CN116160576B - An intelligent glass fiber reinforced pellet production mixing device - Google Patents

Abstract

The invention relates to the technical field of mixing equipment for glass fiber particle production, in particular to an intelligent glass fiber reinforced material particle production mixing device which comprises a stirring part, a conveying part, a screening part and a storage box, wherein the stirring part is connected to the upper side of one end of the conveying part, the screening part is connected to the other end of the conveying part, the storage box is connected to the bottom of the screening part, the conveying part comprises a conveying pipe, a conveying shaft and a first spiral conveying blade, the first spiral conveying blade is fixed on the conveying shaft, a cutting assembly is arranged in the middle of the conveying shaft, a cutting motor is arranged outside the conveying pipe, and an output shaft of the cutting motor is connected with the cutting assembly in a matched mode. The device carries out preliminary cutting through the inside cutting subassembly of conveying part to the material, carries out further cutting to the material through the inside second cutting knife of sieve material part, improves the qualification rate of material granularity, ensures the high-efficient production of material.

Description

Intelligent glass fiber reinforced material grain production mixing device

Technical Field

The invention relates to the technical field of mixing equipment for glass fiber particle production, in particular to an intelligent glass fiber reinforced material particle production mixing device.

Background

The glass fiber reinforced plastic is prepared by adding glass fiber and other additives based on the original pure plastic, thereby improving the application range of the material. The glass fiber plastic particles are frequently used raw materials in the chemical industry, and are mainly used for improving the heat-resistant temperature of the original plastic, and the optimal temperature of the glass fiber plastic particles when the glass fiber plastic particles are poured into a mold is 235 ℃. The glass fiber plastic particle heat-insulating feeder based on stirring heating is an inorganic nonmetallic material with excellent performance, and has the advantages of high insulativity, high heat resistance, high corrosion resistance and high mechanical strength.

In the prior art, when using feeding device to carry out reinforced operation to glass fine plastic particle, be with glass fine plastic particle direct input to extrusion die in, do not carry out preliminary treatment to glass fine plastic particle, lead to a large amount of particle's particle diameter great, surpass the user demand, cause certain influence to the mould, machining efficiency is not good, can not satisfy the user demand. Therefore, the intelligent glass fiber reinforced material particle production mixing device is designed to mix glass fibers and auxiliaries thereof, shear the glass fibers and auxiliaries, and prevent oversized material particles from affecting the processing efficiency.

The intelligent glass fiber reinforced material particle production and mixing device aims to solve the technical problems that an intelligent glass fiber reinforced material particle production and mixing device is designed to efficiently mix and shear materials, so that the glass fiber reinforced material particles are prevented from being large, and the processing efficiency of the glass fiber reinforced material particles is guaranteed.

Disclosure of Invention

In order to solve the problems, the invention provides an intelligent glass fiber reinforced material particle production mixing device.

The technical scheme includes that the intelligent glass fiber reinforced plastic particle production mixing device comprises a stirring part, a conveying part, a screening part and a storage box, wherein the stirring part is connected to the upper side of one end of the conveying part, the screening part is connected to the other end of the conveying part, the storage box is connected to the bottom of the screening part, the conveying part comprises a conveying pipe, a conveying shaft and a first spiral conveying blade, the first spiral conveying blade is fixed on the conveying shaft, a cutting assembly is arranged in the middle of the conveying shaft, a cutting motor is arranged outside the conveying pipe, and an output shaft of the cutting motor is connected with the cutting assembly in a matched mode.

As optimization, the stirring part comprises a stirring tank, a stirring shaft and a stirring paddle, wherein the stirring tank is vertically arranged, the stirring shaft is rotationally connected inside the stirring tank, the stirring paddle is connected to the middle lower part of the stirring shaft, the upper end of the stirring shaft penetrates through the top of the stirring tank to be connected with a stirring motor, the lower part of the stirring tank is provided with a horizontal supporting plate, and the supporting plate is closely provided with a discharging hole;

the top of agitator tank is equipped with the feeder hopper, the top of feeder hopper is involute, the bottom of agitator tank link up with the lower extreme upside of conveyer pipe.

As optimization, the conveying pipe is obliquely arranged, the conveying shaft and the conveying pipe are coaxially arranged, and the lower end of the conveying shaft is connected with a conveying motor;

The cutting assembly comprises a connecting sleeve, a connecting shaft sleeve and a first cutting knife, the connecting shaft sleeve is rotationally connected with a conveying shaft, an annular groove is formed in the middle of the conveying pipe, the connecting sleeve is rotationally connected in the annular groove, the first cutting knife is connected between the connecting sleeve and the connecting shaft sleeve, a first connecting gear is arranged on the outer side of the connecting sleeve, a first driving gear is arranged on an output shaft of the cutting motor, and the first driving gear is meshed with the first connecting gear.

