阅读说明：本技术 一种超韧的高性能工程塑料生产方法 (Production method of super-tough high-performance engineering plastic ) 是由 孟凡芹 于 2021-08-31 设计创作，主要内容包括：本发明提供一种超韧的高性能工程塑料生产方法,所述超韧的高性能工程塑料生产方法通过使用高性能工程塑料生产设备来实现超韧的高性能工程塑料的生产,提高了生产效率；所述高性能工程塑料生产设备包括：工作台；所述工作台为矩形空腔结构,且工作台顶端后侧设有混料箱,并且混料箱下方设有收料槽。本发明中由气缸提供动力,使滑动板沿着滑槽和滑杆上下滑动,通过压板对垫板上的物料进行挤压,当滑动板滑动时,利用推杆推动收料槽以轴杆为轴心进行弧线运动,避免物料粘附在收料槽内壁。(The invention provides a production method of super-tough high-performance engineering plastic, which realizes the production of the super-tough high-performance engineering plastic by using high-performance engineering plastic production equipment, thereby improving the production efficiency; the high-performance engineering plastic production equipment comprises: a work table; the workstation is rectangle cavity structure, and workstation top rear side is equipped with the mixing box to the mixing box below is equipped with receives the silo. According to the invention, the air cylinder provides power to enable the sliding plate to slide up and down along the sliding chute and the sliding rod, the pressing plate is used for extruding materials on the backing plate, and when the sliding plate slides, the push rod is used for pushing the material receiving groove to do arc motion by taking the shaft rod as an axis, so that the materials are prevented from being adhered to the inner wall of the material receiving groove.)

1. A method for producing super-tough high-performance engineering plastics is characterized by comprising the following steps: the production method of the super-tough high-performance engineering plastic realizes the production of the super-tough high-performance engineering plastic by using high-performance engineering plastic production equipment, thereby improving the production efficiency; the high-performance engineering plastic production equipment comprises:

a work table;

the workbench is of a rectangular cavity structure, a mixing box is arranged on the rear side of the top end of the workbench, and a material receiving groove is arranged below the mixing box;

the front end of the material receiving groove is provided with a support frame, an air heater is arranged below the material receiving groove, and the material receiving groove is connected with the air heater through a connecting assembly;

the supporting frame is fixedly connected with the bottom of the cavity of the workbench, a material guide frame is arranged in front of the supporting frame, and a hob is rotatably mounted on the material guide frame;

the mixing box comprises a first motor, a feeding hole and a first discharging hole, the mixing box is of a cylindrical cavity structure, the rear end of the mixing box is provided with the first motor, the top end of the mixing box is provided with the feeding hole, the bottom of the front end of the mixing box is provided with the first discharging hole, and the first discharging hole is located above the material receiving groove.

2. The method for producing super tough high performance engineering plastics according to claim 1, wherein the mixing box further comprises a partition screen plate, an annular frame, connecting rods, a mounting frame and stirring plates, wherein the partition screen plate is arranged in the cavity of the mixing box and is of an annular net structure, two annular frames are arranged on the inner side of the partition screen plate and are connected with the rotating rod through the connecting rods, the rotating rod is connected with a rotating shaft of the first motor, the mounting frame is rotatably arranged between the connecting rods on the front side and the rear side, the stirring plates are arranged in the mounting frame and are distributed in an annular array manner;

receive the silo and include axostylus axostyle and push rod, receive the silo and be V type cross-section cavity structure, and receive silo bottom minimum bore department and be connected with coupling assembling, receive the silo left and right sides and be equipped with the axostylus axostyle, and receive the silo and rotate with the workstation through the axostylus axostyle and be connected, receive the silo front end and be equipped with the push rod, and the push rod rotates with receiving the silo through the round pin axle and is connected to the push rod is connected with the support frame.

3. The method for producing the super-tough high-performance engineering plastic according to claim 2, wherein the support frame comprises an air cylinder, a cushion plate, a chute and a slide bar, the support frame is of a rectangular frame structure, the air cylinder is fixedly mounted on a top plate of the support frame, a rectangular through groove is formed in the middle of two vertical plates on the left and right of the support frame, the chutes are formed in the front side wall and the rear side wall of the rectangular through groove, the slide bar is vertically mounted in the rectangular through groove, the cushion plate is fixedly mounted between the two vertical plates on the support frame and close to the bottom of the support frame, and the cushion plate is flush with the discharge surface of the material guide frame;

the support frame still includes sliding plate, slider and clamp plate, and the sliding plate sets up in the backing plate top, and sliding plate and backing plate are parallel mode and distribute to the sliding plate rotates through round pin axle and push rod to be connected, and both ends all are equipped with the slider about the sliding plate, and the sliding plate bottom is equipped with the clamp plate, and both ends about the sliding plate are run through in the slide bar slip, and the sliding plate passes through slider and spout sliding connection.

