CN116753694A - Modified particle processing drying device - Google Patents

Abstract

The invention provides a modified particle processing and drying device, which is characterized in that a blower is arranged on one side of the drying box, a connecting pipe is arranged at the output end of the blower, a secondary pipe is arranged on the outer side surface of the connecting pipe, a heat exchange air duct is arranged at one end of the secondary pipe, which is far away from the connecting pipe, a baffle plate is arranged at one end of the heat exchange air duct, a collecting box is arranged on one side of the bottom of the drying box, a rotating assembly for drying is arranged on one side of the collecting box, a servo motor drives a connecting shaft to enable a spiral blade to rotate, centrifugal force is generated in the rotating process of the spiral blade, the centrifugal force instantaneously acts on a limiting block and modified particles, and after the modified particles under the action of the centrifugal force push the limiting block to move to one side, the limiting block continuously rotates and moves downwards along with the spiral shape of the spiral blade, and the modified particles collide and turn over when contacting with an electric heating plate in the rotating process, so that the modified particles achieve the effect of uniformly heating and drying.

Description

Modified particle processing drying device

Technical Field

The invention relates to the technical field of drying energy-saving equipment, in particular to a modified particle processing and drying device.

Background

The modified particles are PVC (polyvinyl chloride) which is a high polymer material and cannot be used independently, the properties of the modified particles are required to be improved, the modified particles are required to be cleaned and dried in the processing process of the modified particles, and the dried modified particles mainly show the moisture in the uniformly dried modified particles, so that the drying effect is achieved, the use of subsequent manufacturing procedures is facilitated, and the technical teaching of the dried modified particles is aimed at;

the following problems were found in the study of oven-dried modified particles:

when the modified particle drying device is used for drying the modified particles, the modified particles are dried through hot air flow, the hot air flow is sprayed out through the air jet head to enable the carrier plate to vibrate, the carrier plate simultaneously rotates along with the driving piece, the volume of the modified particles is smaller, the modified particles cannot be kept on the surface of the carrier plate while the modified particles rotate along with the carrier plate and vibrate, and the modified particles are directly discharged after not being dried, so that the purpose of drying effect cannot be achieved;

at present, CN112033117a in the prior art discloses a modified particle drying device, the invention drives a rotating upright shaft to rotate by a driving piece, an air blower disperses air flow blown into a drying cavity from a plurality of places, so that the contact and the circulation of particles in the drying cavity can be increased, the drying effect is improved, an electric heating plate is electrified to generate heat and rotate the rotation of the upright shaft to rotate, the electric heating plate can comprehensively heat and dry the particles, when the hollow poking plate rotates, the air flow sprayed by a jet head through the jet head can cause the hollow poking plate to vibrate up and down, the air flow blows to the hollow poking plate to vibrate and rotate together with the hollow poking plate, so that the particles turn over, and the electric heating plate is used for heating;

the invention mainly solves the problem that the modified particles cannot reach the drying effect because the modified particles cannot be kept on the surface of the carrier plate in the rotation and vibration processes of the carrier plate.

Disclosure of Invention

In order to solve the technical problems, the invention provides a modified particle processing and drying device, which aims to solve the problems described in the background art.

The invention discloses a modified particle processing and drying device, which is characterized by comprising the following specific technical means: the utility model provides a modified granule processing drying device, includes the drying cabinet body, the air-blower is installed to one side of drying cabinet body, the connecting pipe is installed to the output of air-blower, the auxiliary pipe is installed to the lateral surface of connecting pipe, the auxiliary pipe is kept away from the one end of connecting pipe and is installed the heat transfer air duct, the one end of heat transfer air duct is provided with the baffle, the collecting box is installed to bottom one side of drying cabinet body, the rotating assembly who carries out drying is installed to one side of collecting box, rotating assembly includes motor bin, servo motor, the connecting axle, helical blade, the electric plate, the stopper, pivot and return spring, the inside in motor bin is provided with servo motor, the connecting axle is installed to servo motor's output, helical blade is installed to the lateral surface of connecting axle, helical blade's surface is provided with the electric plate, helical blade's inside is provided with the stopper, the inside of stopper sets up the spring that returns, the lateral surface of spring is provided with the pivot.

