CN213971967U - Improved mixing device for forming of nano montmorillonite and PET - Google Patents

Abstract

The utility model discloses an improved mixing device for forming nanometer montmorillonite and PET, which comprises a mixing box, a support column, a base, a discharge head, a discharge valve, a stirring screw, a gear box, a driving motor, a PLC, a driving switch, a switch gate, a screening box, a foreign matter collecting and processing box structure, a rotatable screening frame structure, a connectable rotary cylinder structure, a power line, a communicating pipe, a meter and a montmorillonite hopper, wherein the periphery of the lower end of the mixing box is respectively welded with the support column; support columns are welded on the periphery of the upper end of the base respectively; the discharging head is welded in the middle of the lower end of the mixing box, and the lower end of the discharging head is connected with a discharging valve through a flange. The utility model has the advantages that: through the arrangement of the foreign matter collecting and processing box structure, when materials are conveyed through the conveying plate, the foreign matters are conveniently collected through the collecting box, so that the foreign matter collecting and processing box is convenient to use.

Description

Improved mixing device for forming of nano montmorillonite and PET

Technical Field

The utility model belongs to the technical field of the compounding device, especially, relate to a compounding device is used in shaping of follow-on nanometer montmorillonite and PET.

Background

PET is mainly used for fibers, bottle materials and films, the performance of PET resin is attractive, but the melting point strength is poor, the crystallization speed is low, the stability is poor, the large-scale use of PET plastics is restricted, particularly, the narrowing of the use surface of PET in the aspect of bottle materials is prominent, the PET resin is mainly used for water bottle materials, carbonic acid, tea, fruit juice drinks and the like, but the storage period of carbonic acid, tea drinks and milk products is obviously shortened due to the poor positive permeability and heat resistance of the PET resin, in order to improve the performance of PET, organic nano montmorillonite and PET resin particles are required to be accurately matched, and at present, the nano montmorillonite and PET resin particles are mixed through a mixing device, so that the PET resin can work better and is matched with materials to process and mix.

The existing mixing device for forming the nano montmorillonite and the PET also has the problems that the mode for cleaning the adsorbed foreign matters is complex and the use is easily influenced in the process of cleaning the foreign matters.

Therefore, the invention is very necessary to invent an improved mixing device for forming the nano montmorillonite and the PET.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve is: the utility model provides a follow-on nanometer montmorillonite and PET shaping are with compounding device to solve the problem that the adsorbed foreign matter mode of present nanometer montmorillonite and PET shaping is comparatively complicated and clearance foreign matter in-process influences the use easily with compounding device clearance.

In order to solve the technical problem, the utility model discloses a technical scheme be: an improved mixing device for forming nano montmorillonite and PET comprises a mixing box, support columns, a base, a discharge head, a discharge valve, a stirring screw rod, a gear box, a driving motor, a PLC (programmable logic controller), a driving switch, a switch gate, a screening box, a foreign matter collecting and processing box structure, a rotatable screening frame structure, a rotatable connecting rotary cylinder structure, a power line, a communicating pipe, a meter and a montmorillonite hopper, wherein the support columns are welded around the lower end of the mixing box respectively; support columns are welded on the periphery of the upper end of the base respectively; the discharging head is welded in the middle of the lower end of the mixing box, and the lower end of the discharging head is connected with a discharging valve through a flange; the left end of the stirring screw is respectively arranged at the front part and the rear part on the left side of the inner wall of the mixing box through a bearing, and the right end of the stirring screw is respectively in key connection with the front part and the rear part at the left end of the gear box; the gearbox is arranged at the right end of the mixing box through a bolt, and the right end of the gearbox is in key connection with an output shaft of the driving motor; the driving motor is mounted at the right end of the gear box through a bolt; the PLC bolt is arranged at the lower part of the left end of the mixing box, and the left surface of the PLC is electrically connected with a driving switch; the switch gate bolt is arranged between the mixing box and the screening box; the screening box is arranged at the upper end of the mixing box through bolts; the foreign matter collecting and processing box structure is arranged on the left side of the screening box; the rotatable screening frame structure is arranged in the screening box; the connectable rotary cylinder structure is arranged at the front end of the rotatable screening frame structure; the power line is arranged in the rotatable screening frame structure; the communicating pipe bolt is arranged at the left end of the gauge; the gauge bolt is arranged at the right end of the screening box; the montmorillonite hopper is mounted on the right side of the upper end of the meter through a bolt; the foreign matter collecting and processing box structure comprises a first connecting plate, a through-inserting hole, a conveying plate, a protection plate, a through hole, a cleaning plate, a second connecting plate, a sleeving seat and a collecting box, wherein the first connecting plate is installed on the left side inside the screening box through bolts, and the through-inserting hole is formed in the first connecting plate; the conveying plate is welded at the lower part of the inner wall of the inserting hole; the protection plates are respectively welded at the front part and the rear part on the right side of the upper end of the conveying plate; the through hole is formed in the middle of the right side in the conveying plate; the cleaning plate is welded in the middle of the right side of the upper surface of the conveying plate; the second connecting plate is welded at the lower part of the left end of the first connecting plate; the right end of the collecting box is welded with a sleeve joint seat, and the sleeve joint seat is sleeved on the second connecting plate.

