CN114354299B - Electrode material mixing and separating equipment for manufacturing potential type ammonia sensor - Google Patents

Abstract

The invention relates to a mixing and separating device, in particular to an electrode material mixing and separating device for manufacturing a potential type ammonia sensor. The invention aims to provide electrode material mixing and separating equipment for manufacturing an electric potential type ammonia sensor, which can automatically add auxiliary materials and can automatically stir. The invention provides electrode material mixing and separating equipment for manufacturing an electric potential type ammonia sensor, which comprises a support frame, a control box, a support plate, a first gear motor, a stirring rod, a moving mechanism and the like, wherein the control box is arranged at the rear part of the left side of the support frame, the support plate is arranged at the left side of the upper part of the support frame, the first gear motor is arranged in the middle of the support plate, the stirring rod for stirring raw materials and auxiliary materials is arranged on an output shaft of the first gear motor, and the moving mechanism for moving the mixed materials is arranged at the lower side of the inner part of the support frame. After the first gear motor works, the stirring rod can be driven to rotate, so that the stirring rod can automatically stir raw materials and auxiliary materials, and the physical strength of people is saved.

Description

Electrode material mixing and separating equipment for manufacturing potential type ammonia sensor

Technical Field

The invention relates to a mixing and separating device, in particular to an electrode material mixing and separating device for manufacturing a potential type ammonia sensor.

Background

At present, along with the development of technology, people can discharge NH3 outwards every day, and once the concentration of NH3 is too high, the living environment of people is easy to pollute, so in order to prevent a large amount of NH3 from polluting the environment, a high-performance sensor for monitoring the concentration of NH3 needs to be developed, and because a sensitive electrode material needs to be used in the high-performance sensor, a large amount of sensitive electrode material needs to be prepared.

When the sensitive electrode material is prepared, the raw materials are usually placed in a container, then a proper amount of auxiliary materials are added, and then the mixture is subjected to manual stirring to precipitate and then is heated, so that the sensitive electrode material is obtained.

Therefore, there is a need to develop an electrode material mixing and separating device for manufacturing a potential type ammonia sensor, which can automatically add auxiliary materials and can automatically stir.

Disclosure of Invention

In order to overcome the defects that people forget to add auxiliary materials easily and manual stirring is relatively labor-consuming when preparing the sensitive electrode material, the invention provides electrode material preparing and separating equipment for manufacturing the potential type ammonia sensor, which can automatically add the auxiliary materials and can automatically stir.

The invention is realized by the following technical approaches:

the utility model provides a preparation of electrode material allotment splitter for potential type ammonia sensor, which comprises a supporting rack, the control box, a supporting plate, a gear motor, the puddler, moving mechanism, storage mechanism, add material mechanism and heating mechanism, support frame left side rear portion is equipped with the control box, support frame upper portion left side is equipped with the backup pad, the backup pad middle part is equipped with a gear motor, be equipped with the puddler that is used for stirring raw materials and auxiliary material on the output shaft of a gear motor, the inside downside of support frame is equipped with the moving mechanism that is used for removing the compounding, be equipped with the storage mechanism that is used for raw materials and auxiliary material to carry out the mixing on the moving mechanism, the backup pad right side is equipped with the material mechanism that adds that is used for adding the auxiliary material, the inside right side of support frame is equipped with the heating mechanism that is used for heating the compounding.

More preferably, the moving mechanism comprises a first screw rod, a movable frame, a second gear motor and a first distance sensor, wherein the middle part of the lower side of the inner part of the support frame is rotatably provided with the first screw rod, the left side of the first screw rod is provided with the movable frame in a threaded manner, the right part of the lower side of the inner part of the support frame is provided with the second gear motor, an output shaft of the second gear motor is connected with the first screw rod, and the middle part of the rear side of the lower part of the movable frame is provided with the first distance sensor.

