobalt salt and manganese salt as raw materials, and the proportion (x: y: z) of nickel, cobalt and manganese in the ternary composite anode material precursor product can be adjusted according to actual needs.

The precursor exists in a form before the target product is obtained, mostly exists in an organic-inorganic complex or mixture solid, and also exists in a sol form in part. The precursor is often used in the material preparation methods such as sol-gel method and coprecipitation method, but is not an exact scientific term and has no specific concept. It is also defined as a prototype sample of the target product, i.e., a pre-product from which the target product is obtained after some steps.

When the existing ternary precursor testing device is used for carrying out a mixing test on the ternary precursor material raw material through a reaction kettle, because the inner wall of the existing reaction kettle test device can not be subjected to anti-corrosion treatment, the raw materials of the ternary precursor material can be mixed and react, can cause corrosivity to the shell of the reaction kettle, is easy to damage the reaction kettle, and when the prior ternary precursor material raw material is heated and mixed in the mixing test, because the temperature of the electric heating tube can not be controlled at present, the effect of mixing the raw materials of the ternary precursor material can be influenced when the temperature is too high, and when the existing reaction kettle test device is used for testing the raw materials of the mixed ternary precursor material, the reaction kettle is only singly sealed and added with inert gas to prevent the raw materials from being oxidized, and the oxygen in the air remained in the reaction kettle can easily oxidize the ternary precursor material raw material.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a: the remote control equipment with the ternary precursor testing device is provided for solving the problems that the inner wall of the existing reaction kettle testing device can not be subjected to anti-corrosion treatment and can not control the temperature of an electric heating tube, and oxygen in residual air in a reaction kettle can easily oxidize raw materials of a ternary precursor material.

The utility model adopts the technical scheme as follows: the utility model provides a remote control equipment with ternary precursor test device, includes the base, base top fixed mounting has the shell, shell top fixed mounting has the support frame, support frame top fixed mounting has servo motor, the servo motor bottom is rotated and is connected with the puddler, the nested speed reducer that is provided with in the puddler outside, the top is close to support frame outside both ends embedding and is connected with the pan feeding mouth, shell bottom embedding is connected with the discharge gate, the nested valve A that is provided with in the discharge gate outside.

Wherein, the inboard laminating of shell is provided with the anticorrosive coating, the anticorrosive coating is 316 stainless steel anticorrosive coating.

The bottom of the shell is connected with an electric heating tube in an embedded mode, one end of the outer side of the shell is provided with a circuit control board in a matched mode, one end of the outer side of the shell is close to the upper portion and the lower portion of the circuit control board and is respectively and fixedly provided with an information processor and a temperature control module, and the electric heating tube is arranged between the shell and the anti-corrosion layer in an annular mode.

The air suction pipe is embedded and connected to the rear side of the top of the shell close to the feeding port at one end, an air suction pump is embedded and arranged on the outer side of the other end of the air suction pipe, a pipeline is embedded and connected to the rear side of the feeding port at the other end of the shell close to the top of the shell, a valve B is embedded and arranged on the outer side of the other end of the pipeline, an air storage box is embedded and arranged on the outer side of the bottom of the valve B, the air suction pipe is three, the front end and the rear end of the air suction pipe are arranged at one end of the top of the shell side by side, the pipeline is three, and the front end and the rear end of the air suction pipe are arranged at the other end of the top of the shell side by side.

The information processor is connected with the servo motor control module and the temperature control module through signals, the servo motor control module and the temperature control module are connected with the servo motor and the electric heating tube through signals, the electronic thermometer is matched with the shell inside, the electronic thermometer is connected with the information processor through signals of the temperature sensor, and the information processor is connected with the remote controller through signals of the matched information receiving module and the matched information transmitting module.

The servo motor control module, the temperature sensor, the information receiving module, the information transmitting module and the information processor are electrically connected through corresponding circuit control boards, and the circuit control boards, the servo motor, the electric heating tube and the air suction pump are electrically connected with an external power supply through wires.

To sum up, owing to adopted above-mentioned technical scheme, the beneficial effects of the utility model are that:

1. the utility model discloses in, through opening servo motor and speed reducer, servo motor is when driving the puddler and rotate, and the puddler outside stirring leaf will mix the processing to raw and other materials, and at this moment raw and other materials are when the back takes place to react mixing, and the corrosion resistance can be avoided leading to the fact the corrosivity to the shell by stainless steel anticorrosive coating, prevents to damage the shell, reaches better anticorrosion effect.

2. The utility model discloses in, through opening the electrothermal tube, at this moment staff accessible control temperature control module controls the temperature of electrothermal tube, makes the raw and other materials temperature in the shell rise to the high back that is fit for, can more effectual messenger raw and other materials heat and mix experimental processing, reaches better heating effect.