Preferably, the rotatable screening frame structure comprises a mounting seat, a rotating motor, a rotating pipe, a pipe cavity, a sleeve pipe and an electromagnet, wherein the mounting seat is mounted at the rear end of the screening box through bolts, and the rotating motor is mounted at the rear end of the mounting seat through bolts; the rear end of the rotating pipe is in key connection with an output shaft of the rotating motor, and a pipe cavity is formed in the rotating pipe; the sleeve pipes are respectively welded around the outer wall of the rotating pipe; the electromagnet is embedded in the rotating pipe.

Preferably, the structure of the connectable rotary cylinder comprises a connecting block, a rotary bearing, a connector, a fixed seat, a protective cover and a through hole, wherein the connecting block is welded at the front end of the screening box, and the rotary bearing is embedded in the connecting block; the fixed seats are respectively welded on the left side and the right side of the front end of the connector and are electrically connected with the power line; the protective cover is installed at the front end of the connecting block through bolts, and the front side inside the protective cover is provided with a through hole.

Preferably, the conveying plate is arranged in an inclined shape, and the left end of the conveying plate corresponds to the upper end of the collecting box.

Preferably, the second connecting plate is T-shaped and is respectively matched with the socket, and the socket is L-shaped.

Preferably, the sleeving pipes are provided with a plurality of sleeving pipes and are arranged around the outer wall of the rotating pipe, and electromagnets are arranged in the sleeving pipes.

Preferably, the connector is embedded in the rotary bearing, and the rear end of the connector is embedded in the front part of the inner wall of the pipe cavity.

Preferably, the protection cover adopts a PVC plastic cover, and the protection cover is arranged at the front end of the connecting block.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses in, the delivery board set up to the slope form, delivery board left end correspond with the upper end of collecting the box, when carrying the material through the delivery board, be convenient for collect the foreign matter through collecting the box to convenient to use.

The utility model discloses in, the second connecting plate set up to the T type, and respectively with cup joint a looks adaptation, cup joint the seat and set up to the L type, be convenient for cooperate this collection box to install and use or dismantle and arrange the material.

The utility model discloses in, the outside of through-hole upper end be provided with the cleaning board, the cleaning board set up to the U type, when the inboard of cup joint process cleaning board, can make the cleaning board scrape and get the foreign matter that cup joints on the surface to avoided needing to stop the work that could clear up the foreign matter, and then be convenient for clear up the foreign matter.

The utility model discloses in, the bell and spigot joint pipe be provided with a plurality ofly, and install around rotating the outer wall of pipe, be provided with the electro-magnet in the bell and spigot joint pipe simultaneously, when the bell and spigot joint pipe is at screening incasement internal rotation, can absorb the foreign matter in the screening incasement material and discharge, and then be convenient for absorb the work of foreign matter.

The utility model discloses in, the rotating tube rear end be connected with the rotating electrical machines, the rotating tube is connected with the socket joint pipe simultaneously, be convenient for cooperate the rotating tube and the socket joint pipe is rotatory and use.

The utility model discloses in, the connector embedding in swivel bearing's inside, the embedding of connector rear end is in the front portion of lumen inner wall simultaneously, the cooperation transmitting tube of being convenient for supports and rotatory use, also is convenient for make connector and electro-magnet line connection and use simultaneously.