Further, the inside of helical blade is the cavity setting, and the through-hole has been seted up to one side at helical blade top, and this through-hole one side laminating is provided with carries out spacing auxiliary assembly to modified granule, and the one end of helical blade bottom is the opening setting, and helical blade's inside is seted up flutedly.

Further, the electric heating plates are respectively embedded and arranged on the surface and the side face of the spiral blade, and are arranged in a net shape, and the size of the net-shaped internal grid is smaller than that of the modified particles.

Further, the limiting block is arranged at the groove position inside the spiral blade through the rotating shaft, the size of the limiting block is matched with the size of the hollow position inside the spiral blade, and one end, far away from the limiting block, of the return spring is embedded into the rotating shaft.

Further, auxiliary assembly includes feeding storehouse, water conservancy diversion mainboard, slider, slide rail, auxiliary block, water conservancy diversion subplate, reset spring and fixture block, and the bottom in feeding storehouse is provided with the water conservancy diversion mainboard, and the slider is installed to one side of water conservancy diversion mainboard, and the lateral surface of slider is provided with the slide rail, and the water conservancy diversion subplate is installed to the inner wall of water conservancy diversion mainboard, and the inside of water conservancy diversion mainboard is provided with reset spring, and the fixture block is installed to reset spring's one end, and the inside in feeding storehouse is provided with the slide rail, and auxiliary block is installed to the inside center department in feeding storehouse.

Further, the bottom of feeding storehouse is comma shape setting, and its bottom is the opening form setting, and the slide rail is all installed to the front and back both sides of this opening inner wall, and the slide rail is supporting setting with the slider, and the draw-in groove has been seted up to the lateral surface of slide rail, and one side of this draw-in groove is the arc setting.

Further, the opening of water conservancy diversion mainboard and helical blade top one side is the laminating setting, and the water conservancy diversion mainboard is the opening setting with one side of helical blade laminating, and this opening is the arc setting and with the radian phase-match of helical blade top one side, and the interior angle department of water conservancy diversion mainboard all is barb form setting, and the spout has all been seted up to the upper surface and the lower surface of water conservancy diversion mainboard, and the water conservancy diversion mainboard embedding is the opening setting in one side of feeding storehouse.

Further, the auxiliary block is arranged on the left side and the right side of the inner wall of the bottom end opening of the feeding bin, and the auxiliary block is arranged in a triangle with the width widened from bottom to top in sequence, and the size of the auxiliary block is matched with the size of the grooves on the upper surface and the lower surface of the flow guide main board.

Furthermore, the flow guide auxiliary plate is embedded in the inner angle barb of the flow guide main plate and is in sliding connection with the inner angle barb of the flow guide main plate, the thickness of the flow guide auxiliary plate is consistent with the height of the inner angle barb of the flow guide main plate, and rubber materials are used on one side of the flow guide auxiliary plate adjacent to the auxiliary block.

Further, the fixture block is embedded in the opening at one side of the flow guiding main board through the reset spring, one side of the fixture block is in an arc shape, and the fixture block is matched with the clamping groove at the outer side face of the sliding rail.

The beneficial effects are that:

1. the modified particles enter the guide main board through comma one end at the bottom of the feeding bin and then flow into the opening at the top of the spiral blade, the modified particles enter the inside of the guide main board through a through hole at one side of the top of the spiral blade, and the modified particles are limited along with the elasticity of the limiting block in the spiral blade through the elasticity of the return spring in the spiral blade, so that the modified particles are prevented from directly flowing out when preparing work is performed;