4. The method for producing super tough high performance engineering plastics according to claim 3, wherein the guide frame comprises a guide roller, a driving gear, a cutting pad roller and a driven gear, the guide frame is provided with the guide roller, the driving roller and the cutting pad roller, which are all rotatably connected with the guide frame through bearings, the driving gear and the driven gear are respectively arranged at the left ends of the driving roller and the cutting pad roller, the driving gear is meshed with the driven gear, and the cutting pad roller and the hob are distributed in parallel;

the hobbing cutter comprises a first belt wheel, a belt, a second motor and a second belt wheel, the hobbing cutter is rotatably connected with the material guide frame through a bearing, the right end of the hobbing cutter is provided with the first belt wheel, the second motor is fixedly installed inside the workbench, a rotating shaft of the second motor is provided with the second belt wheel, and the second belt wheel is in transmission connection with the first belt wheel through the belt.

5. The method for producing super tough high performance engineering plastics according to claim 1, wherein the hot air blower comprises a heating box and a second discharge port, the hot air blower is fixedly installed at the bottom of the cavity of the workbench, the heating box is arranged at the front end of the hot air blower, the heating box is communicated with the hot air blower through a conduit, the connecting assembly is arranged at the top end of the heating box, the second discharge port is arranged at the front end of the heating box, and the second discharge port is matched with the backing plate;

coupling assembling includes connecting pipe, elastic hose and resumes the spring, and the connecting pipe is upper and lower symmetrical mode subsection for two, and two connecting pipes are connected through elastic hose, and elastic hose the place ahead is equipped with resumes the spring, and resumes the spring support between two connecting pipes.

Technical Field

The invention belongs to the technical field of engineering plastics, and particularly relates to a production method of super-tough high-performance engineering plastics.

Background

High performance engineering plastics are also called heat-resistant engineering resins (plastics). The heat-resistant grade and the mechanical strength of the synthetic resin (plastic) are higher than those of general engineering plastics, such as polyphenylene sulfide, polysulfone, polyarylsulfone, polyethersulfone, polyetherketone, polyetheretherketone, polyetherketoneketone, polyphenylene sulfide ketone, polyphenylene sulfide amide, poly-p-hydroxybenzoate, fluorine-containing resin, aromatic heterocyclic resin and the like. The processing property is inferior to general engineering plastics due to higher melting temperature and melt viscosity, and some engineering plastics need to be formed and processed by special methods or improved in formability by modification. Is mainly used in high and new technical fields or special occasions. For example, application No.: the invention of CN202010743846.X discloses a production method of ABS engineering plastic.

Present super tough high performance engineering plastics production method is when using, when mixing the in-process to plastics raw materials and auxiliary material, takes place the adhesion easily in the compounding case, makes the compounding effect relatively poor, and the material is when getting into the collecting vat in addition, because electrostatic influence, the material can the adhesion receive the silo inner wall, leads to the collecting vat to obtain the material mouth and takes place to block up, and equipment need adopt a plurality of actuating mechanism to carry out ejection of compact and blank usually, is not convenient for reach accurate control, and manufacturing cost is higher.

Disclosure of Invention

In order to solve the technical problems, the invention provides a production method of super-tough high-performance engineering plastic, which aims to solve the problems that when the existing production method of super-tough high-performance engineering plastic is used, in the process of mixing plastic raw materials and auxiliary materials, the raw materials and the auxiliary materials are easy to adhere to each other in a mixing box, so that the mixing effect is poor, and when the materials enter a collecting tank, the materials are adhered to the inner wall of a material receiving tank due to electrostatic influence, so that a material outlet of the collecting tank is blocked, and generally, a plurality of driving mechanisms are needed for discharging and cutting the materials, so that the accurate control is not convenient to achieve, and the manufacturing cost is high.