The utility model discloses in, the connector pass through the fixing base and be connected with the power cord, be convenient for cooperate the electro-magnet to connect and use thereupon.

The utility model discloses in, the safety cover adopt PVC plastics cover, the safety cover setting at the front end of connecting block, be convenient for protect and use the junction of fixing base and power cord.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of the foreign matter collecting and treating box structure of the present invention.

Fig. 3 is a schematic structural view of the rotatable screening frame structure of the present invention.

Fig. 4 is a schematic structural diagram of the connectable rotary drum structure of the present invention.

Fig. 5 is a schematic diagram of the electrical connection of the present invention.

In fig. 1 to 5:

1. a mixing box; 2. a support pillar; 3. a base; 4. discharging a stub bar; 5. a discharge valve; 6. a stirring screw; 7. a gear case; 8. a drive motor; 9. a PLC; 10. a drive switch; 11. opening and closing the gate; 12. a screening box; 13. a foreign matter collecting and processing box structure; 131. a first connecting plate; 132. inserting the socket; 133. a conveying plate; 134. a protection plate; 135. a through hole; 136. cleaning the plate; 137. a second connecting plate; 138. a socket joint seat; 139. a collection box; 14. a rotatable screening frame structure; 141. a mounting seat; 142. a rotating electric machine; 143. rotating the tube; 144. a lumen; 145. sleeving a pipe; 146. an electromagnet; 15. a rotatable drum structure can be connected; 151. connecting blocks; 152. a rotating bearing; 153. a connector; 154. a fixed seat; 155. a protective cover; 156. Inserting holes; 16. a power line; 17. a communicating pipe; 18. a meter; 19. montmorillonite hopper.

Detailed Description

The invention is further described below with reference to the accompanying drawings:

as shown in fig. 1 and fig. 2, the utility model discloses an improved mixing device for forming nano montmorillonite and PET, which comprises a mixing box 1, a support column 2, a base 3, a discharge head 4, a discharge valve 5, a stirring screw 6, a gear box 7, a driving motor 8, a PLC9, a driving switch 10, a switch gate 11, a screening box 12, a foreign matter collecting and processing box structure 13, a rotatable screening frame structure 14, a connectable rotary cylinder structure 15, a power line 16, a communicating pipe 17, a meter 18 and a montmorillonite hopper 19, wherein the support column 2 is welded around the lower end of the mixing box 1; support columns 2 are welded on the periphery of the upper end of the base 3 respectively; the discharging head 4 is welded in the middle of the lower end of the mixing box 1, and the lower end of the discharging head 4 is connected with a discharging valve 5 in a flange mode; the left end of the stirring screw rod 6 is respectively arranged at the front part and the rear part on the left side of the inner wall of the mixing box 1 through a bearing, and the right end of the stirring screw rod 6 is respectively in key connection with the front part and the rear part at the left end of the gear box 7; the gear box 7 is mounted at the right end of the mixing box 1 through bolts, and the right end of the gear box 7 is in key connection with an output shaft of the driving motor 8; the driving motor 8 is mounted at the right end of the gear box 7 through bolts; the PLC9 is installed at the lower part of the left end of the mixing box 1 through a bolt, and the left surface of the PLC9 is electrically connected with a driving switch 10; the switch gate 11 is installed between the mixing box 1 and the screening box 12 through bolts; the screening box 12 is mounted at the upper end of the mixing box 1 through bolts; the foreign matter collecting and processing box structure 13 is arranged on the left side of the screening box 12; the rotatable screen frame structure 14 is mounted inside the screen box 12; the connectable rotary drum structure 15 is arranged at the front end of the rotatable screening frame structure 14; the power cord 16 is mounted in the rotatable screen frame structure 14; the communicating pipe 17 is mounted at the left end of the gauge 18 through a bolt; the gauge 18 is mounted at the right end of the screening box 12 through bolts; the montmorillonite hopper 19 is mounted on the right side of the upper end of the gauge 18 through a bolt; the foreign matter collecting and treating box structure 13 comprises a first connecting plate 131, inserting openings 132, a conveying plate 133, a protective plate 134, through holes 135, a cleaning plate 136, a second connecting plate 137, a socket 138 and a collecting box 139, wherein the first connecting plate 131 is mounted on the left side inside the screening box 12 through bolts, and the inserting openings 132 are formed in the first connecting plate 131; the conveying plate 133 is welded at the lower part of the inner wall of the inserting hole 132; the protection plates 134 are respectively welded at the front part and the rear part of the right side of the upper end of the conveying plate 133; the through hole 135 is arranged at the right middle part inside the conveying plate 133; the cleaning plate 136 is welded at the middle part of the right side of the upper surface of the conveying plate 133; the second connecting plate 137 is welded at the lower part of the left end of the first connecting plate 131; the right end of the collecting box 139 is welded with a socket 138, and the socket 138 is sleeved on the second connecting plate 137.