More preferably, the storage mechanism comprises a second screw rod, a transmission assembly, a third gear motor, all gears, a storage tank and a liquid level sensor, wherein the second screw rod is symmetrically arranged on the left side and the right side of the inner bottom of the movable frame in a rotating mode, the transmission assembly is arranged between the lower sides of the second screw rods on the left rear side and the right front side, the third gear motor is arranged on the front part of the right side of the lower part of the movable frame, all gears are arranged on the output shaft of the third gear motor and on the lower side of the second screw rod on the right front side, all gears are meshed with each other, the storage tank is arranged between the upper sides of the second screw rods in a threaded mode, and the liquid level sensor is arranged in the middle of the bottom in the storage tank.

More preferably, the feeding mechanism comprises a second storage box, an air pump, a first movable block, a first spring, a first supporting block, a second rotating shaft, a first movable plate, a second torsion spring, a photoelectric sensor and a second cover, wherein the second storage box is arranged on the right side of the supporting plate, the air pump is arranged on the front portion of the right side of the second storage box, the first movable block is slidably arranged on the front side inside the second storage box, two first springs are arranged between the front side of the first movable block and the second storage box, two first supporting blocks are arranged on the lower portion of the rear side inside the supporting plate, the second rotating shaft is rotatably arranged between the first supporting blocks, the first movable plate is provided with the first rotating shaft, the first movable plate is used for blocking a round hole, the second torsion spring is arranged between the inner side of the first movable plate and the first supporting block, the photoelectric sensor is arranged in the middle of the rear side inside the storage box, and the second cover is arranged in the middle of the top of the second storage box.

More preferably, the heating mechanism comprises a supporting rod, a second movable plate, a second spring, an electric push rod, a second movable block, a second distance sensor, a contact switch and a heating tube, wherein two supporting rods are arranged on the right sides of the front side and the rear side of the inside of the supporting frame, the second movable plate is arranged between the upper sides of the supporting rods in a sliding mode, four second springs are arranged between the bottom of the second movable plate and the supporting frame, the second springs are wound on the supporting rods on the same side, the electric push rod is arranged on the upper portion of the right side inside the supporting frame, the second movable block is arranged on the telescopic rod of the electric push rod, the second distance sensor is arranged on the lower portion of the right side inside the supporting frame, the contact switch is arranged on the front portion of the right side of the lower portion of the supporting frame, and the heating tube is arranged on the front side and the rear side inside the second movable plate.

More preferably, the blanking mechanism is used for blanking raw materials, the blanking mechanism comprises a first storage box, a first cover, a first rotating shaft, a movable rod, a first torsion spring and a stop block, the left side of a supporting plate is provided with the first storage box, the front side and the rear side of the top of the first storage box are respectively provided with the first cover in a threaded mode, the front side and the rear side of the bottom in the first storage box are respectively provided with the first rotating shaft, the upper side of the first rotating shaft is respectively provided with the stop block, the lower side of the first rotating shaft is respectively provided with the movable rod, the movable rod is used for blocking the inner bottom of the first storage box, and the first torsion spring is respectively arranged between the lower side of the movable rod and the stop block on the same side.

More preferably, the dust-proof mechanism for preventing dust from falling is further included, the dust-proof mechanism comprises a second supporting block, a third rotating shaft, a third movable plate and a third torsion spring, the second supporting blocks are arranged on the right sides of the front side and the rear side of the upper portion of the supporting plate, the third rotating shaft is rotatably arranged between the inner sides of the second supporting blocks, the third movable plate is arranged on the third rotating shaft, and the third torsion spring is arranged between the front side and the rear side of the third movable plate and the second supporting blocks on the same side.

More preferably, the control box comprises a storage battery, a control module and a power module, the storage battery supplies power for electrode material allocation and separation equipment for the whole manufacturing potential type ammonia sensor, the power module is connected with a power master switch through a circuit, the control module and the power module are electrically connected, the control module is connected with a DS1302 clock circuit and a 24C02 circuit, the first distance sensor, the liquid level sensor, the photoelectric sensor, the second distance sensor and the contact switch are electrically connected with the control module, and the first speed reducing motor, the second speed reducing motor, the third speed reducing motor, the electric push rod, the air pump and the heating tube are all connected with the control module through peripheral circuits.

More preferably, the rear part of the right side of the lower part of the supporting plate is provided with a round hole, and the front side and the rear side of the left side of the lower part of the supporting plate are provided with square holes.

