CN112007544A

CN112007544A - Negative ion inner wall coating process system and filling process method thereof

Info

Publication number: CN112007544A
Application number: CN202010835294.5A
Authority: CN
Inventors: 殷震花
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-08-19
Filing date: 2020-08-19
Publication date: 2020-12-01

Abstract

The invention discloses a negative ion inner wall coating process system, which comprises a stirring unit and a filling unit, wherein the stirring unit is used for stirring the negative ion inner wall coating; the stirring unit is correspondingly arranged above the filling unit; the stirring unit comprises a frame body and a cylinder body; the frame body comprises a guide rail and a traction device; the outer part of the cylinder body is rotatably provided with a switching assembly; the switching assembly is in sliding fit with the guide rail; the traction device is connected with the frame body; the installation height of the retractor is greater than that of the adapter assembly; a rope body is connected between the traction device and the bottom of the cylinder body; driving a traction device to tighten the rope body and pulling the barrel to overturn around the revolving joint assembly to dump materials; the stirring unit and the filling unit can be matched in a one-to-many or many-to-many mode, so that the fault tolerance between the stirring and filling processes can be further enhanced, and the higher overall efficiency is obtained.

Description

Negative ion inner wall coating process system and filling process method thereof

Technical Field

The invention relates to the technical field of paint production, in particular to a negative ion inner wall paint process system and a filling process method thereof.

Background

In the production of negative ion interior wall coating, stirring equipment and filling equipment are usually purchased separately, and the process connection between the stirring equipment and the filling equipment is not smooth enough, which seriously influences the overall production efficiency. Therefore, it is necessary to invent a negative ion inner wall coating process system with high operation efficiency and strong working condition adaptability.

Disclosure of Invention

The purpose of the invention is as follows: in order to overcome the defects in the prior art, the invention provides the negative ion interior wall coating process system which is high in operation efficiency and strong in working condition adaptability.

The technical scheme is as follows: in order to achieve the aim, the negative ion inner wall coating process system comprises a stirring unit and a filling unit; the stirring unit is correspondingly arranged above the filling unit; the stirring unit comprises a frame body and a cylinder body; the frame body comprises a guide rail and a traction device; the outer part of the cylinder body is rotatably provided with a switching assembly; the switching assembly is in sliding fit with the guide rail; the traction device is connected with the frame body; the installation height of the retractor is greater than that of the adapter assembly; a rope body is connected between the traction device and the bottom of the cylinder body; the rope body is tightened up by the driving traction device, and the barrel is pulled to overturn around the rotating connection assembly to dump materials.

Further, the switching components are respectively arranged on two sides of the cylinder body; the switching assembly comprises a connecting rod and a sliding block; the guide rail comprises a first slide rail and a second slide rail; one end of the connecting rod is rotatably matched with the cylinder body, and the other end of the connecting rod is fixedly connected with the sliding block; the sliding blocks on the two sides of the cylinder are respectively arranged in the first sliding rail and the second sliding rail in a sliding manner;

the rack body also comprises a power assembly; the power assembly further comprises a motor and a lead screw; the sliding block is provided with a threaded hole in a penetrating manner along the length direction of the guide rail; the lead screws are arranged in the first slide rail and the second slide rail in pairs; the lead screw is in nested fit with the slide block; the motor is matched with the lead screw to drive the sliding block to move in a reciprocating mode.

Further, a stirring cavity is arranged inside the cylinder body; an opening is formed in the top of the stirring cavity; a pouring opening is formed in the edge of the opening; a material equalizing plate is connected and arranged at the position, corresponding to the pouring opening, outside the cylinder;

a plurality of shunting grooves are formed in the surface of one side, facing the interior of the cylinder, of the homogenizing plate; the adjacent splitter boxes are mutually communicated and overlapped; the arrangement direction of the plurality of the shunting grooves is consistent with the width direction of the pouring opening.

Furthermore, a slot is arranged on the outer side of the cylinder body; the surface of the slot is provided with a positioning hole; the material equalizing plates are correspondingly embedded in the slots; the surface of the homogenizing plate is provided with a positioning groove; the positioning grooves are correspondingly matched with the positioning holes.

