CN113750945B

CN113750945B - Antistatic agent production is with mixing compound cauldron

Info

Publication number: CN113750945B
Application number: CN202111113457.XA
Authority: CN
Inventors: 章德永; 王学军
Original assignee: Hangzhou Yongsheng Plastic Antistatic Material Factory
Current assignee: Hangzhou Yongsheng Plastic Antistatic Material Factory
Priority date: 2021-09-23
Filing date: 2021-09-23
Publication date: 2023-01-17
Anticipated expiration: 2041-09-23
Also published as: CN113750945A

Abstract

The invention discloses a mixing and compounding kettle for producing an antistatic agent, which relates to the technical field of antistatic agent production reaction kettles and comprises a base, wherein a first feeding component for adding raw materials and a detection component for detecting the resistance value of the antistatic agent are arranged on the base, a reaction component for generating the antistatic agent is arranged on the first feeding component, the detection component is arranged below the reaction component, and a second feeding component for adding an initiator is arranged on one side of the reaction component.

Description

Antistatic agent production is with mixing compound cauldron

Technical Field

The invention relates to the technical field of antistatic agent production reaction kettles, in particular to a mixing and compounding kettle for antistatic agent production.

Background

The antistatic agent is added into plastic or coated on the surface of a molded product to achieve the purpose of reducing static accumulation, the antistatic agent needs to be stirred and mixed in a reaction kettle in the production process, the reaction kettle is a container for comprehensive reaction, the traditional antistatic agent production reaction kettle has a complex structure, is inconvenient for people to operate and use, cannot control the flow rate of feeding, uses more driving parts, wastes energy, and needs to be transferred to special detection equipment for detection after the antistatic agent is produced, and the efficiency is low.

The patent with the application number of CN208372887U provides an antistatic agent production device, which comprises a box body, a water inlet is formed in one end of the top of the box body, a water outlet is formed in the bottom of the box body, when a first stirring device works, an output shaft of a rotating motor drives a first gear to rotate through a connecting belt, the first gear drives a second gear to rotate, the second gear drives a connecting block to rotate, the connecting shaft drives a concave stirring blade to rotate through the movement of the connecting block, in the movement of the first stirring device, the second stirring device drives a pulley to rotate through the output shaft of a servo motor, the pulley drives another pulley to rotate through a conveying belt, the conveying belt drives a connecting rod to move through the connecting plate, the connecting rod drives a movable plate to move inside the concave stirring blade, although the patent can uniformly stir, driving pieces used in the patent are more, the structure is more complex, meanwhile, the patent cannot control the feeding speed of raw materials, cannot detect in time after the antistatic agent is produced, and the efficiency is lower.

Disclosure of Invention

Aiming at the technical problem, the invention provides a mixing and compounding kettle for antistatic agent production, which comprises a base, wherein a first feeding component for adding raw materials and a detection component for detecting the resistance value of an antistatic agent are arranged on the base, a reaction component for generating the antistatic agent is arranged on the first feeding component, the detection component is arranged below the reaction component, a second feeding component for adding an initiator is arranged on one side of the reaction component, the first feeding component comprises an arc-shaped support plate I, a clamping plate unit and a feeding unit, the clamping plate unit and the arc-shaped support plate I are both arranged on the base, the clamping plate unit penetrates through the arc-shaped support plate I, the feeding unit is arranged on the arc-shaped support plate I, a pulling plate for adjusting the feeding flow velocity is arranged between the clamping plate unit and the feeding unit, and the feeding unit is connected with the reaction component, the reaction assembly comprises a temperature control unit, a stirring unit and a discharge control unit, the temperature control unit is installed on a first arc-shaped supporting plate, the temperature control unit comprises a reaction cylinder and a heating pipe, the reaction cylinder is installed on the first arc-shaped supporting plate, the heating pipe is installed on the reaction cylinder, a first supporting seat is installed on the reaction cylinder, a temperature measuring instrument and a sensor are arranged on the reaction cylinder, the stirring unit and the discharge control unit are both installed on the reaction cylinder, the stirring unit comprises a gear driving mechanism and a stirring mechanism, the gear driving mechanism is installed on the reaction cylinder, the stirring mechanism is connected with the gear driving mechanism, the stirring mechanism comprises a stirring frame and a rotating plate with a groove, the rotating plate with the groove is rotatably installed on the reaction cylinder, and the rotating plate with the groove is connected with the gear driving mechanism, stirring frame fixed mounting is on the trough of belt commentaries on classics board, install the protective housing in the reaction cylinder, fixed mounting has the material pump in the protective housing, be provided with inlet pipe and discharging pipe on the material pump, be provided with a plurality of feed inlets on the inlet pipe, material pump and gear drive mechanism are connected, material pump and feeding unit connection.