As shown in fig. 3, in the above embodiment, specifically, the rotatable screening frame structure 14 includes a mounting seat 141, a rotating motor 142, a rotating pipe 143, a pipe cavity 144, a sleeve pipe 145 and an electromagnet 146, the mounting seat 141 is bolted at the rear end of the screening box 12, and the rotating motor 142 is bolted at the rear end of the mounting seat 141; the rear end of the rotating tube 143 is in key connection with an output shaft of the rotating motor 142, and a tube cavity 144 is formed in the rotating tube 143; the sleeve pipes 145 are respectively welded around the outer wall of the rotating pipe 143; the electromagnet 146 is embedded in the rotating tube 143.

As shown in fig. 4, in the above embodiment, specifically, the connectable rotary drum structure 15 includes a connecting block 151, a rotary bearing 152, a connecting head 153, a fixing seat 154, a protecting cover 155 and a through hole 156, the connecting block 151 is welded at the front end of the screening box 12, and the rotary bearing 152 is embedded in the connecting block 151; the fixing seat 154 is respectively welded on the left side and the right side of the front end of the connecting head 153, and the fixing seat 154 is electrically connected with the power line 16; the protective cover 155 is bolted to the front end of the connecting block 151, and a through hole 156 is opened on the front side inside the protective cover 155.

In the above embodiment, specifically, the conveying plate 133 is disposed in an inclined shape, and the left end of the conveying plate 133 corresponds to the upper end of the collecting box 139, so that when the material is conveyed by the conveying plate 133, the collecting box 139 can collect the foreign materials, thereby facilitating the use.

In the above embodiment, specifically, the second connecting plate 137 is T-shaped and is respectively matched with the sleeving seat 138, and the sleeving seat 138 is L-shaped, so as to be conveniently matched with the collecting box 139 for installation and use or disassembly and discharge.

In the above embodiment, specifically, the cleaning plate 136 is arranged on the outer side of the upper end of the through hole 135, the cleaning plate 136 is set to be U-shaped, and when the socket pipe 145 passes through the inner side of the cleaning plate 136, the cleaning plate 136 can scrape foreign matters on the surface of the socket pipe 145, so that the problem that the foreign matters can be cleaned only by stopping the cleaning plate is avoided, and the foreign matters can be cleaned conveniently.

In the above embodiment, specifically, the plurality of the sleeving pipes 145 are arranged around the outer wall of the rotating pipe 143, and the electromagnets 146 are arranged in the sleeving pipes 145, so that when the sleeving pipes 145 rotate in the screening box 12, the foreign matters in the material in the screening box 12 can be sucked and discharged, and the foreign matters can be sucked and discharged conveniently.

In the above embodiment, specifically, the rear end of the rotating pipe 143 is connected to the rotating motor 142, and the rotating pipe 143 is connected to the sleeve 145, so that the rotating pipe 143 and the sleeve 145 can be conveniently rotated and used.

In the above embodiment, specifically, the connector 153 is embedded in the rotary bearing 152, and the rear end of the connector 153 is embedded in the front portion of the inner wall of the cavity 144, so as to be conveniently supported and rotated by matching with the rotating tube 143, and to be conveniently connected with the line of the electromagnet 146 for use.

In the above embodiment, specifically, the connector 153 is connected to the power line 16 through the fixing seat 154, so as to be conveniently connected to the electromagnet 146 for use therewith.