The invention is achieved by the following specific technical means:

a production method of super-tough high-performance engineering plastics realizes the production of the super-tough high-performance engineering plastics by using high-performance engineering plastics production equipment, and improves the production efficiency; the high-performance engineering plastic production equipment comprises:

a work table; the workbench is of a rectangular cavity structure, a mixing box is arranged on the rear side of the top end of the workbench, and a material receiving groove is arranged below the mixing box; the front end of the material receiving groove is provided with a support frame, an air heater is arranged below the material receiving groove, and the material receiving groove is connected with the hot air heater through a connecting assembly; the support frame is fixedly connected with the bottom of the cavity of the workbench, a material guide frame is arranged in front of the support frame, and a hob is rotatably mounted on the material guide frame.

The mixing box comprises a first motor, a feeding hole and a first discharging hole, the mixing box is of a cylindrical cavity structure, the rear end of the mixing box is provided with the first motor, the top end of the mixing box is provided with the feeding hole, the bottom of the front end of the mixing box is provided with the first discharging hole, and the first discharging hole is located above the material receiving groove.

Further, the mixing box is still including separating otter board, annular frame, connecting rod, mounting bracket and stirring board, is equipped with in the mixing box cavity and separates the otter board, and separates the otter board and be annular network structure, separates the otter board inboard and is equipped with two annular frames, and the annular frame is connected with the bull stick through the connecting rod to the bull stick is connected with the pivot of first motor, rotates between the connecting rod of front and back both sides and installs the mounting bracket, and is equipped with the stirring board in the mounting bracket, and stirs the board and be the annular array mode and distribute.

Receive the silo and include axostylus axostyle and push rod, receive the silo and be V type cross-section cavity structure, and receive silo bottom minimum bore department and be connected with coupling assembling, receive the silo left and right sides and be equipped with the axostylus axostyle, and receive the silo and rotate with the workstation through the axostylus axostyle and be connected, receive the silo front end and be equipped with the push rod, and the push rod rotates with receiving the silo through the round pin axle and is connected to the push rod is connected with the support frame.

Further, the support frame includes cylinder, backing plate, spout and slide bar, and the support frame is the rectangular frame structure, and fixed mounting has the cylinder on the roof of support frame, and two riser intermediate positions are equipped with the rectangle and lead to the groove about the support frame, and the rectangle leads to the groove front and back both sides wall and all seted up the spout to the rectangle leads to the inslot vertical slide bar of installing, is close to bottom fixed mounting between the riser of support frame two and has the backing plate, and the backing plate keeps level with the guide frame discharge surface mutually.

The support frame still includes sliding plate, slider and clamp plate, and the sliding plate sets up in the backing plate top, and sliding plate and backing plate are parallel mode and distribute to the sliding plate rotates through round pin axle and push rod to be connected, and both ends all are equipped with the slider about the sliding plate, and the sliding plate bottom is equipped with the clamp plate, and both ends about the sliding plate are run through in the slide bar slip, and the sliding plate passes through slider and spout sliding connection.

Further, the guide frame includes guide roller, driving gear, cutting pad roller and driven gear, is equipped with guide roller, driving roller and cutting pad roller on the guide frame, and it all rotates with the guide frame through the bearing to be connected, and driving roller and cutting pad roller left end are equipped with driving gear and driven gear respectively, and the driving gear is connected with the driven gear meshing to cutting pad roller is parallel mode with the hobbing cutter and distributes.

The hobbing cutter comprises a first belt wheel, a belt, a second motor and a second belt wheel, the hobbing cutter is rotatably connected with the material guide frame through a bearing, the right end of the hobbing cutter is provided with the first belt wheel, the second motor is fixedly installed inside the workbench, a rotating shaft of the second motor is provided with the second belt wheel, and the second belt wheel is in transmission connection with the first belt wheel through the belt.

Further, the air heater includes heating cabinet and second discharge gate, and air heater fixed mounting is in workstation cavity bottom, and the air heater front end is equipped with the heating cabinet, and the heating cabinet communicates with each other with the air heater through the pipe, and coupling assembling sets up in the heating cabinet top, and the heating cabinet front end is equipped with the second discharge gate, and second discharge gate and backing plate phase-match.

Coupling assembling includes connecting pipe, elastic hose and resumes the spring, and the connecting pipe is upper and lower symmetrical mode subsection for two, and two connecting pipes are connected through elastic hose, and elastic hose the place ahead is equipped with resumes the spring, and resumes the spring support between two connecting pipes.