2. the heat exchange air pipe heats the external air flow and then discharges the air flow into the drying chamber of the drying box body through the baffle plate, the energy of the air flow is high, the distance between air molecules is large, the air with small density is light, so that the air flow enters the drying chamber of the drying box body and then moves upwards, meanwhile, the electric heating plate starts to heat modified particles entering the spiral blade, the air flow is arranged in a net shape through the electric heating plate, and then the air flow continuously heats and dries the modified particles inside the spiral blade after moving upwards until the air flow moves to the top of the drying box body and enters the air guide chamber again through the interval between the baffle plate and the drying box body;

3. the servo motor drives the connecting shaft to enable the spiral blade to rotate, centrifugal force is generated in the rotation process of the spiral blade, the centrifugal force instantaneously acts on the limiting block and the modified particles, and the modified particles under the action of the centrifugal force push the limiting block to move to one side and then continuously rotate along with the spiral shape of the spiral blade and move downwards, so that the modified particles collide and turn when power is generated in the rotation process and the centrifugal force acts on the electric heating plate, and further the modified particles achieve the effect of uniformly heating and drying;

4. the spiral blade impacts the guide main board for many times in the rotating process, the guide main board is increased by the thrust of the spiral blade through the arc-shaped side, the guide main board further moves into the bottom of the feeding bin through the sliding block in the sliding rail, the reset spring is continuously extruded by the clamping block pushed by the feeding bin, the extrusion of the reset spring is canceled after the guide main board enters the bottom of the feeding bin, the reset spring elastically pushes the clamping block into the clamping groove on the outer side face of the sliding rail, and the guide main board is prevented from affecting the rotation of the spiral blade;

drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic cross-sectional view of the present invention;

FIG. 3 is a schematic view of the structure of the feeding bin of the invention;

FIG. 4 is a schematic diagram of the splitting structure of the feeding bin of the invention;

FIG. 5 is a schematic diagram of a split structure of a flow guiding motherboard according to the present invention;

FIG. 6 is an enlarged schematic view of the structure of FIG. 5A according to the present invention;

FIG. 7 is an enlarged schematic view of the structure of FIG. 5B according to the present invention;

FIG. 8 is a schematic view of a helical blade structure according to the present invention;

FIG. 9 is a schematic view of the helical blade of the present invention in a disassembled configuration.

In fig. 1 to 9, the correspondence between the component names and the reference numerals is:

1. a drying box body; 101. a baffle plate; 2. a feeding bin; 201. a diversion main board; 202. a slide block; 203. a slide rail; 204. an auxiliary block; 205. a flow guiding auxiliary plate; 206. a return spring; 207. a clamping block; 3. a blower; 301. a connecting pipe; 302. a secondary pipe; 303. a heat exchange air duct; 4. a collection box; 5. a motor bin; 501. a servo motor; 502. a connecting shaft; 503. a helical blade; 504. an electric heating plate; 505. a limiting block; 506. a rotating shaft; 507. and a return spring.

Detailed Description

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 only some embodiments of the present invention, but not all embodiments, and all other embodiments obtained by those skilled in the art without making any inventive effort based on the embodiments of the present invention are within the scope of protection of the present invention.

As shown in fig. 1 to 9:

example 1

The utility model provides a modified granule processing drying device, including drying cabinet 1, air-blower 3 is installed to one side of drying cabinet 1, connecting pipe 301 is installed to the output of air-blower 3, auxiliary pipe 302 is installed to the lateral surface of connecting pipe 301, auxiliary pipe 302 is kept away from the one end of connecting pipe 301 and is installed heat exchange air duct 303, one end of heat exchange air duct 303 is provided with baffle 101, collecting box 4 is installed to one side of the bottom of drying cabinet 1, the rotating component who carries out the drying is installed to one side of collecting box 4, rotating component includes motor storehouse 5, servo motor 501, connecting axle 502, helical blade 503, electric plate 504, stopper 505, pivot 506 and return spring 507;