3. The utility model discloses in, through opening the aspirator pump, the aspirator pump can discharge the air in the shell through the breathing pipe, the valve is opened again to the staff, the valve is sent the inert gas in with the gas storage tank to the shell in, at this moment the staff opens servo motor and speed reducer, servo motor drives the puddler outside when stirring the leaf and mixing raw and other materials, because original air discharges through the breathing pipe in the shell, can prevent that a large amount of oxygen from making the raw and other materials oxidation that ternary precursor material used in the shell, reach better anti-oxidation effect.

Drawings

FIG. 1 is a schematic diagram of a front sectional structure of a ternary precursor testing device of the present invention;

FIG. 2 is a schematic diagram of a side view structure of the stirring rod of the present invention;

FIG. 3 is a schematic diagram of a partial top view structure of the ternary precursor testing device of the present invention;

fig. 4 is a schematic diagram of the circuit structure of the present invention.

The labels in the figure are: 1. a base; 2. a housing; 201. a feeding port; 202. a discharge port; 203. a valve A; 204. an anticorrosive layer; 205. a circuit control board; 206. a support frame; 3. a servo motor; 301. a stirring rod; 302. A speed reducer; 4. a material storage box; 5. a gas storage tank; 501. a valve B; 502. a pipeline; 6. an information processor; 7. an electric heating tube; 701. a temperature control module; 8. a getter pump; 801. and (4) sucking a pipe.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention; the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; furthermore, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, as they may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The utility model discloses in:

referring to fig. 1-4, a remote control device with a ternary precursor testing device comprises a base 1, wherein a shell 2 is fixedly mounted at the top of the base 1, a supporting frame 206 is fixedly mounted at the top of the shell 2, a servo motor 3 is fixedly mounted at the top of the supporting frame 206, a stirring rod 301 is rotatably connected to the bottom of the servo motor 3, a speed reducer 302 is nested in the outer side of the stirring rod 301, a feeding port 201 is embedded and connected to two ends of the top, close to the outer side of the supporting frame 206, of the top, a discharging port 202 is embedded and connected to the bottom of the shell 2, and a valve a203 is nested in the outer side of the discharging port 202.

Referring to fig. 1, it is further, the inboard laminating of shell 2 is provided with anticorrosive coating 204, anticorrosive coating 204 is 316 stainless steel anticorrosive coating 204, when the staff need carry out the experimental mixed ternary precursor material, the staff carries the raw and other materials that mixed ternary precursor material used to place the place of reation kettle testing device after, the staff puts into shell 2 back through pan feeding mouth 201 with raw and other materials, servo motor 3 and speed reducer 302 are opened to the staff, when servo motor 3 drives puddler 301 and rotates, puddler 301 outside stirring leaf will carry out hybrid processing to raw and other materials, at this moment, raw and other materials react after mixing, 316 stainless steel anticorrosive coating 204 can avoid raw and other materials to cause corrosivity to shell 2, prevent to damage shell 2, reach better anticorrosion effect.

Referring to fig. 1, further, the bottom of the housing 2 is embedded and connected with the electric heating tube 7, one end of the outer side of the housing 2 is provided with the circuit control board 205 in a matching manner, one end of the outer side of the housing 2 near the upper and lower sides of the circuit control board 205 is respectively and fixedly provided with the information processor 6 and the temperature control module 701, the electric heating tube 7 is arranged between the housing 2 and the anti-corrosion layer 204 in a ring shape, when workers put the raw materials for mixing the ternary precursor materials into the shell 2 and mix and stir the raw materials through the stirring rod 301, and the raw materials need to be heated and mixed, the workers can open the electric heating tube 7, at this time, the worker can control the temperature of the electric heating tube 7 by controlling the temperature control module 701, so that after the temperature of the raw material in the shell 2 is raised to a proper height, can more effectively heat and mix the raw material for experimental treatment, and achieve better heating effect.

Referring to fig. 1 and 3, further, an air suction pipe 801 is embedded and connected at the back side of the top of the housing 2 close to the material inlet 201 at one end, an air suction pump 8 is embedded and connected at the outer side of the other end of the air suction pipe 801, a pipeline 502 is embedded and connected at the back side of the material inlet 201 at the other end of the top of the housing 2 close to the other end of the housing 502, a valve B501 is embedded and connected at the outer side of the other end of the pipeline 502, an air storage tank 5 is embedded and connected at the outer side of the bottom of the valve B501, three air suction pipes 801 are arranged at one end of the top of the housing 2 in a front-back side-by-side manner, three pipelines 502 are arranged at the other end of the top of the housing 2 in a front-back side-by-side manner, when a worker needs to perform experiments on mixing of ternary precursor materials, the worker opens the air suction pump 8, the air in the housing 2 can be discharged through the air suction pipe 801, the worker opens the valve B501 again, the valve B501 sends inert gas in the air storage tank 5 into the housing 2, at this time, the worker opens the servo motor 3 and the speed reducer 302, when the servo motor 3 drives the stirring blades on the outer side of the stirring rod 301 to mix and stir the raw materials, because the original air in the shell 2 is discharged through the air suction pipe 801, the raw materials used by the ternary precursor material can be prevented from being oxidized by a large amount of oxygen in the shell 2, and a better anti-oxidation effect is achieved.