The discharging control unit comprises a fourth discharging pipe, a first magnetic block, a first supporting block, an inclined plane sliding plate, a second magnetic block, a discharging barrel, a shielding plate and a supporting rod, wherein the first supporting block is fixedly installed on the reaction barrel, the first magnetic block is slidably installed on the reaction barrel, a second spring is connected between the first magnetic block and the first supporting block, the second magnetic block is slidably installed in the reaction barrel, the second magnetic block corresponds to the first magnetic block in position, the discharging barrel is fixedly installed at the bottom of the reaction barrel, the third discharging pipe is fixedly installed at the bottom of the discharging barrel, the supporting rod is fixedly installed in the discharging barrel, a guide rod is fixedly installed on the supporting rod, two shielding plates are slidably installed on the guide rod, a third spring is connected between the shielding plate and the supporting rod, the inclined plane sliding plate is slidably connected with the shielding plates, inclined planes are arranged on the inclined plane sliding plate and the shielding plates, a discharging port is formed in the discharging barrel, the shielding plate is arranged above the discharging port of the discharging barrel, and a collecting device is connected to the third discharging pipe.

Further, the cardboard unit includes arc backup pad two and slide bar, two fixed mounting of arc backup pad are on the base, slide bar slidable mounting is on arc backup pad two, be connected with spring one between slide bar and the arc backup pad two, the one end of slide bar is provided with the knob, arm-tie and knob are connected, the feeding unit is including throwing workbin one, throwing workbin one is installed on supporting seat one, the last surface mounting who throws workbin one has the material feeding pipe, the side-mounting that throws workbin one has outflow pipe one, spring one, slide bar, knob, arm-tie, throw workbin one, material feeding pipe and outflow pipe one all are provided with a plurality ofly, be provided with the spout in throwing workbin one, arm-tie and throw workbin sliding connection, be provided with a plurality of rectangular shape cardboards on the slide bar, a plurality of rectangular shape cardboard evenly distributed, be provided with rectangular shape opening on the arc backup pad one.

Further, the second is thrown the material subassembly and is included the support frame and throw workbin two, the support frame with throw workbin two equal fixed mounting on supporting seat one, slidable mounting has the push pedal on throwing workbin two, throw and install the hot plate on the workbin two, push pedal and support frame sliding connection, be provided with a plurality of blanking mouths on the hot plate, hot plate and trough of belt commentaries on classics board are connected, be provided with the handle in the push pedal, throw workbin two side-mounting and have outlet pipe two, outlet pipe two and reaction cylinder are connected, and the material of hot plate is copper.

Further, gear drive mechanism includes the motor, takes tooth drum and gear shaft, motor fixed mounting is on the reaction cylinder, fixed mounting has the connecting axle on the output shaft of motor, connecting axle and reaction cylinder rotate to be connected, fixed mounting has gear one on the connecting axle, take tooth drum fixed mounting on the trough of belt commentaries on classics board, take fixed mounting to have gear two on the tooth drum, the gear shaft rotates to be installed on the trough of belt commentaries on classics board, the gear shaft is connected with the pump of drawing materials, fixed mounting has gear three on the gear shaft, gear three and gear two mesh are connected, gear one and take tooth drum mesh to be connected.