In the above embodiment, specifically, the protection cover 155 is a PVC plastic cover, and the protection cover 155 is disposed at the front end of the connection block 151, so as to protect and use the connection between the fixing base 154 and the power line 16.

In the above embodiment, specifically, the driving motor 8 is a 5IK90A-CF motor.

In the above embodiment, specifically, the PLC9 is a PLC of model FX 2N-48.

In the above embodiment, specifically, the switch gate 11 is a CBF gate.

In the above embodiment, specifically, the rotating electrical machine 142 is a model HJX57RO motor.

In the above embodiment, specifically, the electromagnet 146 is an electromagnet with model No. JF-0520B.

In the above embodiment, specifically, the driving switch 10 is electrically connected to an input terminal of the PLC9, the driving motor 8 is electrically connected to an output terminal of the PLC9, the switch gate 11 is electrically connected to an output terminal of the PLC9, the rotating motor 142 is electrically connected to an output terminal of the PLC9, and the electromagnet 146 is electrically connected to an output terminal of the PLC 9.

Principle of operation

The utility model discloses a theory of operation: when in use, materials are conveyed into the screening box 12 through the matching of the montmorillonite hopper 19, the meter 18 and the communicating pipe 17, the rotating motor 142 drives the rotating pipe 143, the sleeve pipe 145 and the electromagnet 146 to rotate while conveying, so that the electromagnet 146 can be matched with foreign matters in the adsorbing material of the sleeve pipe 145 to rotate after adsorbing, then the rotating sleeve pipe 145 penetrates through the through hole 135 and the cleaning plate 136, so that the adsorbed foreign matters can be scraped, the foreign matters reach the conveying plate 133, finally the foreign matters enter the collecting box 139 to be stored according to the inclined angle, the switch gate 11 is opened after the foreign matters are adsorbed to enable the materials to enter the mixing box 1, finally the driving motor 8 is matched with the gear box 7 to drive the stirring screw 6 to rotate to carry out the mixing work, after the mixing is finished, the discharge valve 5 is opened to match with the discharge head 4 to discharge the materials in the mixing box 1, and completes the work.

Utilize technical scheme, or technical personnel in the field are in the utility model discloses under technical scheme's the inspiration, design similar technical scheme, and reach above-mentioned technological effect, all fall into the utility model discloses a protection scope.

Claims (10)

1. The improved mixing device for forming the nano montmorillonite and the PET is characterized by comprising a mixing box (1), supporting columns (2), a base (3), a discharging head (4), a discharging valve (5), a stirring screw (6), a gear box (7), a driving motor (8), a PLC (9), a driving switch (10), a switch gate (11), a screening box (12), a foreign matter collecting and processing box structure (13), a rotatable screening frame structure (14), a connectable rotary barrel structure (15), a power line (16), a communicating pipe (17), a meter (18) and a montmorillonite hopper (19), wherein the supporting columns (2) are welded around the lower end of the mixing box (1) respectively; supporting columns (2) are welded around the upper end of the base (3) respectively; the discharge head (4) is welded in the middle of the lower end of the mixing box (1), and the lower end of the discharge head (4) is connected with a discharge valve (5) in a flange manner; the left end of the stirring screw rod (6) is respectively arranged at the front part and the rear part on the left side of the inner wall of the mixing box (1) through bearings, and the right end of the stirring screw rod (6) is respectively connected with the front part and the rear part at the left end of the gear box (7) in a key mode; the gear box (7) is mounted at the right end of the mixing box (1) through bolts, and the right end of the gear box (7) is in key connection with an output shaft of the driving motor (8); the driving motor (8) is mounted at the right end of the gear box (7) through a bolt; the PLC (9) is installed at the lower part of the left end of the mixing box (1) through a bolt, and the left surface of the PLC (9) is electrically connected with a driving switch (10); the switch gate (11) is arranged between the mixing box (1) and the screening box (12) through bolts; the screening box (12) is mounted at the upper end of the mixing box (1) through bolts; the foreign matter collecting and processing box structure (13) is arranged on the left side of the screening box (12); the rotatable screening frame structure (14) is arranged inside the screening box (12); the connectable rotary cylinder structure (15) is arranged at the front end of the rotatable screening frame structure (14); the power line (16) is arranged in the rotatable screening frame structure (14); the communicating pipe (17) is mounted at the left end of the gauge (18) through a bolt; the gauge (18) is mounted at the right end of the screening box (12) through bolts; the montmorillonite hopper (19) is mounted on the right side of the upper end of the gauge (18) through a bolt; the foreign matter collecting and treating box structure (13) comprises a first connecting plate (131), inserting openings (132), a conveying plate (133), a protective plate (134), through holes (135), a cleaning plate (136), a second connecting plate (137), a socket joint seat (138) and a collecting box (139), wherein the first connecting plate (131) is arranged on the left side inside the screening box (12) through bolts, and inserting openings (132) are formed in the first connecting plate (131); the conveying plate (133) is welded at the lower part of the inner wall of the through-inserting opening (132); the protection plates (134) are respectively welded at the front part and the rear part of the right side of the upper end of the conveying plate (133); the through hole (135) is arranged in the middle part of the right side in the conveying plate (133); the cleaning plate (136) is welded in the middle of the right side of the upper surface of the conveying plate (133); the second connecting plate (137) is welded at the lower part of the left end of the first connecting plate (131); the right end of the collecting box (139) is welded with a socket joint seat (138), and the socket joint seat (138) is sheathed on the second connecting plate (137).