Compared with the prior art, the invention has the remarkable advantages that:

1. according to the invention, auxiliary materials are added into the second storage tank, after raw materials flow into the storage tank, when the air pump is started, the auxiliary materials can be automatically extruded to flow into the storage tank through the round hole, so that the auxiliary materials are automatically fed, and people are prevented from forgetting.

2. After the first gear motor works, the stirring rod can be driven to rotate, so that the stirring rod can automatically stir raw materials and auxiliary materials, and the physical strength of people is saved.

3. According to the invention, after the heating tube is opened, when the telescopic rod of the electric push rod is extended, the second movable plate can cover the storage tank, so that the heating tube can heat the mixed materials at a high speed.

4. Under the action of the third movable plate, dust can be prevented from falling into the storage tank, and waste of raw materials and auxiliary materials is avoided.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic view of a first partially cut-away perspective structure of the present invention.

Fig. 3 is a schematic view of a second partially cut-away perspective structure of the present invention.

Fig. 4 is a schematic perspective view of a moving mechanism according to the present invention.

Fig. 5 is a schematic cross-sectional perspective view of the moving mechanism of the present invention.

Fig. 6 is a schematic perspective view of a storage mechanism according to the present invention.

Fig. 7 is a schematic cross-sectional perspective view of a storage mechanism of the present invention.

Fig. 8 is a schematic cross-sectional perspective view of the blanking mechanism of the present invention.

Fig. 9 is an enlarged perspective view of the present invention at a.

Fig. 10 is a schematic cross-sectional perspective view of the feeding mechanism of the present invention.

Fig. 11 is an enlarged perspective view of the B-site of the present invention.

Fig. 12 is a schematic perspective view of a first portion of a heating mechanism according to the present invention.

Fig. 13 is a schematic perspective view of a second portion of the heating mechanism of the present invention.

Fig. 14 is a schematic perspective view of a dust-proof mechanism of the present invention.

Fig. 15 is an enlarged perspective view of the C-position structure of the present invention.

Fig. 16 is a circuit block diagram of the present invention.

Fig. 17 is a schematic circuit diagram of the present invention.

Meaning of reference numerals in the drawings: 1. a supporting frame, 2, a control box, 3, a supporting plate, 4, a first gear motor, 5, a stirring rod, 6, a moving mechanism, 61, a first screw rod, 62, a movable frame, 63, a second gear motor, 64, a first distance sensor, 7, a storage mechanism, 71, a second screw rod, 72, a transmission component, 73, a third gear motor, 74, a full gear, 75, a storage tank, 76, a liquid level sensor, 8, a blanking mechanism, 81, a first storage tank, 82, a first cover, 83, a first rotating shaft, 84, a movable rod, 85, a first torsion spring, 86, a stop block, 9, a feeding mechanism, 91 and a second storage tank, 92, an air pump, 93, a first movable block, 94, a first spring, 95, a first support block, 96, a second rotating shaft, 97, a first movable plate, 98, a second torsion spring, 99, a photoelectric sensor, 910, a second cover, 10, a heating mechanism, 101, a support rod, 102, a second movable plate, 103, a second spring, 104, an electric push rod, 105, a second movable block, 106, a second distance sensor, 107, a contact switch, 108, a heating tube, 11, a dust prevention mechanism, 111, a second support block, 112, a third rotating shaft, 113, a third movable plate, 114, and a third torsion spring.

Detailed Description

The invention is further elucidated below in conjunction with the drawings of the specification, and embodiments of the invention are given in conjunction with the drawings of the specification.

Example 1

The utility model provides a preparation of electrode material allotment splitter for potential type ammonia sensor, as shown in fig. 1-15, including support frame 1, control box 2, backup pad 3, first gear motor 4, puddler 5, moving mechanism 6, storage mechanism 7, add material mechanism 9 and heating mechanism 10, support frame 1 left side rear portion is equipped with control box 2, support frame 1 upper portion left side welding has backup pad 3, the round hole has been opened at backup pad 3 lower part right side rear portion, square hole has all been opened to backup pad 3 left front and back both sides, the backup pad 3 middle part is equipped with first gear motor 4, be equipped with puddler 5 on the output shaft of first gear motor 4, puddler 5 can stir raw materials and auxiliary material when taking place to rotate, support frame 1 inside downside is equipped with moving mechanism 6, be equipped with storage mechanism 7 on moving mechanism 6, support frame 3 right side is equipped with and adds material mechanism 9, support frame 1 inside right side is equipped with heating mechanism 10.