Further, the detecting component comprises a material taking unit and a detecting unit, the material taking unit is installed on the base, the detecting unit is installed on the material taking unit, the material taking unit comprises a second supporting seat, the second supporting seat is fixedly installed on the base, a detecting box is slidably installed on the second supporting seat, a push rod is fixedly installed on the detecting box, a blocking rod is slidably installed in the detecting box, a material inlet is formed in the detecting box, a connecting rod is slidably installed on the detecting box, a second supporting block is fixedly installed on the connecting rod, the fourth outflow pipe is connected with the second supporting block, a fourth spring is connected between the second supporting block and the detecting box, and the material inlet of the blocking rod on the detecting box is formed.

Further, the detecting unit comprises a first conductive column, a positive detecting rod, a negative detecting rod and a second conductive column, wherein the first positive detecting rod and the second negative detecting rod are installed on the detecting box, the first positive detecting rod and the second negative detecting rod are communicated with the inside of the detecting box, the first conductive column and the second conductive column are installed on the second supporting seat, a resistance tester is externally connected to the first positive detecting rod and the second negative detecting rod, the first positive detecting rod is electrified when the first positive detecting rod is connected with the first conductive column, the first positive detecting rod is electrified when the first positive detecting rod is separated from the second conductive column, the second negative detecting rod is electrified when the second negative detecting rod is connected with the second conductive column, and the second negative detecting rod is electrified when the second negative detecting rod is separated from the second conductive column.

Compared with the prior art, the invention has the beneficial effects that: (1) The reaction assembly drives the mixing, compounding and stirring of various raw materials and the initiator through one motor, so that energy is saved, the stirring is more sufficient, the reaction rate is improved, and meanwhile, the temperature of the reaction cylinder can be automatically controlled during the reaction, so that the reaction is more stable; (2) The first feeding assembly can adjust the feeding speed of the raw materials so as to meet the requirements of different feeding speeds; (3) The second feeding assembly can heat the initiator to melt the initiator from a solid state to a liquid state, so that the reaction efficiency is further improved; (4) The detection assembly can extract a sample in time for detection after the antistatic agent is generated, so that the detection efficiency is improved.

Drawings

FIG. 1 is an overall schematic view of the present invention.

FIG. 2 is an overall view of another aspect of the present invention.

FIG. 3 is a schematic top view of the present invention.

Fig. 4 is a schematic view of a first feeding assembly and a protective casing according to the present invention.

FIG. 5 is a first schematic view of a reaction module and a second feeding module according to the present invention.

FIG. 6 is an enlarged view of the area A in FIG. 5 according to the present invention.

FIG. 7 is a second schematic view of a reaction module and a second dosing module of the present invention.

FIG. 8 is a schematic view of a partial structure of a reaction module and a heating plate according to the present invention.

FIG. 9 is a schematic view showing a partial structure of a reaction module and a detection module according to the present invention.

FIG. 10 is an enlarged view of the invention at B of FIG. 9.

FIG. 11 is an enlarged view of FIG. 9 at C.

Reference numerals: 1-a base; 2-a first feeding assembly; 3-a second feeding assembly; 4-a reaction module; 5-a detection component; 201-arc supporting plate I; 202-spring one; 203-arc support plate II; 204-a slide bar; 205-a knob; 206-pulling plate; 207-feeding box I; 208-a feeding pipe; 209-outflow pipe one; 301-a support frame; 302-push plate; 303-feeding box II; 304-a heating plate; 305-outflow tube two; 401-a reaction cylinder; 402-outflow tube three; 403-outflow pipe four; 404-heating tubes; 405-magnetic block one; 406-spring two; 407-supporting block one; 408-supporting seat one; 409-a motor; 410-a connecting shaft; 411-gear one; 412-gear two; 413-toothed cylinder; 414-gear shaft; 415-gear three; 416-a pump; 417-stirring frame; 418-grooved rotating plate; 419-protective shell; 420-a bevel skateboard; 421-magnetic block two; 422-discharging cylinder; 423-shielding plate; 424-spring three; 425-a support bar; 426-a guide bar; 501-a second supporting seat; 502-a pushrod; 503-detection box; 504-conductive pillar one; 505-positive detection bar; 506-spring four; 507-negative pole test arm; 508-conducting pillar two; 509-a shutter lever; 510-a second support block; 511-connecting rod.