2. The improved mixing device for forming the nano montmorillonite and the PET as claimed in claim 1, wherein the rotatable screening frame structure (14) comprises a mounting seat (141), a rotating motor (142), a rotating pipe (143), a pipe cavity (144), a sleeve pipe (145) and an electromagnet (146), the mounting seat (141) is mounted at the rear end of the screening box (12) through bolts, and the rotating motor (142) is mounted at the rear end of the mounting seat (141) through bolts; the rear end of the rotating pipe (143) is in key connection with an output shaft of the rotating motor (142), and a pipe cavity (144) is formed in the rotating pipe (143); the sleeve pipes (145) are respectively welded around the outer wall of the rotating pipe (143); the electromagnet (146) is embedded in the rotating pipe (143).

3. The improved mixing device for forming the nano montmorillonite and the PET as claimed in claim 1, wherein the connectable rotary cylinder structure (15) comprises a connecting block (151), a rotary bearing (152), a connecting head (153), a fixed seat (154), a protective cover (155) and a through hole (156), the connecting block (151) is welded at the front end of the screening box (12), and the rotary bearing (152) is embedded in the connecting block (151); the fixing seats (154) are respectively welded at the left side and the right side of the front end of the connecting head (153), and the fixing seats (154) are electrically connected with the power line (16); safety cover (155) bolted mounting at the front end of connecting block (151), and the inside front side of safety cover (155) opens and is equipped with through-hole (156).

4. The improved mixing device for forming nano montmorillonite and PET as claimed in claim 1, wherein the conveying plate (133) is arranged in an inclined shape, and the left end of the conveying plate (133) corresponds to the upper end of the collecting box (139).

5. The improved mixing device for forming nanometer montmorillonite and PET as claimed in claim 1, wherein the second connecting plate (137) is T-shaped and is respectively matched with the socket base (138), and the socket base (138) is L-shaped.

6. The improved mixing device for forming nano montmorillonite and PET as claimed in claim 1, wherein a cleaning plate (136) is arranged outside the upper end of the through hole (135), and the cleaning plate (136) is U-shaped.

7. The improved mixing device for forming the nano montmorillonite and the PET as claimed in claim 2, wherein a plurality of the sleeving pipes (145) are arranged and installed around the outer wall of the rotating pipe (143), and the sleeving pipes (145) are internally provided with electromagnets (146).

8. The improved mixing device for forming nano montmorillonite and PET as claimed in claim 2, wherein the rear end of the rotating pipe (143) is connected with a rotating motor (142), and the rotating pipe (143) is connected with a sleeve pipe (145).

9. The improved mixing device for forming nano montmorillonite and PET as claimed in claim 3, wherein the connector (153) is embedded in the rotary bearing (152), and the rear end of the connector (153) is embedded in the front part of the inner wall of the tube cavity (144).

10. The improved mixing device for forming nano montmorillonite and PET as claimed in claim 3, wherein the protective cover (155) is made of PVC plastic, and the protective cover (155) is arranged at the front end of the connecting block (151).

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