The moving mechanism 6 comprises a first screw rod 61, a movable frame 62, a second gear motor 63 and a first distance sensor 64, wherein the middle part of the lower side of the inner part of the support frame 1 is rotatably provided with the first screw rod 61, the movable frame 62 is arranged on the left side of the first screw rod 61 in a threaded manner, the movable frame 62 can drive a mixed material to move when moving, the right part of the lower side of the inner part of the support frame 1 is connected with the second gear motor 63 in a bolt manner, an output shaft of the second gear motor 63 is connected with the first screw rod 61, and the middle part of the lower part of the movable frame 62 is provided with the first distance sensor 64.

The storage mechanism 7 comprises a second screw rod 71, a transmission assembly 72, a third gear motor 73, a full gear 74, a storage tank 75 and a liquid level sensor 76, wherein the second screw rod 71 is symmetrically arranged on the left side and the right side of the bottom in the movable frame 62 in a front-back symmetrical mode, the transmission assembly 72 is arranged between the lower sides of the second screw rods 71 on the left rear side and the right front side, the transmission assembly 72 consists of two belt pulleys and a belt, the belt pulleys are arranged on the lower sides of the second screw rods 71 on the left rear side and the right front side, the belt pulleys are wound, the third gear motor 73 is bolted to the front part on the right side of the lower part of the movable frame 62, the full gear 74 is meshed with the lower sides of the second screw rods 71 on the right front side, the storage tank 75 is arranged between the upper sides of the second screw rods 71 in a threaded mode, raw materials and auxiliary materials flow into the storage tank 75, after being stirred by the stirring rod 5, the raw materials and the auxiliary materials can be mixed, and the liquid level sensor 76 is arranged in the middle of the bottom of the storage tank 75.

The feeding mechanism 9 comprises a second storage tank 91, an air pump 92, a first movable block 93, a first spring 94, a first supporting block 95, a second rotating shaft 96, a first movable plate 97, a second torsion spring 98, a photoelectric sensor 99 and a second cover 910, wherein the second storage tank 91 is welded on the right side of the supporting plate 3, auxiliary materials are added into the second storage tank 91, the auxiliary materials can automatically flow into the storage tank 75, the air pump 92 is arranged at the front part of the right side of the second storage tank 91, the first movable block 93 is arranged at the front side of the inside of the second storage tank 91 in a sliding manner, two first springs 94 are arranged between the front side of the first movable block 93 and the second storage tank 91, two first supporting blocks 95 are arranged at the lower part of the rear side of the inside of the supporting plate 3, the second rotating shaft 96 is rotatably arranged between the first supporting blocks 95, the first movable plate 97 is arranged on the second rotating shaft 96, the round holes are blocked by the first movable plate 97, the second torsion spring 98 is arranged between the inner side of the first movable plate 97 and the inner side of the first supporting block 95, the photoelectric sensor 99 is arranged in the middle of the rear side of the storage tank 75, and the middle of the inside of the storage tank 75, and the middle of the second storage tank is provided with a second cover 910 in a threaded manner.

The heating mechanism 10 comprises a supporting rod 101, a second movable plate 102, a second spring 103, an electric push rod 104, a second movable block 105, a second distance sensor 106, a contact switch 107 and a heating tube 108, wherein two supporting rods 101 are welded on the right sides of the front side and the rear side of the inside of the supporting frame 1, the second movable plate 102 is arranged between the upper sides of the supporting rods 101 in a sliding mode, four second springs 103 are arranged between the bottom of the second movable plate 102 and the supporting frame 1, the second springs 103 are wound on the supporting rods 101 on the same side, the electric push rod 104 is arranged on the upper right side inside the supporting frame 1, the second movable block 105 is arranged on a telescopic rod of the electric push rod 104, the second distance sensor 106 is arranged on the lower right side inside the supporting frame 1, the contact switch 107 is arranged on the front side of the right side inside of the lower portion of the supporting frame 1, the heating tube 108 is arranged on the front side and the rear side inside of the second movable plate 102, and the heating tube 108 is opened to heat a mixed material, and the mixed material can be formed into a sensitive electrode material.