Detailed Description

The present invention will be further described with reference to specific examples, which are illustrative of the invention and are not to be construed as limiting the invention.

Example (b): referring to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, a mixing and compounding kettle for antistatic agent production includes a base 1, a first feeding component 2 for adding raw materials and a detecting component 5 for detecting resistance of antistatic agent are disposed on the base 1, a reaction component 4 for generating antistatic agent is disposed on the first feeding component 2, the detecting component 5 is disposed below the reaction component 4, a second feeding component 3 for adding initiator is disposed on one side of the reaction component 4, the first feeding component 2 includes a first arc-shaped supporting plate 201, a clamping plate unit and a feeding unit, the clamping plate unit and the first arc-shaped supporting plate 201 are both mounted on the base 1, the clamping plate unit passes through the first arc-shaped supporting plate 201, the feeding unit is mounted on the first arc-shaped supporting plate 201, a pulling plate 206 for adjusting flow rate of feeding is disposed between the clamping plate unit and a grooved feeding unit, the feeding unit and the reaction component 4 are connected, the reaction component 4 includes a temperature control unit, a stirring unit and a discharging control unit, the temperature control unit is mounted on the first arc-shaped supporting plate 201, the stirring unit is mounted on a stirring mechanism 401, the stirring mechanism 401 and a stirring mechanism is mounted on a stirring cylinder 401, the stirring mechanism and a stirring mechanism is mounted on a stirring cylinder 401, the heating cylinder 401 and a stirring mechanism 401, the stirring mechanism 401 and a stirring mechanism mounted on a stirring cylinder 401, the grooved rotating plate 418 is connected with a gear driving mechanism, the stirring frame 417 is fixedly installed on the grooved rotating plate 418, the reaction cylinder 401 is internally provided with a protective shell 419, the protective shell 419 is internally and fixedly provided with a pumping pump 416, the pumping pump 416 is provided with a feeding pipe and a discharging pipe, the feeding pipe is provided with a plurality of feeding ports, the pumping pump 416 is connected with the gear driving mechanism, and the pumping pump 416 is connected with a feeding unit.

As shown in fig. 1 to 4, the clamping plate unit includes an arc-shaped support plate two 203 and a slide bar 204, the arc-shaped support plate two 203 is fixedly installed on the base 1, the slide bar 204 is slidably installed on the arc-shaped support plate two 203, a spring one 202 is connected between the slide bar 204 and the arc-shaped support plate two 203, one end of the slide bar 204 is provided with a knob 205, the pull plate 206 is connected with the knob 205, the feeding unit includes a feeding box one 207, the feeding box one 207 is installed on a support base one 408, the upper surface of the feeding box one 207 is provided with a feeding pipe 208, the side surface of the feeding box one 207 is provided with an outflow pipe one 209, the spring one 202, the slide bar 204, the knob 205, the pull plate 206, the feeding box one 207, the feeding pipe 208 and the outflow pipe one 209 are all provided with a plurality of elongated clamping plates, the feeding box one 207 is internally provided with a sliding chute, the pull plate 206 is slidably connected with the feeding box one 207, the slide bar 204 is provided with a plurality of elongated clamping plates, the elongated clamping plates are uniformly distributed, and the arc-shaped support plate one 201 is provided with an elongated opening.