As optimization, the upper part of the storage box is provided with a negative pressure cavity, the negative pressure cavity is connected with a negative pressure fan, an air outlet filter screen is connected between the negative pressure cavity and the storage box, a pressure sensor is arranged in the negative pressure cavity, and the bottom of the storage box is rotationally connected with a discharge plate;

The bottom of the discharging plate is connected with an electric telescopic rod which is horizontally arranged.

As the optimization, the sieve material part include sieve material shell, second screw conveyor blade, cutting part and filter sieve, the vertical upper portion that sets up in the storage box of sieve material shell, the conveyer pipe is connected in the lower part of sieve material shell, second screw conveyor blade is vertical to be set up inside the sieve material shell, the filter sieve is vertical to be set up in the inboard axle center department of sieve material shell, cutting part sets up between filter sieve and second screw conveyor blade, cutting part, second screw conveyor blade all rotate with sieve material shell and are connected.

As optimization, second screw conveyor paddle and filter screen coaxial setting, the top of second screw paddle is equipped with annular drive block, the outside of drive block is equipped with the second connecting gear, the top of sieve material shell is equipped with the material loading motor, be equipped with the second drive gear on the output shaft of material loading motor, the second drive gear with the second connecting gear meshing is connected.

As the optimization, the cutting part include the second cutting knife of a plurality of vertical setting, a plurality of second cutting knife is circumference array setting, the top of second cutting knife is equipped with the fixed plate, second cutting knife bottom is equipped with the go-between, the go-between with the bottom rotation of filter screen is connected, the fixed plate level sets up, the top of sieve material shell is equipped with driving motor, driving motor's output shaft with the coaxial heart fixed connection of fixed plate, the filter screen is cylindric, the top of filter screen is the seal, the top and the adjacent setting of fixed plate of filter screen, the bottom of filter screen downwards passes sieve material shell and the top through connection of storage box.

As an optimization, the device further comprises a controller, wherein the controller is used for executing commands of the stirring motor, the cutting motor, the conveying motor, the driving motor and the feeding motor.

The beneficial effect of this scheme is, an intelligent glass fiber reinforcement grain production compounding device has following beneficial part:

Stirring and mixing the materials through the stirring part, conveying the mixed materials to the inside of the material sieving part through the conveying part, lifting the mixed materials upwards through a second spiral conveying blade in the material sieving part, cutting the materials through a second cutting knife in the material sieving part, and filtering the materials with qualified size through a filter sieve and then entering a processing box;

the device carries out preliminary cutting on the materials through the cutting component in the conveying part, and further cuts the materials through the second cutting knife in the screening part, so that the qualification rate of the granularity of the materials is improved, and the efficient production of the materials is ensured;

the negative pressure fan is connected in the storage box, and the negative pressure fan is used for sucking the inside of the storage box and the inside of the screening part, so that the inside of the device is in a negative pressure state, the material is conveniently discharged, and the material in the screening part is prevented from being blocked;

The cutting assembly is arranged in the conveying part and is used for primarily cutting the materials, so that the size of the larger granular materials is reduced, and the overall material treatment effect of the device is improved;

Lifting the material through the second screw conveying blade, enabling the material to pass through the cutting part from top to bottom, efficiently cutting the material through the cutting part, discharging qualified particles after cutting through a filter screen, enabling unqualified materials to fall into the bottom of a screen shell, continuously lifting the unqualified materials to the bottom of the inner side of the screen shell through the second screw conveying blade, and facilitating further cutting of the material, wherein the material treatment efficiency is high;

the support plate is arranged at the lower part of the inner side of the stirring tank, so that the discharging speed of the materials is slowed down, the mixing effect of the materials is improved, and the mixed materials are discharged into the conveying part through the discharge hole in the support plate, so that the materials are convenient to convey.

Drawings

Fig. 1 is an isometric view of the present invention.

Fig. 2 is a left-hand schematic view of the present invention.

FIG. 3 is a schematic view of the structure of FIG. 2, taken along line A-A, according to the present invention.

Fig. 4 is an enlarged schematic view of the portion a of fig. 3 according to the present invention.

Fig. 5 is an enlarged schematic view of the portion B of fig. 3 according to the present invention.

Fig. 6 is a bottom isometric view of the invention.

Fig. 7 is a schematic diagram of a connection structure between a screen material part of a screen material housing and a material storage box, which is omitted.

Fig. 8 is a schematic view of the internal structure of the screening part of the present invention.