Further, the filling unit comprises a bucket; the top of the material containing barrel is provided with an opening, and the position of the opening corresponds to the moving track of the barrel; a screening component is embedded above the opening of the material containing barrel in a matching way; the screening assembly comprises a ring piece, a filter screen bag and a baffle plate; the ring piece bearing is arranged at the upper end of the containing barrel; the filter screen pocket is connected and arranged at the bottom of the ring piece; a space is reserved between the side surface of the filter net bag and the inner wall of the material containing barrel; the baffle is arranged inside the ring piece; a platform is arranged on the outer side of the material containing barrel; the top of the platform is rotatably provided with a wheel disc; the wheel disc is correspondingly matched with the outer side of the ring piece to drive the ring piece to rotate.

Furthermore, balls are arranged at the top of the charging bucket at intervals in the circumferential direction; the bottom of the ring piece is provided with an embedded groove; the upper ends of the balls are correspondingly embedded in the embedding grooves.

Further, a nozzle assembly is arranged at the bottom of the containing barrel; the nozzle assembly comprises a feeding barrel, a conical body and a temperature control body; one end of the feeding barrel is communicated and connected with the bottom of the material containing barrel, and the other end of the feeding barrel is connected with the conical body; the conical body is hollow and is correspondingly communicated with the feeding barrel; the section of the conical body gradually shrinks along the direction far away from the feeding barrel; the temperature control body is arranged on the periphery of the feeding barrel in a fitting and sleeving manner; a conveying pipe is embedded in the temperature control body; and a temperature conducting medium flows in the conveying pipe.

Further, the feeding barrel is connected with the conical body through threads; an expansion ring is embedded on the end surface of the feeding barrel, which is close to the conical body; an inflation nozzle is embedded in the side wall of the feeding barrel; the inflation nozzle is communicated and connected with the expansion ring; an annular groove is formed in the end face, close to the feeding barrel, of the conical body; the annular groove is correspondingly matched with the expansion ring.

Further, the filling process method of the negative ion inner wall coating process system comprises the following steps: comprises the following steps of (a) carrying out,

s1, adding the raw materials of the coating into a cylinder, and stirring to obtain a uniform mixture;

s2, driving the screw rod to rotate through the motor, and driving the barrel to move to an upper position corresponding to the opening of the material containing barrel along the guide rail;

s3, pulling the rope body through the traction device to drive the cylinder body to turn over; the mixture in the cylinder body is poured into the screening assembly;

s4, in the process of dumping the cylinder body of S3, the wheel disc is used for driving the screening assembly to rotate; the mixture in the screening assembly penetrates through the filter screen bags at the bottom and around under the stirring of the baffle plate, and the filtered mixture falls into the bottom of the material containing barrel;

s5, enabling the mixture in the material containing barrel to pass through the nozzle assembly and fall into each empty material barrel to finish filling; during filling, temperature conducting media flow in the conveying pipe, and the feeding barrel in the temperature control body can be heated or cooled according to the requirements of the filling process.

Has the advantages that: the invention relates to an anion inner wall coating process system, which comprises a stirring unit and a filling unit; the stirring unit is correspondingly arranged above the filling unit; the stirring unit comprises a frame body and a cylinder body; the frame body comprises a guide rail and a traction device; the outer part of the cylinder body is rotatably provided with a switching assembly; the switching assembly is in sliding fit with the guide rail; the traction device is connected with the frame body; the installation height of the retractor is greater than that of the adapter assembly; a rope body is connected between the traction device and the bottom of the cylinder body; driving a traction device to tighten the rope body and pulling the barrel to overturn around the revolving joint assembly to dump materials; the stirring unit and the filling unit can be matched in a one-to-many or many-to-many mode, so that the fault tolerance between the stirring and filling processes can be further enhanced, and the higher overall efficiency is obtained.

Drawings

FIG. 1 is a diagram of the overall architecture of a process system;

FIG. 2 is a schematic view of the overall structure of the stirring unit;

FIG. 3 is a detailed view of the socket structure;

FIG. 4 is a detail view of the structure of the equalizing plate;

FIG. 5 is a schematic view of the overall structure of the filling unit;

FIG. 6 is a detailed view of the screening assembly;

FIG. 7 is a schematic view of a nozzle assembly;

FIG. 8 is a schematic view showing the machining position of the ring groove.

Detailed Description

The present invention will be further described with reference to the accompanying drawings.