As shown in fig. 5-8, the second feeding assembly 3 includes a supporting frame 301 and a second feeding box 303, the supporting frame 301 and the second feeding box 303 are both fixedly mounted on a first supporting seat 408, a push plate 302 is slidably mounted on the second feeding box 303, a heating plate 304 is mounted on the second feeding box 303, the push plate 302 is slidably connected with the supporting frame 301, a plurality of blanking ports are disposed on the heating plate 304, the heating plate 304 is connected with a rotating plate 418 with grooves, a handle is disposed on the push plate 302, a second outflow pipe 305 is mounted on a side surface of the second feeding box 303, the second outflow pipe 305 is connected with the reaction cylinder 401, and the heating plate 304 is made of copper.

As shown in fig. 1 to 11, the discharging control unit includes a fourth discharging pipe 403, a first magnetic block 405, a first supporting block 407, an inclined sliding plate 420, a second magnetic block 421, a discharging cylinder 422, a shielding plate 423 and a supporting rod 425, the first supporting block 407 is fixedly mounted on the reaction cylinder 401, the first magnetic block 405 is slidably mounted on the reaction cylinder 401, a second spring 406 is connected between the first magnetic block 405 and the first supporting block 407, the second magnetic block 421 is slidably mounted in the reaction cylinder 401, the positions of the second magnetic block 421 and the first magnetic block 405 correspond to each other, the discharging cylinder 422 is fixedly mounted at the bottom of the reaction cylinder 401, a third discharging pipe 402 is fixedly mounted at the bottom of the discharging cylinder 422, the supporting rod 425 is fixedly mounted with a guiding rod 426, two shielding plates 423 are slidably mounted on the guiding rod 426, a third spring 424 is connected between the shielding plates 423 and the supporting rod 425, the inclined sliding plate 420 and the shielding plate 423 are slidably connected, inclined surfaces are both arranged on the inclined sliding plate 420 and the shielding plate 423, a discharging port is arranged on the discharging cylinder 422, a discharging port 423 is arranged on the discharging cylinder 422, and a collecting device is connected to the third discharging pipe 402.

The gear driving mechanism comprises a motor 409, a toothed cylinder 413 and a gear shaft 414, the motor 409 is fixedly installed on the reaction cylinder 401, a connecting shaft 410 is fixedly installed on an output shaft of the motor 409, the connecting shaft 410 is rotatably connected with the reaction cylinder 401, a first gear 411 is fixedly installed on the connecting shaft 410, the toothed cylinder 413 is fixedly installed on a grooved rotating plate 418, a second gear 412 is fixedly installed on the toothed cylinder 413, the gear shaft 414 is rotatably installed on the grooved rotating plate 418, the gear shaft 414 is connected with a material pumping pump 416, a third gear 415 is fixedly installed on the gear shaft 414, the third gear 415 is meshed with the second gear 412, and the first gear 411 is meshed with the toothed cylinder 413.

As shown in fig. 1, 9 and 11, wherein the detecting assembly 5 includes a material taking unit and a detecting unit, the material taking unit is installed on the base 1, the detecting unit is installed on the material taking unit, the material taking unit includes a second supporting seat 501, the second supporting seat 501 is fixedly installed on the base 1, a detecting box 503 is slidably installed on the second supporting seat 501, a push rod 502 is fixedly installed on the detecting box 503, a blocking rod 509 is slidably installed on the detecting box 503, a material inlet is formed in the detecting box 503, a connecting rod 511 is slidably installed on the detecting box 503, a second supporting block 510 is fixedly installed on the connecting rod 511, a fourth outflow pipe 403 is connected with the second supporting block 510, a fourth spring 506 is connected between the second supporting block 510 and the detecting box 503, and the blocking rod 509 is arranged at the material inlet on the detecting box 503.