Compared with the prior art, the invention has the following beneficial effects:

1. because the inner side of the partition screen plate is provided with two annular frames which are connected with the rotating rod through the connecting rods, the rotating rod is connected with the rotating shaft of the first motor, the mounting frame is rotatably mounted between the connecting rods on the front side and the rear side, the stirring plates are arranged in the mounting frame and distributed in an annular array mode, the device is powered by the first motor, the mounting frame is driven to rotate through the annular frames and the connecting rods, the stirring plates are used for mixing materials in the partition screen plate, the stirring plates are rotated, the occurrence of adhesion is reduced, and the material mixing efficiency is ensured;

2. the sliding plate is provided with the sliding blocks at the left end and the right end, the bottom end of the sliding plate is provided with the pressing plate, the sliding rods penetrate through the left end and the right end of the sliding plate in a sliding mode, and the sliding plate is connected with the sliding chute in a sliding mode through the sliding blocks;

3. because second motor fixed mounting is inside the workstation, and is equipped with the second band pulley in the pivot of second motor to the second band pulley passes through the belt and is connected with first band pulley transmission, and this device is provided power by the second motor, makes driving roller and second band pulley rotate, utilizes driving gear and driven gear to drive the cutting pad roller and rotates, utilizes belt and second band pulley to drive the hobbing cutter rotation simultaneously, thereby realizes ejection of compact and blank process, simple structure, and flexible operation.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.

Drawings

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

Fig. 2 is a schematic diagram of the right-view cross-sectional viewing angle structure of the present invention.

FIG. 3 is a schematic view of the structure of the mixing box of the present invention.

FIG. 4 is a schematic diagram of the internal structure of the mixing box from FIG. 3.

Fig. 5 is a schematic structural diagram of the material receiving groove and the hot air blower of the invention.

Fig. 6 is an enlarged view of the portion a in fig. 5 according to the present invention.

Fig. 7 is a schematic view of the supporting frame structure of the present invention.

Fig. 8 is a schematic view of the guide and hob structure of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a work table; 2. a mixing box; 201. a first motor; 202. a feed inlet; 203. a first discharge port; 204. separating the mesh plate; 205. an annular frame; 206. a connecting rod; 207. a mounting frame; 208. stirring the plate; 3. a material receiving groove; 301. a shaft lever; 302. a push rod; 4. a support frame; 401. a cylinder; 402. a base plate; 403. a chute; 404. a slide bar; 405. a sliding plate; 406. a slider; 407. pressing a plate; 5. a material guide frame; 501. a material guide roller; 502. a driving roller; 503. a driving gear; 504. cutting the pad roller; 505. a driven gear; 6. hobbing cutters; 601. a first pulley; 602. a belt; 603. a second motor; 604. a second pulley; 7. a hot air blower; 701. a heating box; 702. a second discharge port; 8. a connecting assembly; 801. a connecting pipe; 802. an elastic hose; 803. the spring is restored.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 8:

the invention provides a production method of super-tough high-performance engineering plastic, which realizes the production of the super-tough high-performance engineering plastic by using high-performance engineering plastic production equipment, thereby improving the production efficiency; the high-performance engineering plastic production equipment comprises: a work table 1; the workbench 1 is of a rectangular cavity structure, a mixing box 2 is arranged on the rear side of the top end of the workbench 1, and a material receiving groove 3 is arranged below the mixing box 2; the front end of the material receiving groove 3 is provided with a support frame 4, an air heater 7 is arranged below the material receiving groove 3, and the material receiving groove 3 is connected with the hot air heater 7 through a connecting assembly 8; the air heater 7 comprises a heating box 701 and a second discharge hole 702, the air heater 7 is fixedly arranged at the bottom of the cavity of the workbench 1, the heating box 701 is arranged at the front end of the air heater 7, the heating box 701 is communicated with the air heater 7 through a guide pipe, the connecting assembly 8 is arranged at the top end of the heating box 701, the second discharge hole 702 is arranged at the front end of the heating box 701, and the second discharge hole 702 is matched with the backing plate 402; the connecting assembly 8 comprises a connecting pipe 801, an elastic hose 802 and a restoring spring 803, wherein the connecting pipe 801 is divided into two parts in a vertically symmetrical manner, the two connecting pipes 801 are connected through the elastic hose 802, the restoring spring 803 is arranged in front of the elastic hose 802, and the restoring spring 803 is supported between the two connecting pipes 801; support frame 4 and 1 cavity bottom fixed connection of workstation, and 4 the place ahead of support frame are equipped with guide frame 5 to rotate on the guide frame 5 and install hobbing cutter 6.