A negative ion inner wall coating process system is shown in figure 1 and comprises a stirring unit 1 and a filling unit 2; the stirring unit 1 is correspondingly arranged above the filling unit 2, so that the coating mixture can be transferred to the filling unit 2 by pouring after the stirring unit 1 finishes stirring; meanwhile, the stirring unit 1 and the filling unit 2 can be matched in a one-to-many or many-to-many manner, so that the fault tolerance between the stirring and filling processes can be further enhanced, and higher overall efficiency can be obtained; as shown in fig. 2, the stirring unit 1 includes a frame body 3 and a cylinder body 4, and a stirring head 49 is disposed in the cylinder body 4 in a matching manner; the frame body 3 comprises a guide rail 31 and a retractor 32; the outer part of the cylinder body 4 is rotatably provided with a switching component 5; the adapter assembly 5 is in sliding fit with the guide rail 31; the retractor 32 is connected with the frame body 3; the installation height of the tractor 32 is larger than that of the adapter assembly 5; a rope body 301 is connected between the traction device 32 and the bottom of the barrel 4; driving a traction device 32 to tighten the rope body 301, and pulling the barrel 4 to turn around the rotating assembly 5 to dump materials; the traction device 32 is internally provided with a rotary drum, and the rope body 301 is wound on the surface of the rotary drum, so that the rope body 301 can be controlled to be wound and unwound through the bidirectional rotation of the rotary drum.

As shown in fig. 2, the adapter assemblies 5 are respectively arranged on two sides of the cylinder 4; the adapter assembly 5 comprises a connecting rod 51 and a sliding block 52; the guide rail 31 comprises a first slide rail 311 and a second slide rail 312; one end of the connecting rod 51 is in rotating fit with the cylinder 4, and the other end of the connecting rod is fixedly connected with the sliding block 52; the sliding blocks 52 on the two sides of the cylinder 4 are respectively arranged in the first sliding rail 311 and the second sliding rail 312 in a sliding manner; when the rope body 301 is pulled, the barrel 4 and the adapter component 5 rotate relatively;

the frame body 3 further comprises a power assembly 33; the power assembly 33 further comprises a motor 331 and a lead screw 332; the slide block 52 is provided with a threaded hole 521 along the length direction of the guide rail 31; the lead screws 332 are arranged in the first slide rail 311 and the second slide rail 312 in pairs; the lead screw 332 is in nested fit with the slide block 52; the motor 331 is matched with the lead screw 332 to drive the slide block 52 to reciprocate; by means of the cooperation between the sliding block 52 and the lead screw 332, stable reciprocating movement is achieved, and therefore the situation that splashing is caused by shaking is reduced.

As shown in fig. 2-4, a stirring chamber 41 is arranged inside the cylinder 4; the top of the stirring cavity 41 is provided with an opening 42; a pouring opening 43 is formed in the edge of the opening 42 and used for restricting the flowing position of the coating and ensuring pouring accuracy; a material homogenizing plate 45 is connected and arranged at the position, corresponding to the pouring opening 43, outside the cylinder 4;

the surface of one side of the material homogenizing plate 45 facing the inside of the cylinder 4 is provided with a plurality of shunting grooves 451; the adjacent shunting grooves 451 are mutually communicated and overlapped; the arrangement direction of the plurality of shunting grooves 451 is consistent with the width direction of the pouring opening 43; the shunting grooves 451 can ensure the uniform distribution of the coating in the width direction when the coating flows, and avoid the phenomenon that the coating is concentrated on one side of the material homogenizing plate 45 when the two sides of the material homogenizing plate 45 are not consistent in the horizontal direction, thereby remarkably reducing the condition of concentrated overflow of the flow and improving the process stability.

As shown in fig. 3, the outer side of the cylinder 4 is provided with a slot 44; the surface of the slot 44 is provided with a positioning hole 441; the material equalizing plate 45 is correspondingly embedded in the slot 44, so that the material equalizing plate is convenient and quick to disassemble and assemble, and the operation cost during cleaning and maintenance is simplified; as shown in fig. 4, the material homogenizing plate 45 is provided with positioning grooves 452 on the surface; the positioning groove 452 is correspondingly matched with the positioning hole 441, and the inserting pin structure is sequentially embedded into the positioning hole 441 and the positioning groove 452, so that the slot 44 and the material homogenizing plate 45 are fixed.