The detection unit comprises a first conductive column 504, a positive detection rod 505, a negative detection rod 507 and a second conductive column 508, wherein the positive detection rod 505 and the negative detection rod 507 are both installed on the detection box 503, meanwhile, the positive detection rod 505 and the negative detection rod 507 are both communicated with the inside of the detection box 503, the first conductive column 504 and the second conductive column 508 are both installed on the second support seat 501, a resistance tester is externally connected to the positive detection rod 505 and the negative detection rod 507, when the positive detection rod 505 is connected with the first conductive column 504, the positive detection rod 505 is powered on, when the positive detection rod 505 is separated from the first conductive column 504, the positive detection rod 505 is powered off, when the negative detection rod 507 is connected with the second conductive column 508, the negative detection rod 507 is powered on, and when the negative detection rod 507 is separated from the second conductive column 508, the negative detection rod 507 is powered off.

The working principle of the invention is as follows: a user injects different raw materials into different charging boxes 207 from different charging pipes 208 according to a formula, pushes the push plate 302 away from the charging box two 303 by pushing a handle on the push plate 302, adds a solid initiator into the charging box two 303, pulls the handle on the push plate 302 to pull the push plate 302 back to the original position to cover the charging box two 303, initially, the pull plate 206 separates the charging box one 207 (the raw materials fall on the pull plate 206 in the charging box one 207), pulls the pull plate 206, the pull plate 206 slides in the charging box one 207, so that the raw materials in the charging box one 207 flow into the feeding pipe on the extraction pump 416 from the outflow pipe one 209, the pull plate 206 drives the slide bar 204 to slide on the arc-shaped support plates two 203 by the knob 205 when sliding, simultaneously, the spring one 202 compresses, so that the strip-shaped clamping plate on the slide bar 204 moves out from the opening on the arc-shaped support plate one 201, the knob 205, the slide bar 205 drives the clamping plate to rotate by the slide bar 204, so that the strip-shaped clamping plate is clamped on the arc-shaped support plate 201, when the arc-shaped support plate 201 is clamped, the slide, the flow velocity of the strip-shaped support plate 207 does not change, the flow velocity of the discharge pipe 207, the flow velocity of the strip-shaped support plate 207 changes, and the flow velocity of the strip-shaped support plate 207 changes, so that the strip-shaped support plate 207 moves to the discharge flow velocity of the strip-shaped support plate 201 in the discharge pipe 201, the strip-shaped support plate 207 and the strip-shaped support plate 207 changes, the flow velocity of the strip-shaped support plate 207.

The temperature measuring instrument on the reaction cylinder 401 measures the temperature, when the temperature (the temperature is set according to the requirement), the sensor on the reaction cylinder 401 sends out a power-on signal, the power-on makes the heating pipe 404 generate heat to heat the reaction cylinder 401, when the temperature is high, the sensor on the reaction cylinder 401 sends out a power-off signal, the power-off stops heating, thereby ensuring that the temperature in the reaction cylinder 401 reaches the requirement, the motor 409 is started, the output shaft of the motor 409 drives the first gear 411 to rotate through the connecting shaft 410, the first gear 411 drives the toothed cylinder 413 to rotate, the second gear 413 drives the second gear 412 to rotate, the second gear 412 drives the gear shaft 414 to rotate through the third gear 415, the toothed cylinder 413 drives the grooved rotating plate 418 to rotate, when the grooved rotating plate 418 rotates, the friction heating plate 304 (the friction heating plate 304 on one hand when the grooved rotating plate 418 rotates, on the other hand, because the reaction cylinder has high temperature, the heat is transferred to the heating plate 304 to generate heat through the friction rotation of the grooved rotating plate 418), so that the heating plate 304 generates heat, when the heating plate 304 generates heat, the solid initiator is melted into the liquid initiator, the liquid initiator flows out from a blanking port on the heating plate 304 and flows into the reaction cylinder 401 through the second outflow pipe 305, the gear shaft 414 drives the pumping pump 416 to work when rotating, the pumping pump 416 pumps the raw material in the feeding pipe into the reaction cylinder 401 through the discharging pipe, when the grooved rotating plate 418 rotates, the stirring frame 417 rotates, when the stirring frame 417 rotates, the raw material and the initiator in the reaction cylinder 401 are stirred, so that the raw material and the initiator fully react to generate the antistatic agent.