The standard hot air blower is a preferred product for upgrading and updating modern industrial heat sources, which is developed by self on the basis of full learning of international leading technology, is widely applied to various industries such as electronics, food, pharmacy, printing, packaging, cleaning and heat treatment … …, has a very good application prospect, and is the optimal hot air source configuration of automation machinery in the hot air drying industry.

The continuous use temperature can reach 350 ℃/450 ℃/500 ℃, and the application is wide; the multi-fiber heat-insulation cotton is heat-insulation, firm in shell, safe and reliable in use and capable of keeping high-temperature work for a long time; the air outlet is provided with a K-type thermocouple, direct detection and control are realized, and the air outlet temperature is constant; the device is provided with a multiple overheating overload protection device, so that the safety of the equipment is fully ensured, and the equipment can continuously operate all the year around 365 days; the design of the ingenious wind tunnel, the air passes through the inside/outside of the spiral electric heating wire evenly, the heat exchange is nearly 100%, the wind pressure loss is less, and the flow is less; the heating wire is hidden in the ceramic cavity in a suspension mode, hot air can uniformly pass through two sides of the heating wire, the air quantity is large, the wind resistance is low, and the temperature of the heating wire is low.

The mixing box 2 comprises a first motor 201, a feeding hole 202 and a first discharging hole 203, the mixing box 2 is of a cylindrical cavity structure, the first motor 201 is arranged at the rear end of the mixing box 2, the feeding hole 202 is arranged at the top end of the mixing box 2, the first discharging hole 203 is arranged at the bottom of the front end of the mixing box 2, and the first discharging hole 203 is positioned above the material receiving groove 3;

mixing box 2 is still including separating otter board 204, annular frame 205, connecting rod 206, mounting bracket 207 and stirring board 208, be equipped with in the 2 cavities of mixing box and separate otter board 204, and separate otter board 204 and be annular network structure, it is equipped with two annular frame 205 to separate otter board 204 inboard, and annular frame 205 is connected with the bull stick through connecting rod 206, and the bull stick is connected with the pivot of first motor 201, it installs mounting bracket 207 to rotate between the front and back both sides connecting rod 206, and be equipped with stirring board 208 in the mounting bracket 207, and stirring board 208 is annular array mode and distributes, this device provides power by first motor 201, it rotates to drive mounting bracket 207 through annular frame 205 and connecting rod 206, make stirring board 208 carry out the compounding to the inside of separation otter board 204, utilize stirring board 208 to rotate, mix plastics raw materials and auxiliary material.

The receiving trough 3 comprises a shaft lever 301 and a push rod 302, the receiving trough 3 is of a V-shaped section cavity structure, the minimum caliber position of the bottom end of the receiving trough 3 is connected with a connecting assembly 8, the shaft lever 301 is arranged on the left side and the right side of the receiving trough 3, the receiving trough 3 is rotatably connected with the workbench 1 through the shaft lever 301, the push rod 302 is arranged at the front end of the receiving trough 3, the push rod 302 is rotatably connected with the receiving trough 3 through a pin shaft, and the push rod 302 is connected with the support frame 4;

the support frame 4 comprises an air cylinder 401, a base plate 402, a sliding groove 403 and a sliding rod 404, the support frame 4 is of a rectangular frame structure, the air cylinder 401 is fixedly mounted on a top plate of the support frame 4, rectangular through grooves are formed in the middle positions of two vertical plates on the left and right of the support frame 4, the sliding grooves 403 are formed in the front side wall and the rear side wall of each rectangular through groove, the sliding rod 404 is vertically mounted in each rectangular through groove, the base plate 402 is fixedly mounted between the two vertical plates on the support frame 4 and close to the bottom of the support frame 4, and the base plate 402 is flush with the discharging surface of the guide frame 5;

the support frame 4 further comprises a sliding plate 405, a sliding block 406 and a pressing plate 407, the sliding plate 405 is arranged above the base plate 402, the sliding plate 405 and the base plate 402 are distributed in a parallel mode, the sliding plate 405 is rotatably connected with the push rod 302 through a pin shaft, the sliding plate 405 is provided with the sliding blocks 406 at the left end and the right end, the pressing plate 407 is arranged at the bottom end of the sliding plate 405, the sliding rod 404 penetrates through the left end and the right end of the sliding plate 405 in a sliding mode, the sliding plate 405 is slidably connected with the sliding groove 403 through the sliding blocks 406, the device is powered by the air cylinder 401, the sliding plate 405 slides up and down along the sliding groove 403 and the sliding rod 404, materials on the base plate 402 are extruded through the pressing plate 407, when the sliding plate 405 slides, the push rod 302 is used for pushing the material receiving groove 3 to perform arc motion by taking the shaft rod 301 as an axis, and the materials are prevented from being adhered to the inner wall of the material receiving groove 3.