The stirring device comprises a stirring tank, 2, a stirring shaft, 3, stirring paddles, 4, a supporting plate, 5, a discharging hole, 6, a feeding hopper, 7, a conveying pipe, 8, a conveying shaft, 9, a first spiral conveying blade, 10, a cutting motor, 11, a connecting sleeve, 12, a connecting sleeve, 13, a first cutting knife, 14, a negative pressure cavity, 15, a negative pressure fan, 16, an air outlet filter screen, 17, a storage box, 18, a discharging plate, 19, an electric telescopic rod, 20, a screening shell, 21, a second spiral conveying blade, 22, a filter screen, 23, a driving block, 24, a feeding motor, 25, a second cutting knife, 26, a driving motor, 27, a stirring motor, 28 and a conveying motor.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. The components of the embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It should be noted that like reference numerals and letters refer to like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.

In the description of the present invention, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are directions or positional relationships based on those shown in the drawings, or are directions or positional relationships conventionally put in use of the inventive product, are merely for convenience of describing the present invention and simplifying the description, and are not indicative or implying that the apparatus or element to be referred to must have a specific direction, be constructed and operated in a specific direction, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

As shown in fig. 1 and 3, an intelligent glass fiber reinforced plastic granule production mixing device comprises a stirring part, a conveying part, a screening part and a storage box 17, wherein the stirring part is connected to the upper side of one end of the conveying part, the screening part is connected to the other end of the conveying part, the storage box 17 is connected to the bottom of the screening part, the conveying part comprises a conveying pipe 7, a conveying shaft 8 and a first spiral conveying blade 9, the first spiral conveying blade 9 is fixed on the conveying shaft 8, a cutting assembly is arranged in the middle of the conveying shaft 8, a cutting motor 10 is arranged outside the conveying pipe 7, and an output shaft of the cutting motor 10 is connected with the cutting assembly in a matched manner.

As shown in fig. 3, the stirring part comprises a stirring tank 1, a stirring shaft 2 and a stirring paddle 3, wherein the stirring tank 1 is vertically arranged, the stirring shaft 2 is rotatably connected inside the stirring tank 1, the stirring paddle 3 is connected to the middle lower part of the stirring shaft 2, the upper end of the stirring shaft 2 penetrates through the top of the stirring tank 1 and is connected with a stirring motor 27, the lower part of the stirring tank 1 is provided with a horizontal supporting plate 4, and the supporting plate 4 is closely provided with a discharging hole 5;

As shown in fig. 3, a feed hopper 6 is arranged at the top of the stirring tank 1, the top of the feed hopper 6 is involute, and the bottom of the stirring tank 1 is communicated with the upper side of the lower end of a conveying pipe 7.

As shown in fig. 3, the conveying pipe 7 is obliquely arranged, the conveying shaft 8 and the conveying pipe 7 are coaxially arranged, and the lower end of the conveying shaft 8 is connected with a conveying motor 28;

As shown in fig. 3 and 4, the cutting assembly comprises a connecting sleeve 11, a connecting shaft sleeve 12 and a first cutting knife 13, the connecting shaft sleeve 12 is rotationally connected with the conveying shaft 8, an annular groove is formed in the middle of the conveying pipe 7, the connecting sleeve 11 is rotationally connected in the annular groove, the first cutting knife 13 is connected between the connecting sleeve 11 and the connecting shaft sleeve 12, a first connecting gear is arranged on the outer side of the connecting sleeve 11, a first driving gear is arranged on an output shaft of the cutting motor 10, and the first driving gear is in meshed connection with the first connecting gear.

As shown in fig. 3, a negative pressure cavity 14 is arranged at the upper part of the storage box 17, a negative pressure fan 15 is connected to the negative pressure cavity 14, an air outlet filter screen 16 is connected between the negative pressure cavity 14 and the storage box 17, a pressure sensor is arranged in the negative pressure cavity 14, and a discharging plate 18 is rotatably connected to the bottom of the storage box 17;

as shown in fig. 3, a horizontally arranged electric telescopic rod 19 is connected to the bottom of the discharge plate 18.

As shown in fig. 1 and 3, the screening part comprises a screening shell 20, a second screw conveying blade 21, a cutting part and a filter screen 22, the screening shell 20 is vertically arranged on the upper portion of the storage box 17, the conveying pipe 7 is connected to the lower portion of the screening shell 20, the second screw conveying blade 21 is vertically arranged inside the screening shell 20, the filter screen 22 is vertically arranged at the axis of the inner side of the screening shell 20, the cutting part is arranged between the filter screen 22 and the second screw conveying blade 21, and the cutting part and the second screw conveying blade 21 are both rotationally connected with the screening shell 20.