After the reaction is carried out for a period of time (the time is set according to the requirement), the first magnetic block 405 is pulled, the first magnetic block 405 drives the second magnetic block 421 to move through magnetic force, the second magnetic block 421 drives the inclined sliding plate 420 to move, the inclined sliding plate 420 drives the shielding plate 423 to slide on the guide rod 426 when moving, meanwhile, the third spring 424 is compressed, the shielding plate 423 moves away from the discharge opening on the discharge barrel 422 when sliding, the antistatic agent generated in the reaction barrel 401 flows into the third outflow pipe 402 from the discharge opening on the discharge barrel 422, and the antistatic agent flows into the collection device from the third outflow pipe 402.

When the resistance of the antistatic agent needs to be detected, the push rod 502 is pushed, the push rod 502 drives the detection box 503 to slide, the detection box 503 drives the positive detection rod 505 and the negative detection rod 507 to move when sliding, the positive detection rod 505 and the negative detection rod 507 are separated from the first conductive column 504 and the second conductive column 508 respectively, when sliding on the second support seat 501 and the connection rod 511, the fourth spring 506 is compressed, due to the limitation of the fourth outflow pipe 403, the second support block 510 and the shielding rod 509 do not move, so that the feeding port of the detection box 503 is separated from the shielding rod 509, at the moment, the feeding port on the detection box 503 moves to the lower part of the fourth outflow pipe 403, the antistatic agent generated by reaction flows into the detection box 503 from the fourth outflow pipe 403, after flowing for a period of time (time is set according to requirements), the push rod 502 is released, the fourth spring 506 drives the detection box 503 to return to the original position through elasticity, the positive detection rod 505 is connected with the first conductive column 504, the negative detection rod 507 is connected with the second conductive column 508, so that the positive detection rod 505 and the resistance of the antistatic agent is electrified, the resistance is detected by the resistance tester, when the production is qualified, the production of the antistatic agent is detected, and the formula is checked, and whether the antistatic agent is checked.

Claims

1. The utility model provides an antistatic agent production is with mixing compound cauldron, includes the base, its characterized in that:

the base is provided with a first feeding component for adding raw materials and a detection component for detecting the resistance value of the antistatic agent, the first feeding component is provided with a reaction component for generating the antistatic agent, the detection component is arranged below the reaction component, and one side of the reaction component is provided with a second feeding component for adding an initiator; the first feeding assembly comprises an arc-shaped support plate I, a clamping plate unit and a feeding unit, the clamping plate unit and the arc-shaped support plate I are both arranged on the base, the clamping plate unit penetrates through the arc-shaped support plate I, the feeding unit is arranged on the arc-shaped support plate I, a pulling plate used for adjusting the feeding flow rate is arranged between the clamping plate unit and the feeding unit, and the feeding unit is connected with the reaction assembly; the reaction assembly comprises a temperature control unit, a stirring unit and a discharging control unit, the temperature control unit is installed on a first arc-shaped supporting plate and comprises a reaction cylinder and a heating pipe, the reaction cylinder is installed on the first arc-shaped supporting plate, the heating pipe is installed on the reaction cylinder, a first supporting seat is installed on the reaction cylinder, a temperature measuring instrument and a sensor are arranged on the reaction cylinder, and the stirring unit and the discharging control unit are installed on the reaction cylinder; the stirring unit comprises a gear driving mechanism and a stirring mechanism, the gear driving mechanism is installed on the reaction cylinder, the stirring mechanism is installed on the reaction cylinder and is connected with the gear driving mechanism, the stirring mechanism comprises a stirring frame and a trough rotating plate, the trough rotating plate is rotatably installed on the reaction cylinder and is connected with the gear driving mechanism, the stirring frame is fixedly installed on the trough rotating plate, a protective shell is installed in the reaction cylinder, a pumping pump is fixedly installed in the protective shell and is provided with a feeding pipe and a discharging pipe, the feeding pipe is provided with a plurality of feeding ports, the pumping pump is connected with the gear driving mechanism, and the pumping pump is connected with the feeding unit; the discharging control unit comprises a third outlet pipe, a first magnetic block, a first supporting block, an inclined plane sliding plate, a second magnetic block, a discharging barrel, a shielding plate and a supporting rod, wherein the first supporting block is fixedly arranged on the reaction barrel;