a servo motor 501 is arranged in the motor bin 5, a connecting shaft 502 is arranged at the output end of the servo motor 501, a spiral blade 503 is arranged on the outer side surface of the connecting shaft 502, an electric heating plate 504 is arranged on the surface of the spiral blade 503, a limiting block 505 is arranged in the spiral blade 503, a return spring 507 is arranged in the limiting block 505, and a rotating shaft 506 is arranged on the outer side surface of the return spring 507;

wherein, the bottom of the drying box body 1 is provided with a disc type through hole, and the baffle plate 101 is positioned in the drying box body 1 and is not connected with the top of the drying box body 1;

the spiral blade 503, the inside of the spiral blade 503 is hollow, a through hole is formed in one side of the top of the spiral blade 503, an auxiliary component for limiting modified particles is attached to one side of the through hole, one end of the bottom of the spiral blade 503 is provided with an opening, and a groove is formed in the inside of the spiral blade 503;

the electric heating plates 504, the electric heating plates 504 are respectively embedded and arranged on the surface and the side surface of the spiral blade 503, and the electric heating plates 504 are arranged in a net shape, and the size of the net-shaped internal grid is smaller than that of the modified particles;

the limiting block 505 is arranged at a groove in the spiral blade 503 through the rotating shaft 506, the size of the limiting block 505 is matched with the size of the hollow in the spiral blade 503, and one end of the return spring 507, which is far away from the limiting block 505, is embedded in the rotating shaft 506;

the modified particles enter the inside of the drying box body through the through hole at one side of the top of the spiral blade 503, the modified particles are limited by the elasticity of the internal return spring 507 along with the limit block 505 in the spiral blade 503, so that the modified particles are prevented from directly flowing out when the modified particles are prepared, the electric heating plate 504 and the blower 3 are started, the blower 3 guides external air flow into the auxiliary pipe 302 through the connecting pipe 301, the air flow is guided into the heat exchange air duct 303 through the auxiliary pipe 302, the heat exchange air duct 303 heats the external air flow and then is discharged into the drying chamber of the drying box body 1 through the baffle plate 101, the energy of the hot air flow is high, the distance between gas molecules is large, the gas with small density is light, the hot air flow enters the drying chamber of the drying box body 1 and then moves upwards, meanwhile, the electric heating plate 504 starts to heat the modified particles entering the spiral blade 503, the hot air flow is arranged in a net shape through the electric heating plate 504, and then continuously heats and dries the modified particles inside the spiral blade 503 after the hot air flow moves upwards until the hot air flow moves to the top of the drying box body 1 and enters the air duct 303 again through the interval between the baffle plate 101 and the drying box body 1, in the process, the servo motor drives the connecting shaft to rotate after the external air flow through the baffle plate 303, the centrifugal force rotates the spiral blade to enable the spiral blade to rotate, the spiral blade 505 is enabled to rotate, the spiral particles are enabled to rotate, and the modified particles are enabled to collide with the modified particles in a uniform motion effect, and the rotating effect is generated when the spiral particles are in a rotating motion, and the drying plate 505 is enabled to rotate, and the modified particles are in a rotating process, and the condition is in a rotating condition is in a moment, and the condition is in a condition that the condition is in contact with the drying process;

example 2

The present embodiment differs from embodiment 1 in that: the auxiliary assembly comprises a feeding bin 2, a guide main board 201, a sliding block 202, a sliding rail 203, an auxiliary block 204, a guide auxiliary board 205, a reset spring 206 and a clamping block 207, wherein the guide main board 201 is arranged at the bottom of the feeding bin 2, the sliding block 202 is arranged on one side of the guide main board 201, the sliding rail 203 is arranged on the outer side surface of the sliding block 202, the guide auxiliary board 205 is arranged on the inner wall of the guide main board 201, the reset spring 206 is arranged in the guide main board 201, the clamping block 207 is arranged at one end of the reset spring 206, the sliding rail 203 is arranged in the feeding bin 2, and the auxiliary block 204 is arranged at the center of the inside of the feeding bin 2;