As shown in fig. 3, the second screw conveying blade 21 and the filter screen 22 are coaxially arranged, an annular driving block 23 is arranged at the top of the second screw conveying blade, a second connecting gear is arranged at the outer side of the driving block 23, a feeding motor 24 is arranged at the top of the screen material shell 20, a second driving gear is arranged on an output shaft of the feeding motor 24, and the second driving gear is meshed with the second connecting gear.

As shown in fig. 3 and 5, the cutting part comprises a plurality of second cutting knives 25 which are vertically arranged, the plurality of second cutting knives 25 are arranged in a circumferential array, a fixed plate is arranged at the top of each second cutting knife 25, a connecting ring is arranged at the bottom of each second cutting knife 25, the connecting ring is rotatably connected with the bottom of each filter screen 22, the fixed plates are horizontally arranged, a driving motor 26 is arranged at the top of each screen material shell 20, an output shaft of the driving motor 26 is fixedly connected with the corresponding fixed plate in a coaxial manner, each filter screen 22 is cylindrical, the top of each filter screen 22 is sealed, the top of each filter screen 22 is adjacent to the corresponding fixed plate, and the bottom of each filter screen 22 downwards penetrates through the corresponding screen material shell 20 and the top of the corresponding storage box 17.

Also included are controllers for executing commands to the agitator motor 27, the cutter motor 10, the conveyor motor 28, the drive motor 26 and the loading motor 24.

The position of the controller in the scheme is set according to actual conditions when working by staff, the controller is used for controlling used electric devices in the scheme, including but not limited to sensors, motors, telescopic rods, water pumps, electromagnetic valves, heating wires, heat pumps, display screens, computer input devices, switch buttons, communication devices, lamps, horns and microphones, the controller is an Intel processor, an AMD processor, a PLC (programmable logic controller), an ARM processor or a singlechip, the controller is matched with the AMD processor, the PLC controller, the ARM processor or the singlechip, the controller also comprises a main board, a memory bank, a storage medium and a power supply, the power supply is commercial power or a lithium battery, the controller is also provided with a display card when provided with the display screens, the operation principle of the controller is referred to the automatic control principle published by Qinghua university publishing society, the microcontroller principle and application simulation case, and books can be referred to for reading, and other unrecited automatic control and power utilization devices belong to the knowledge known by the person in the art, and are not repeated.

The using method comprises the following steps:

When the device is specifically used, glass fibers and materials are added into the stirring tank 1 through the feed hopper 6;

The stirring motor 27 drives the stirring shaft 2 and the stirring shaft 3 to stir the materials, the supporting plate 4 supports the materials, the downward flow speed of the materials is slowed down, the contact time of the materials and the stirring paddles 3 is prolonged, and the stirring effect is improved;

the material flows into the conveying pipe 7 through the discharging hole 5, and the conveying motor 28 drives the first screw conveying blade 9 to convey the material;

In the material conveying process, the controller controls the cutting motor 10 to operate so as to drive the first cutting knife 13 to rotate and cut the material in the conveying pipe 7;

the material enters the inside of the screen material shell 20 through the conveying pipe 7, the second screw conveying blade 21 is driven by the feeding motor 24, the material is lifted upwards from the bottom of the screen material shell 20, and after the material reaches the top of the screen material shell 20, the material falls into the axis direction of the second screw conveying blade 21 from top to bottom, contacts with the second cutter 25, and is cut by the second cutter 25;

The cut materials enter the filter screen 22 when meeting the requirement of particles, and the materials enter the storage box 17 through the filter screen 22;

Under the action of the negative pressure fan 15, materials quickly flow into the storage box 17 through the inside of the filter screen 22, when the materials in the storage box 17 are fully stored, the pressure sensor detects that the pressure in the negative pressure cavity 14 is smaller, the controller controls the electric telescopic rod 19 to shorten, the discharging plate 18 is opened, and the materials are discharged;

After the discharging is completed, the electric telescopic rod 19 stretches, the discharging plate 18 is closed, and the negative pressure fan continues to operate.

The longitudinal interface of the second screw conveying blade 21 is an inclined plane, and one side of the second screw conveying blade 21 adjacent to the screen material shell 20 is lower than the inner side of the second screw conveying blade 21, so that the material is convenient to convey.

The above embodiments are merely specific examples of the present invention, and the scope of the present invention includes, but is not limited to, the product forms and styles of the above embodiments, any suitable changes or modifications made by one of ordinary skill in the art, which are consistent with the claims of the present invention, shall fall within the scope of the present invention.