the clamping plate unit comprises an arc-shaped supporting plate II and a sliding rod, the arc-shaped supporting plate II is fixedly mounted on a base, the sliding rod is slidably mounted on the arc-shaped supporting plate II, a spring I is connected between the sliding rod and the arc-shaped supporting plate II, a knob is arranged at one end of the sliding rod, a pulling plate is connected with the knob, the feeding unit comprises a feeding box I, the feeding box I is mounted on a supporting seat I, a feeding pipe is mounted on the upper surface of the feeding box I, an outflow pipe I is mounted on the side surface of the feeding box I, the spring I, the sliding rod, the knob, the pulling plate, the feeding box I, the feeding pipe and the outflow pipe I are all provided with a plurality of elongated clamping plates which are uniformly distributed, and elongated openings are formed in the arc-shaped supporting plate I;

the second feeding assembly comprises a support frame and a feeding box II, the support frame and the feeding box II are both fixedly mounted on the support base I, a push plate is slidably mounted on the feeding box II, a heating plate is mounted on the feeding box II, the push plate is slidably connected with the support frame, a plurality of blanking ports are arranged on the heating plate, the heating plate is connected with a rotating plate with a groove, a handle is arranged on the push plate, two outflow pipes II are mounted on two sides of the feeding box, the outflow pipes II are connected with the reaction cylinder, and the heating plate is made of copper;

the detection assembly comprises a material taking unit and a detection unit, the material taking unit is installed on the base, the detection unit is installed on the material taking unit, the material taking unit comprises a second supporting seat, the second supporting seat is fixedly installed on the base, a detection box is installed on the second supporting seat in a sliding mode, a push rod is fixedly installed on the detection box, a blocking rod is installed in the detection box in a sliding mode, a material inlet is formed in the detection box, a connecting rod is installed on the detection box in a sliding mode, a second supporting block is fixedly installed on the connecting rod, a fourth outflow pipe is connected with the second supporting block, a fourth spring is connected between the second supporting block and the detection box, and the blocking rod is arranged at the material inlet on the detection box;

the detecting unit is including leading electrical pillar one, anodal measuring stick, negative pole measuring stick and leading electrical pillar two, anodal measuring stick and negative pole measuring stick are all installed on the detection case, and anodal measuring stick and negative pole measuring stick all communicate with the detection case is inside simultaneously, it all installs on supporting seat two to lead electrical pillar one and lead electrical pillar two, external resistance tester that has gone up on anodal measuring stick and the negative pole measuring stick, when anodal measuring stick and lead electrical pillar one and connect, the positive pole measuring stick circular telegram, when anodal measuring stick and lead electrical pillar one and separate, the outage of anodal measuring stick, when the negative pole measuring stick and lead electrical pillar two and connect, the negative pole measuring stick circular telegram, when the negative pole measuring stick with lead electrical pillar two and separate, the outage of negative pole measuring stick.

2. The mixing and compounding kettle for antistatic agent production as claimed in claim 1, wherein: gear drive mechanism includes the motor, takes tooth drum and gear shaft, motor fixed mounting is on the reaction cylinder, fixed mounting has the connecting axle on the output shaft of motor, connecting axle and reaction cylinder rotate to be connected, fixed mounting has gear one on the connecting axle, take tooth drum fixed mounting on the trough of belt commentaries on classics board, take fixed mounting to have gear two on the tooth drum, the gear shaft rotates to be installed on the trough of belt commentaries on classics board, the gear shaft is connected with the material pump of taking out, fixed mounting has gear three on the gear shaft, gear three and the meshing of gear two are connected, gear one and the meshing of taking tooth drum are connected.