As shown in fig. 5 and 6, the filling unit 2 comprises a bucket 21; the top of the material containing barrel 21 is provided with an opening corresponding to the moving track position of the barrel 4; a screening component 6 is embedded above the opening of the material containing barrel 21 in a matching way; the screening assembly 6 comprises a ring piece 61, a filter screen pocket 62 and a baffle 63; the ring 61 is arranged at the upper end of the charging bucket 21; the filter screen bag 62 is connected and arranged at the bottom of the ring piece 61; a space is reserved between the side surface of the filter net bag 62 and the inner wall of the material containing barrel 21; the baffle 63 is arranged inside the ring 61; a platform 22 is arranged on the outer side of the charging bucket 21; a wheel disc 23 is rotatably arranged at the top of the platform 22; the wheel disc 23 is correspondingly matched with the outer side of the ring piece 61 to drive the ring piece 61 to rotate; the mixture after stirring can be subjected to primary screening by using the screening component 6, so that the uniformity of a final product is improved; the baffle 63 is used for pushing the mixture in the screening assembly 6 to rotate, and the screening process can be accelerated by means of gravity and centrifugal force, so that the filling supply is ensured.

The top of the charging bucket 21 is provided with balls 201 at intervals in the circumferential direction; the bottom of the ring piece 61 is provided with a caulking groove; the upper end of the ball 201 is correspondingly embedded in the embedding groove, and the friction force borne by the ring piece 61 during rotation can be greatly reduced by means of the ball 201, so that the noise is reduced, and the service life is prolonged.

As shown in fig. 7 and 8, the bottom of the charging bucket 21 is provided with a nozzle assembly 7; the nozzle assembly 7 comprises a feeding barrel 71, a conical body 72 and a temperature control body 73; one end of the feeding barrel 71 is communicated and connected with the bottom of the material containing barrel 21, and the other end of the feeding barrel is connected with the conical body 72; the conical body 72 is hollow and is correspondingly communicated with the feeding barrel 71; the section of the conical body 72 gradually shrinks along the direction away from the feeding barrel 71; the temperature control body 73 is sleeved on the periphery of the feeding barrel 71 in a fitting manner; a delivery pipe 731 is embedded in the temperature control body 73; the conveying pipe 731 is internally provided with a temperature conducting medium in a flowing manner, and the temperature of the flowing coating mixture can be controlled by means of heat conduction between the temperature control body 73 and the outer wall of the feeding barrel 71, so that the special working conditions of low temperature and the like in northern autumn and winter can be adapted, and the regional adaptability of the equipment is improved.

The feeding barrel 71 is connected with the conical body 72 through threads; an expansion ring 711 made of rubber is embedded on the end face, close to the conical body 72, of the feeding barrel 71; an air charging nozzle 712 is embedded in the side wall of the feeding barrel 71; the inflation nozzle 712 is communicated with the expansion ring 711; an annular groove 721 is arranged on the end surface of the conical body 72 close to the feeding barrel 71; the annular groove 721 is correspondingly matched with the expansion ring 711; after the conical body 72 is screwed with the feeding barrel 71, air is conveyed to the expansion ring 711 through the air charging nozzle 712, the annular groove 721 is clamped by utilizing the expansion effect of the air charging nozzle, the peripheral sealing effect is formed, and the stability of the filling process is enhanced.

The filling process method of the negative ion inner wall coating process system comprises the following steps: comprises the following steps of (a) carrying out,

s1, adding the raw materials of the coating into the cylinder 4, and stirring to obtain a uniform mixture;

s2, the motor 331 drives the screw 332 to rotate, and the barrel 4 is driven to move to the upper position corresponding to the opening of the material containing barrel 21 along the guide rail 31;

s3, pulling the rope body 301 through the puller 32 to drive the barrel 4 to turn over; the mixture inside the cylinder 4 is poured inside the screening assembly 6;

s4, in the process of dumping the cylinder 4 in the S3, the wheel disc 23 is used for driving the screening assembly 6 to rotate; the mixture in the screening component 6 passes through the filter screen pockets 62 at the bottom and around under the stirring of the baffle 63, and the filtered mixture falls into the bottom of the material containing barrel 21;

s5, enabling the mixture in the material containing barrel 21 to pass through the nozzle assembly 7 and fall into each empty material barrel to finish filling; during filling, a temperature conducting medium flows in the conveying pipe 731, and the feeding barrel 71 in the temperature control body 73 can be heated or cooled according to the requirements of the filling process.

The above description is only of the preferred embodiments of the present invention, and it should be noted that: it will be apparent to those skilled in the art that various modifications and adaptations can be made without departing from the principles of the invention and these are intended to be within the scope of the invention.