wherein, the bottom of the feeding bin 2 is comma-shaped, the bottom end of the feeding bin 2 is provided with an opening, the front side and the rear side of the inner wall of the opening are provided with sliding rails 203, the sliding rails 203 and the sliding blocks 202 are arranged in a matched way, the outer side surface of the sliding rail 203 is provided with clamping grooves, and one side of each clamping groove is arc-shaped;

the flow guiding main board 201, the flow guiding main board 201 is attached to the opening on one side of the top of the spiral blade 503, the side of the flow guiding main board 201 attached to the spiral blade 503 is provided with an opening, and the opening is arc-shaped and is matched with the radian on one side of the top of the spiral blade 503;

the inner corners of the guide main board 201 are arranged in a barb shape, the upper surface and the lower surface of the guide main board 201 are provided with sliding grooves, and the guide main board 201 is embedded into one side of the feeding bin 2 and is arranged in an opening;

the auxiliary blocks 204 are arranged on the left side and the right side of the inner wall of the bottom end opening of the feeding bin 2, the auxiliary blocks 204 are arranged in a triangle with the width widened from bottom to top in sequence, and the size of each auxiliary block 204 is matched with the size of the grooves on the upper surface and the lower surface of the flow guiding main board 201;

the auxiliary flow guide plate 205 is embedded in the inner angle barb of the main flow guide plate 201, the auxiliary flow guide plate 205 and the main flow guide plate 201 are connected in a sliding manner, the thickness of the auxiliary flow guide plate 205 is consistent with the height of the inner angle barb of the main flow guide plate 201, and the side, adjacent to the auxiliary block 204, of the auxiliary flow guide plate 205 is made of rubber;

the clamping block 207 is embedded into an opening at one side of the flow guiding main board 201 through the reset spring 206, and one side of the clamping block 207 is arranged in an arc shape and is matched with a clamping groove at the outer side face of the sliding rail 202;

modified particles enter a guide main board 201 through a comma at the bottom of a feeding bin 2 and then flow into an opening at the top of a spiral blade 503, the spiral blade 503 rotates along with a connecting shaft 502 after stopping blanking, one side of the guide main board 201 is arc-shaped, the spiral blade 503 impacts the guide main board 201 for a plurality of times in the rotating process, the guide main board 501 increases the thrust of the spiral blade 503 through the arc-shaped side, the guide main board 201 further moves into the bottom of the feeding bin 2 through a sliding block 202 in a sliding rail 203, a reset spring 206 is continuously extruded by a clamping block 207 pushed by the feeding bin 2, the guide main board 201 is enabled to cancel extrusion of the reset spring 206 after entering the bottom of the feeding bin 2, the reset spring 206 elastically pushes the clamping block 207 into a clamping groove at the outer side of a sliding rail 202, the guide main board 201 is further prevented from influencing the rotation of the spiral blade 503, the guide main board 201 is bonded with an auxiliary block 204 through a groove at the upper surface and the lower surface in the process of the guide main board 201 entering the bin 2, and gradually widens from bottom to top along with the width of the auxiliary block 204, the auxiliary block 204 is enabled to gradually widen along with the width of the auxiliary block 204, the auxiliary block 204 in the process of entering the bin 2 is enabled to be a rubber block 205 adjacent to the auxiliary block 205 in the side of the auxiliary block 205 in the process of the guide main board 2, and the auxiliary block 205 is gradually moves along with the auxiliary block 205, and the auxiliary block 205 is further inclined to move along with the auxiliary block 204, and the auxiliary block 204 is gradually and the auxiliary block 204 is prevented from gradually falling down along with the auxiliary block 204;

the embodiments of the 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 embodiments were 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.