Referring to fig. 1, further, the information processor 6 is in signal connection with a servo motor control module and a temperature control module, the servo motor control module and the temperature control module 701 are both in signal connection with a servo motor 3 and an electrothermal tube 7, an electronic thermometer is matched with the inside of the shell 2, the electronic thermometer is in signal connection with the information processor 6 through a temperature sensor, and the information processor 6 is in signal connection with a remote controller through a matched information receiving module and an information transmitting module.

Referring to fig. 1 and 3, further, the servo motor control module, the temperature control module 701, the temperature sensor, the information receiving module, the information transmitting module and the information processor 6 are electrically connected through corresponding circuit control boards 205, and the circuit control boards 205, the servo motor 3, the electric heating tube 7 and the getter pump 8 are electrically connected with an external power supply through wires.

The working principle is as follows: firstly, when a worker needs to test a mixed ternary precursor material, the worker carries raw materials used for mixing the ternary precursor material to a place for placing a reaction kettle test device, the air suction pump 8 is opened, the air suction pump 8 can discharge air in the shell 2 through the air suction pipe 801, the worker opens the valve B501, the valve B501 sends inert gas in the gas storage tank 5 to the shell 2, at the moment, the worker opens the servo motor 3 through the remote controller and the servo motor control module, the speed reducer 302 drives the stirring blades on the outer side of the stirring rod 301 to mix and stir the raw materials, then, the worker opens the electric heating pipe 7 through the remote controller and the temperature control module 701, the temperature of the raw materials in the shell 2 is raised to a proper height, the raw materials can be more effectively heated and mixed for test treatment, and meanwhile, the temperature sensor can enable the remote controller to visually see the temperature condition in the shell 2, finally, when the raw materials are mixed and react, the 316 stainless steel anticorrosive coating 204 can prevent the raw materials from causing corrosivity to the shell 2 and damage to the shell 2.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (6)

1. A remote control device with a ternary precursor testing device comprises a base (1), and is characterized in that: base (1) top fixed mounting has shell (2), shell (2) top fixed mounting has support frame (206), support frame (206) top fixed mounting has servo motor (3), servo motor (3) bottom is rotated and is connected with puddler (301), puddler (301) outside nestification is provided with speed reducer (302), the top is close to support frame (206) outside both ends embedding and is connected with pan feeding mouth (201), shell (2) bottom embedding is connected with discharge gate (202), discharge gate (202) outside nestification is provided with valve A (203).

2. The remote control apparatus with a ternary precursor testing apparatus of claim 1, wherein: the inner side of the shell (2) is provided with an anticorrosive coating (204) in a fitting manner, and the anticorrosive coating (204) is a 316 stainless steel anticorrosive coating (204).

3. The remote control apparatus with a ternary precursor testing apparatus of claim 1, wherein: the bottom of the shell (2) is embedded and connected with an electric heating tube (7), one end of the outer side of the shell (2) is provided with a circuit control board (205) in a matching mode, one end of the outer side of the shell (2) is close to the upper portion and the lower portion of the circuit control board (205) and is fixedly provided with an information processor (6) and a temperature control module (701) respectively, and the electric heating tube (7) is arranged between the shell (2) and the anti-corrosion layer (204) in an annular shape.

4. The remote control apparatus with a ternary precursor testing apparatus of claim 1, wherein: the utility model discloses a valve, including shell (2), breathing pipe (801), shell (2) top, pipeline (502) other end outside, valve B (501) bottom outside is nested and is provided with gas storage tank (5), breathing pipe (801) have threely, and set up side by side in shell (2) top one end around being, pipeline (502) have threely, and set up side by side around being near one end pan feeding mouth (201) rear side embedding and be connected with breathing pipe (801), breathing pipe (801) other end outside is nested and is provided with aspirator pump (8), shell (2) top outside is nested, valve B (501) bottom outside is provided with gas storage tank (5), breathing pipe (801) have threely, and set up side by side at shell (2) top one end around being.

5. A remote control apparatus having a ternary precursor testing apparatus according to claim 3, wherein: information processor (6) signal connection has servo motor control module and temperature control module (701), and servo motor control module and temperature control module (701) equal signal connection have servo motor (3) and electrothermal tube (7), and inside supporting electronic thermometer that has of shell (2), and electronic thermometer has information processor (6) through temperature sensor signal connection, and information processor (6) have remote control ware through supporting information receiving module and information transmitting module signal connection.

6. The remote control apparatus with a ternary precursor testing apparatus of claim 5, wherein: the servo motor control module, the temperature control module (701), the temperature sensor, the information receiving module, the information transmitting module and the information processor (6) are electrically connected through corresponding circuit control boards (205), and the circuit control boards (205), the servo motor (3), the electric heating pipe (7) and the air suction pump (8) are electrically connected with an external power supply through wires.

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