The blanking mechanism 8 comprises a first storage box 81, a first cover 82, a first rotating shaft 83, a movable rod 84, a first torsion spring 85 and a stop block 86, wherein the first storage box 81 is welded on the left side of the supporting plate 3, raw materials are added into the first storage box 81, people can conveniently feed the raw materials, the first cover 82 is arranged on the front side and the rear side of the top of the first storage box 81 in a threaded mode, the first rotating shaft 83 is arranged on the front side and the rear side of the bottom inside the first storage box 81, the stop block 86 is arranged on the upper side of the first rotating shaft 83, the movable rod 84 is arranged on the lower side of the first rotating shaft 83 in a rotating mode, the movable rod 84 is used for blocking the inner bottom of the first storage box 81, and the first torsion spring 85 is arranged between the lower side of the movable rod 84 and the stop block 86 on the same side.

The dustproof mechanism 11 comprises a second supporting block 111, a third rotating shaft 112, a third movable plate 113 and a third torsion spring 114, wherein the second supporting block 111 is arranged on the right side of the front side and the rear side of the upper portion of the supporting plate 3, the third rotating shaft 112 is rotatably arranged between the inner sides of the second supporting blocks 111, the third movable plate 113 is arranged on the third rotating shaft 112, the third movable plate 113 can block dust and prevent the dust from falling into the storage tank 75, and the third torsion spring 114 is arranged between the front side and the rear side of the third movable plate 113 and the second supporting block 111 on the same side.