The material guide frame 5 comprises a material guide roller 501, a transmission roller 502, a driving gear 503, a cutting pad roller 504 and a driven gear 505, the material guide frame 5 is provided with the material guide roller 501, the transmission roller 502 and the cutting pad roller 504 which are rotatably connected with the material guide frame 5 through bearings, the driving gear 503 and the driven gear 505 are respectively arranged at the left ends of the transmission roller 502 and the cutting pad roller 504, the driving gear 503 is meshed with the driven gear 505, and the cutting pad roller 504 and the hob cutter 6 are distributed in a parallel manner;

hobbing cutter 6 includes first band pulley 601, belt 602, second motor 603 and second band pulley 604, hobbing cutter 6 passes through the bearing and rotates with guide frame 5 to be connected, and hobbing cutter 6 right-hand member is equipped with first band pulley 601, second motor 603 fixed mounting is inside workstation 1, and be equipped with second band pulley 604 in the pivot of second motor 603, and second band pulley 604 is connected with first band pulley 601 transmission through belt 602, this device is provided power by second motor 603, make driving roller 502 and second band pulley 604 rotate, utilize driving gear 503 and driven gear 505 to drive cutting pad roller 504 to rotate, it is rotatory to utilize belt 602 and second band pulley 604 to drive hobbing cutter 6 simultaneously, thereby realize ejection of compact and blank process.

In another embodiment, a limiting round rod is disposed at the front end between the two connecting pipes 801, and the limiting round rod is disposed in the restoring spring 803, and the limiting round rod and the elastic hose 802 are distributed in parallel, so that the two connecting pipes 801 are more stable when swinging, the restoring spring 803 can be always at the front end between the two connecting pipes 801, and the operation reliability of the spring is improved.

The production method of the super-tough high-performance engineering plastic specifically comprises the following steps:

firstly, plastic raw materials and auxiliary materials enter a mixing box 2 through a feeding hole 202, two annular frames 205 are arranged on the inner side of a partition screen plate 204, the annular frames 205 are connected with rotating rods through connecting rods 206, the rotating rods are connected with rotating shafts of a first motor 201, a mounting frame 207 is rotatably mounted between the connecting rods 206 on the front side and the rear side, stirring plates 208 are arranged in the mounting frame 207, the stirring plates 208 are distributed in an annular array mode, power is provided by the first motor 201, the mounting frame 207 is driven to rotate through the annular frames 205 and the connecting rods 206, the stirring plates 208 are used for mixing materials in the partition screen plate 204, the stirring plates 208 are rotated, the occurrence of adhesion is reduced, and the mixing efficiency is ensured;

secondly, when the material enters the material receiving tank 3 from the first material outlet 203 and enters the heating box 701 through the connecting assembly 8, the heated material is discharged onto the backing plate 402 from the second material outlet 702, the air cylinder 401 is started to provide power, the sliding plate 405 slides up and down along the sliding groove 403 and the sliding rod 404, the material on the backing plate 402 is extruded through the pressing plate 407, and when the sliding plate 405 slides, the pushing rod 302 is used for pushing the material receiving tank 3 to perform arc motion by taking the shaft lever 301 as an axis, so that the material is prevented from being adhered to the inner wall of the material receiving tank 3;

in addition, second motor 603 fixed mounting is inside workstation 1, and is equipped with second band pulley 604 in the pivot of second motor 603, and second band pulley 604 passes through belt 602 and is connected with first band pulley 601 transmission, and this device is provided power by second motor 603, makes driving roller 502 and second band pulley 604 rotate, utilizes driving gear 503 and driven gear 505 to drive cutting pad roller 504 and rotates, utilizes belt 602 and second band pulley 604 to drive hobbing cutter 6 rotatory simultaneously, thereby realizes ejection of compact and blank process, simple structure, and flexible operation.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.