Claims (10)

1. The modified particle processing and drying device comprises a drying box body and is characterized in that a blower is installed on one side of the drying box body, a connecting pipe is installed at the output end of the blower, an auxiliary pipe is installed on the outer side surface of the connecting pipe, a heat exchange air duct is installed at one end of the auxiliary pipe far away from the connecting pipe, a baffle plate is arranged at one end of the heat exchange air duct, a collecting box is installed on one side of the bottom of the drying box body, a rotating assembly for drying is installed on one side of the collecting box, and the rotating assembly comprises a motor bin, a servo motor, a connecting shaft, a spiral blade, an electric heating plate, a limiting block, a rotating shaft and a return spring;

the inside in motor storehouse is provided with servo motor, and servo motor's output installs the connecting axle, and helical blade is installed to the lateral surface of connecting axle, and helical blade's surface is provided with the electric plate, and helical blade's inside is provided with the stopper, and the inside of stopper sets up the spring that returns, and the lateral surface of returning the spring is provided with the pivot.

2. The modified particle processing and drying device according to claim 1, wherein the inside of the spiral blade is hollow, a through hole is formed in one side of the top of the spiral blade, an auxiliary component for limiting the modified particles is attached to one side of the through hole, one end of the bottom of the spiral blade is provided with an opening, and the inside of the spiral blade is provided with a groove.

3. The modified particle processing and drying device according to claim 2, wherein the electric heating plates are respectively embedded in the surface and the side surface of the spiral blade, and the electric heating plates are arranged in a net shape, and the size of the net-shaped internal grid is smaller than that of the modified particles.

4. The modified particle processing and drying device according to claim 2, wherein the limiting block is arranged at a groove in the spiral blade through the rotating shaft, the size of the limiting block is matched with the size of a hollow in the spiral blade, and one end, far away from the limiting block, of the return spring is embedded into the rotating shaft.

5. The modified particle processing and drying device according to claim 2, wherein the auxiliary assembly comprises a feeding bin, a guide main board, a sliding block, a sliding rail, an auxiliary block, a guide auxiliary board, a reset spring and a clamping block, the guide main board is arranged at the bottom of the feeding bin, the sliding block is arranged on one side of the guide main board, the sliding rail is arranged on the outer side surface of the sliding block, the guide auxiliary board is arranged on the inner wall of the guide main board, the reset spring is arranged in the guide main board, the clamping block is arranged at one end of the reset spring, the sliding rail is arranged in the feeding bin, and the auxiliary block is arranged at the center of the feeding bin.

6. The modified particle processing and drying device according to claim 5, wherein the bottom of the feeding bin is comma-shaped, the bottom end of the feeding bin is provided with an opening, sliding rails are arranged on the front side and the rear side of the inner wall of the opening, the sliding rails are arranged in a matched mode with the sliding blocks, clamping grooves are formed in the outer side faces of the sliding rails, and one side of each clamping groove is arc-shaped.

7. The modified particle processing and drying device according to claim 5, wherein the opening on one side of the top of the spiral blade is formed by attaching the guide main board, the opening is arc-shaped and is matched with the radian on one side of the top of the spiral blade, the inner corners of the guide main board are all barb-shaped, the upper surface and the lower surface of the guide main board are both provided with sliding grooves, and the guide main board is embedded in one side of the feeding bin and is arranged in the opening.

8. The modified particle processing and drying device according to claim 6, wherein the auxiliary blocks are arranged on the left and right sides of the inner wall of the bottom end opening of the feeding bin, the auxiliary blocks are arranged in a triangle shape with the widths widened from bottom to top, and the sizes of the auxiliary blocks are matched with the sizes of the grooves on the upper surface and the lower surface of the flow guiding main board.

9. The modified particle processing and drying device according to claim 7, wherein the flow guide auxiliary plate is embedded in the inner angle barb of the flow guide main plate and is in sliding connection with the inner angle barb of the flow guide main plate, the thickness of the flow guide auxiliary plate is consistent with the height of the inner angle barb of the flow guide main plate, and rubber materials are used on the adjacent sides of the flow guide auxiliary plate and the auxiliary block.

10. The modified particle processing and drying device according to claim 6, wherein the clamping block is embedded into the opening at one side of the guide main board through the return spring, and one side of the clamping block is arc-shaped and is matched with the clamping groove at the outer side face of the sliding rail.