When people need to use the electrode material preparing and separating device for the potential type ammonia sensor, the first cover 82 and the second cover 910 are firstly rotated to be unscrewed, then two different raw materials are respectively added into the first storage tank 81, then auxiliary materials are added into the second storage tank 91, then the first cover 82 and the second cover 910 are screwed back to the original positions, then the power supply main switch is pressed, the electrode material preparing and separating device for the potential type ammonia sensor is electrified, the first distance sensor 64, the liquid level sensor 76, the photoelectric sensor 99 and the second distance sensor 106 start to work, then the movable rod 84 is rotated, the first torsion spring 85 deforms, the movable rod 84 does not block the inner bottom of the first storage tank 81, thus the two different raw materials respectively flow into the storage tank 75 through square holes, the third movable plate 113 is rotated to be opened, the third torsion spring 114 deforms, then people can watch the raw materials in the storage tank 75, when the storage tank 75 is filled with proper raw materials, the movable rod 84 is loosened again, the first torsion spring 85 is restored, the first torsion spring 85 drives the movable rod 84 to reversely reset, the movable rod 84 is enabled to block the inner bottom of the first storage tank 81 again, then the third movable plate 113 is loosened, the third torsion spring 114 is restored to the original state, the third torsion spring 114 drives the third movable plate 113 to reversely close, the third movable plate 113 is enabled to prevent dust from falling into the storage tank 75, when the liquid level sensor 76 senses that the liquid level of the raw materials is higher than the highest preset value, the liquid level sensor 76 sends out a signal, the control module receives the signal and then controls the air pump 92 to work for 5 seconds, the air pump 92 pumps air into the second storage tank 91, thereby extruding the first movable block 93 to move backwards, the first spring 94 stretches, and the first movable block 93 extrudes auxiliary materials to move backwards, the auxiliary materials are extruded to rotate the first movable plate 97, the second torsion spring 98 deforms, the first movable plate 97 does not block the round hole any more, the auxiliary materials flow into the storage tank 75 through the round hole, meanwhile, the control module controls the first gear motor 4 to work for 20 seconds, the output shaft of the first gear motor 4 drives the stirring rod 5 to rotate, the stirring rod 5 stirs the raw materials and the auxiliary materials, after 5 seconds, the control module controls the air pump 92 to stop working, at the moment, the first spring 94 is restored to the original state, the first movable block 93 moves forwards to reset, the first movable block 93 does not squeeze the auxiliary materials any more, at the moment, the second torsion spring 98 is restored to the original state, the second torsion spring 98 drives the first movable plate 97 to reversely reset, the first movable plate 97 blocks the round hole again, after 15 seconds, the control module controls the first gear motor 4 to stop working, the stirring rod 5 stops rotating, and the stirred mixed materials are precipitated, when the mixed material after stirring is deposited, the sediment in the mixed material can block the photoelectric sensor 99, when the photoelectric sensor 99 senses that the light is weaker than a preset value, the photoelectric sensor 99 sends out a signal, the control module receives the signal and then controls the third gear motor 73 to start working, the output shaft of the third gear motor 73 rotates positively, thereby driving the second screw rod 71 at the right front side to rotate positively through the full gear 74, driving the second screw rod 71 at the left rear side to rotate positively through the transmission assembly 72, driving the storage tank 75 to move downwards, thereby driving the deposited mixed material to move downwards, when the first distance sensor 64 senses that the distance between the first distance sensor and the storage tank 75 is smaller than the minimum preset value, the first distance sensor 64 sends out a signal, the control module receives the signal and then controls the third gear motor 73 to stop working, and meanwhile, the control module controls the second gear motor 63 to start working, the output shaft of the second gear motor 63 is rotated forward, so as to drive the first screw rod 61 to rotate forward, the movable frame 62, the second screw rod 71, the storage tank 75 and the precipitated mixed material move rightward, when the second distance sensor 106 senses that the distance between the second distance sensor 106 and the movable frame 62 is smaller than the minimum preset value, the second distance sensor 106 sends a signal, the control module controls the second gear motor 63 to stop working after receiving the signal, meanwhile, the control module controls the heating tube 108 to start working, and simultaneously, the control module controls the electric push rod 104 to work for 5 seconds, so that the telescopic rod of the electric push rod 104 is stretched, thereby driving the second movable block 105 to move leftward, when the second movable block 105 contacts with the second movable plate 102, the second movable block 105 extrudes the second movable plate 102 to move downward, the second spring 103 compresses, so that the second movable plate 102 covers the storage tank 75, so that the heating tube 108 heats the mixed material in the storage tank 75, after 5 seconds, the control module controls the electric push rod 104 to stop working, when the mixed material in the storage tank 75 is heated to be a sensitive electrode material, the mixed material liquid level in the storage tank 75 can drop, when the liquid level sensor 76 senses that the liquid level of the mixed material is lower than a lowest preset value, the liquid level sensor 76 sends out a signal, the control module controls the heating tube 108 to stop working after receiving the signal, meanwhile, the control module controls the electric push rod 104 to work for 5 seconds, so that the telescopic rod of the electric push rod 104 is shortened, thereby driving the second movable block 105 to move rightwards, when the second movable block 105 is separated from the second movable plate 102, the second spring 103 is restored to be original, the second spring 103 drives the second movable plate 102 to move upwards for resetting, so that the second movable plate 102 loosens the storage tank 75, after 5 seconds, the control module controls the electric push rod 104 to stop working, then the sensitive electrode material in the storage tank 75 is taken out manually, the contact switch 107 is pressed once again, the contact switch 107 sends out a signal, the control module controls the second gear motor 63 to start working after receiving the signal, the output shaft of the second gear motor 63 is reversed, thereby driving the first screw 61 to be reversed, the movable frame 62, the second screw 71 and the storage tank 75 are moved leftwards for reset, when the second distance sensor 106 senses that the distance between the movable frame 62 is larger than the maximum preset value, the second distance sensor 106 sends out a signal, the control module controls the second gear motor 63 to stop working after receiving the signal, and simultaneously, the control module controls the third gear motor 73 to start working, so that the output shaft of the third gear motor 73 is reversed, thereby driving the second screw 71 on the right front side to be reversed through the full gear 74, and driving the second screw 71 on the left rear side through the transmission component 72, the storage tank 75 is moved upwards for reset, when the first distance sensor 64 senses that the distance between the first distance sensor 64 and the storage tank 75 is larger than the maximum preset value, the second distance sensor 106 sends out a signal, the control module controls the third gear motor 73 to stop working, then the second gear motor 73 is controlled to stop working, the second gear motor 73 is driven by the second gear motor 73, the second gear motor is driven by the transmission component to rotate, the second gear motor is driven by the left and the left gear motor is driven by the left gear motor 71 to be reversed, the left rear gear motor is driven by the second screw, the left and the left gear motor is driven by the left and the left gear motor to be driven by the left and 75.