Claims (7)

1. The intelligent glass fiber reinforced material particle production mixing device is characterized by comprising a stirring part, a conveying part, a screening part and a storage box, wherein the stirring part is connected to the upper side of one end of the conveying part, the screening part is connected to the other end of the conveying part, the storage box is connected to the bottom of the screening part, the conveying part comprises a conveying pipe, a conveying shaft and a first spiral conveying blade, the first spiral conveying blade is fixed on the conveying shaft, a cutting assembly is arranged in the middle of the conveying shaft, a cutting motor is arranged outside the conveying pipe, and an output shaft of the cutting motor is connected with the cutting assembly in a matched manner;

The sieve material part include sieve material shell, second screw conveyor blade, cutting part and filter sieve, the vertical upper portion that sets up in the storage box of sieve material shell, the conveyer pipe is connected in the lower part of sieve material shell, second screw conveyor blade is vertical to be set up inside the sieve material shell, the vertical axle center department that sets up in sieve material shell inboard of filter sieve, cutting part sets up between filter sieve and second screw conveyor blade, cutting part, second screw conveyor blade all rotate with sieve material shell and are connected.

2. The intelligent glass fiber reinforced plastic grain production mixing device of claim 1, wherein the stirring part comprises a stirring tank, a stirring shaft and a stirring paddle, the stirring tank is vertically arranged, the stirring shaft is rotationally connected inside the stirring tank, the stirring paddle is connected to the middle lower part of the stirring shaft, the upper end of the stirring shaft penetrates through the top of the stirring tank and is connected with a stirring motor, the lower part of the stirring tank is provided with a horizontal supporting plate, and the supporting plate is closely provided with a discharging hole;

the top of agitator tank is equipped with the feeder hopper, the top of feeder hopper is involute, the bottom of agitator tank link up with the lower extreme upside of conveyer pipe.

3. The intelligent glass fiber reinforced plastic grain production mixing device according to claim 1, wherein the conveying pipe is obliquely arranged, the conveying shaft and the conveying pipe are coaxially arranged, and the lower end of the conveying shaft is connected with a conveying motor;

The cutting assembly comprises a connecting sleeve, a connecting shaft sleeve and a first cutting knife, the connecting shaft sleeve is rotationally connected with a conveying shaft, an annular groove is formed in the middle of the conveying pipe, the connecting sleeve is rotationally connected in the annular groove, the first cutting knife is connected between the connecting sleeve and the connecting shaft sleeve, a first connecting gear is arranged on the outer side of the connecting sleeve, a first driving gear is arranged on an output shaft of the cutting motor, and the first driving gear is meshed with the first connecting gear.

4. The intelligent glass fiber reinforced plastic grain production mixing device according to claim 1, wherein a negative pressure cavity is arranged at the upper part of the storage box, a negative pressure fan is connected to the negative pressure cavity, an air outlet filter screen is connected between the negative pressure cavity and the storage box, a pressure sensor is arranged in the negative pressure cavity, and a discharge plate is rotatably connected to the bottom of the storage box;

The bottom of the discharging plate is connected with an electric telescopic rod which is horizontally arranged.

5. The intelligent glass fiber reinforced plastic grain production mixing device according to claim 1, wherein the second screw conveying blade and the filter screen are coaxially arranged, an annular driving block is arranged at the top of the second screw conveying blade, a second connecting gear is arranged on the outer side of the driving block, a feeding motor is arranged at the top of the screen shell, a second driving gear is arranged on an output shaft of the feeding motor, and the second driving gear is in meshed connection with the second connecting gear.

6. The intelligent glass fiber reinforced plastic grain production mixing device according to claim 5, wherein the cutting part comprises a plurality of second cutting knives which are vertically arranged, the plurality of second cutting knives are arranged in a circumferential array, a fixed plate is arranged at the top of each second cutting knife, a connecting ring is arranged at the bottom of each second cutting knife, the connecting ring is rotationally connected with the bottom of each filter screen, the fixed plate is horizontally arranged, a driving motor is arranged at the top of each screen material shell, an output shaft of the driving motor is fixedly connected with the corresponding fixed plate in a coaxial manner, each filter screen is cylindrical, the top of each filter screen is provided with a seal, the top of each filter screen is adjacent to the corresponding fixed plate, and the bottom of each filter screen downwards penetrates through the corresponding screen material shell and is in through connection with the top of each storage box.

7. The intelligent glass fiber reinforced plastic grain production mixing device according to any one of claims 1-6, further comprising a controller, wherein the controller is used for executing commands of a stirring motor, a cutting motor, a conveying motor, a driving motor and a feeding motor.