Example 2

Based on embodiment 1, as shown in fig. 16 and 17, the control box 2 includes a storage battery, a control module and a power module, the storage battery supplies power to the electrode material allocation and separation device for the whole manufacturing potential type ammonia sensor, the power module is connected with a main power switch through a circuit, the control module is electrically connected with the power module, the control module is connected with a DS1302 clock circuit and a 24C02 circuit, the first distance sensor 64, the liquid level sensor 76, the photoelectric sensor 99, the second distance sensor 106 and the contact switch 107 are electrically connected with the control module, and the first speed reducing motor 4, the second speed reducing motor 63, the third speed reducing motor 73, the electric push rod 104, the air pump 92 and the heating tube 108 are all connected with the control module through peripheral circuits.

Finally, it is necessary to state that: the foregoing is provided to assist in understanding the technical solutions of the present invention, and is not to be construed as limiting the scope of protection of the present invention; insubstantial modifications and variations from the above teachings are within the scope of the invention as claimed.

Claims (3)

1. The electrode material mixing and separating device for the potential ammonia sensor comprises a support frame (1), a control box (2), a support plate (3), a first gear motor (4) and a stirring rod (5), wherein the control box (2) is arranged at the rear part of the left side of the support frame (1), the support plate (3) is arranged at the left side of the upper part of the support frame (1), the first gear motor (4) is arranged in the middle of the support plate (3), the stirring rod (5) for stirring raw materials and auxiliary materials is arranged on an output shaft of the first gear motor (4), and the electrode material mixing and separating device is characterized by further comprising a moving mechanism (6), a storage mechanism (7), a material adding mechanism (9) and a heating mechanism (10), wherein the moving mechanism (6) is arranged at the lower side in the support frame (1), the storage mechanism (7) for mixing raw materials and auxiliary materials is arranged on the moving mechanism (6), the material adding mechanism (9) for adding auxiliary materials is arranged on the right side of the support plate (3), and the heating mechanism (10) for heating the mixed materials is arranged on the right side in the support frame (1). The moving mechanism (6) comprises a first screw rod (61), a movable frame (62), a second gear motor (63) and a first distance sensor (64), wherein the first screw rod (61) is rotatably arranged in the middle of the lower side of the inner part of the support frame (1), the movable frame (62) is arranged on the left side of the first screw rod (61) in a threaded manner, the second gear motor (63) is arranged on the right part of the lower side of the inner part of the support frame (1), an output shaft of the second gear motor (63) is connected with the first screw rod (61), and the first distance sensor (64) is arranged in the middle of the rear side of the lower part of the movable frame (62); the storage mechanism (7) comprises a second screw rod (71), a transmission assembly (72), a third gear motor (73), all gears (74), a storage tank (75) and a liquid level sensor (76), wherein the second screw rod (71) is symmetrically arranged on the left side and the right side of the inner bottom of the movable frame (62) in a front-back symmetrical mode, the transmission assembly (72) is arranged between the lower sides of the second screw rod (71) on the left rear side and the right front side, the third gear motor (73) is arranged on the front part of the right side of the lower part of the movable frame (62), all gears (74) are arranged on the output shaft of the third gear motor (73) and the lower side of the second screw rod (71) on the right front side, all gears (74) are meshed with each other, the storage tank (75) is arranged between the upper sides of the second screw rod, and the liquid level sensor (76) is arranged in the middle of the inner bottom of the storage tank (75); the feeding mechanism (9) comprises a second storage box (91), an air pump (92), a first movable block (93), a first spring (94), a first supporting block (95), a second rotating shaft (96), a first movable plate (97), a second torsion spring (98), a photoelectric sensor (99) and a second cover (910), wherein the second storage box (91) is arranged on the right side of the supporting plate (3), the air pump (92) is arranged on the front portion of the right side of the second storage box (91), the first movable block (93) is arranged on the front portion of the interior of the second storage box (91) in a sliding manner, two first springs (94) are arranged between the front side of the first movable block (93) and the second storage box (91), two first supporting blocks (95) are arranged on the lower portion of the interior of the supporting plate (3), the second rotating shaft (96) is arranged between the first movable plate (97), the first movable plate (97) blocks the round hole, the second movable plate (97) is arranged between the inner side of the first movable plate and the first supporting block (95), the second movable plate (97) is arranged, the second torsion spring (91) is arranged on the middle portion of the interior of the second supporting block (95), and the second movable plate (95) is arranged on the middle portion of the second supporting plate (95); the rear part of the right side of the lower part of the supporting plate (3) is provided with a round hole, and the front side and the rear side of the left side of the lower part of the supporting plate (3) are provided with square holes; the heating mechanism (10) comprises a supporting rod (101), a second movable plate (102), a second spring (103), an electric push rod (104), a second movable block (105), a second distance sensor (106), a contact switch (107) and a heating tube (108), wherein two supporting rods (101) are arranged on the right side of the front side and the rear side of the inside of the supporting frame (1), the second movable plate (102) is slidably arranged between the upper sides of the supporting rods (101), four second springs (103) are arranged between the bottom of the second movable plate (102) and the supporting frame (1), the second springs (103) are wound on the supporting rods (101) on the same side, the electric push rod (104) is arranged on the upper right side of the inside of the supporting frame (1), the second movable block (105) is arranged on the telescopic rod of the electric push rod (104), the second distance sensor (106) is arranged on the lower right side of the inside of the supporting frame (1), the contact switch (107) is arranged on the front side of the right side of the lower part of the supporting frame (1), and the heating tube (108) is arranged on the front side and the inside of the second movable plate (102); the automatic feeding device is characterized by further comprising a feeding mechanism (8) for feeding raw materials, wherein the feeding mechanism (8) comprises a first storage box (81), a first cover (82), a first rotating shaft (83), a movable rod (84), a first torsion spring (85) and a stop block (86), the left side of the supporting plate (3) is provided with the first storage box (81), the front side and the rear side of the top of the first storage box (81) are respectively provided with the first cover (82) in a threaded manner, the front side and the rear side of the bottom of the first storage box (81) are respectively provided with the first rotating shaft (83), the upper side of the first rotating shaft (83) is respectively provided with the stop block (86), the lower side of the first rotating shaft (83) is respectively provided with the movable rod (84), the movable rod (84) is used for blocking the inner bottom of the first storage box (81), and the first torsion spring (85) is respectively arranged between the lower side of the movable rod (84) and the stop block (86) on the same side.

2. The electrode material mixing and separating device for the manufacturing potential ammonia sensor according to claim 1, further comprising a dust prevention mechanism (11) for preventing dust from falling, wherein the dust prevention mechanism (11) comprises a second supporting block (111), a third rotating shaft (112), a third movable plate (113) and a third torsion spring (114), the second supporting block (111) is arranged on the right side of the front side and the rear side of the upper portion of the supporting plate (3), the third rotating shaft (112) is rotatably arranged between the inner sides of the second supporting block (111), the third movable plate (113) is arranged on the third rotating shaft (112), and the third torsion spring (114) is arranged between the front side, the rear side and the second supporting block (111) on the same side.

3. The electrode material allocation and separation device for manufacturing the potential type ammonia sensor according to claim 2 is characterized in that a storage battery, a control module and a power module are arranged in the control box (2), the storage battery supplies power for the whole electrode material allocation and separation device for manufacturing the potential type ammonia sensor, a power master switch is connected to the power module through a circuit, the control module and the power module are electrically connected, a DS1302 clock circuit and a 24C02 circuit are connected to the control module, a first distance sensor (64), a liquid level sensor (76), a photoelectric sensor (99), a second distance sensor (106) and a contact switch (107) are electrically connected with the control module, and a first speed reducing motor (4), a second speed reducing motor (63), a third speed reducing motor (73), an electric push rod (104), an air pump (92) and a heating tube (108) are connected with the control module through peripheral circuits.

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