Claims

1. A negative ion inner wall coating process system is characterized in that: comprises a stirring unit (1) and a filling unit (2); the stirring unit (1) is correspondingly arranged above the filling unit (2); the stirring unit (1) comprises a frame body (3) and a cylinder body (4); the frame body (3) comprises a guide rail (31) and a traction device (32); the outer part of the cylinder body (4) is rotatably provided with a switching component (5); the adapter component (5) is in sliding fit with the guide rail (31); the traction device (32) is connected with the frame body (3); the installation height of the tractor (32) is greater than the height of the adapter component (5); a rope body (301) is connected between the traction device (32) and the bottom of the barrel body (4); the rope body (301) is tightened by driving the traction device (32), and the barrel body (4) is pulled to overturn around the rotating connection assembly (5) to dump materials.

2. The negative ion interior wall coating process system of claim 1, wherein: the switching components (5) are respectively arranged on two sides of the cylinder body (4); the switching assembly (5) comprises a connecting rod (51) and a sliding block (52); the guide rail (31) comprises a first slide rail (311) and a second slide rail (312); one end of the connecting rod (51) is in rotary fit with the cylinder body (4), and the other end of the connecting rod is fixedly connected with the sliding block (52); the sliding blocks (52) on the two sides of the cylinder (4) are respectively arranged in the first sliding rail (311) and the second sliding rail (312) in a sliding manner;

the frame body (3) also comprises a power assembly (33); the power assembly (33) further comprises a motor (331) and a lead screw (332); the sliding block (52) is provided with a threaded hole (521) in a penetrating manner along the length direction of the guide rail (31); the lead screws (332) are arranged in the first sliding rail (311) and the second sliding rail (312) in pairs; the lead screw (332) is in nested fit with the sliding block (52); the motor (331) is matched with the lead screw (332) and drives the sliding block (52) to reciprocate.

3. The negative ion interior wall coating process system of claim 2, wherein: a stirring cavity (41) is arranged in the barrel body (4); an opening (42) is formed in the top of the stirring cavity (41); a pouring opening (43) is arranged at the edge of the opening (42); a material homogenizing plate (45) is connected and arranged at the position, corresponding to the pouring opening (43), outside the barrel body (4);

a plurality of shunting grooves (451) are formed in the surface of one side, facing the interior of the barrel (4), of the material equalizing plate (45); the adjacent shunting grooves (451) are mutually communicated and overlapped; the arrangement direction of the plurality of diversion grooves (451) is consistent with the width direction of the pouring opening (43).

4. The negative ion interior wall coating process system of claim 2, wherein: a slot (44) is formed in the outer side of the cylinder body (4); positioning holes (441) are formed in the surfaces of the slots (44); the material equalizing plates (45) are correspondingly embedded in the slots (44); the surface of the material homogenizing plate (45) is provided with a positioning groove (452); the positioning groove (452) is correspondingly matched with the positioning hole (441).

5. The negative ion interior wall coating process system of claim 1, wherein: the filling unit (2) comprises a material containing barrel (21); the top of the material containing barrel (21) is provided with an opening, and the position of the movement track of the material containing barrel corresponds to that of the barrel (4); a screening component (6) is embedded above the opening of the material containing barrel (21) in a matching way; the screening assembly (6) comprises a ring piece (61), a filter screen pocket (62) and a baffle (63); the ring piece (61) is arranged at the upper end of the material containing barrel (21) in a bearing way; the filter screen bag (62) is connected and arranged at the bottom of the ring piece (61); a space is reserved between the side surface of the filter net bag (62) and the inner wall of the material containing barrel (21); the baffle (63) is arranged inside the ring (61); a platform (22) is arranged on the outer side of the material containing barrel (21); a wheel disc (23) is rotatably arranged at the top of the platform (22); the wheel disc (23) is correspondingly matched with the outer side of the ring piece (61) to drive the ring piece (61) to rotate.

6. The negative ion interior wall coating process system of claim 5, wherein: the top of the charging bucket (21) is provided with balls (201) at intervals in the circumferential direction; the bottom of the ring piece (61) is provided with a caulking groove; the upper ends of the balls (201) are correspondingly embedded in the embedding grooves.

7. The negative ion interior wall coating process system of claim 5, wherein: the bottom of the material containing barrel (21) is provided with a nozzle assembly (7); the nozzle assembly (7) comprises a feeding barrel (71), a conical body (72) and a temperature control body (73); one end of the feeding barrel (71) is communicated and connected with the bottom of the material containing barrel (21), and the other end of the feeding barrel is connected with the conical body (72); the conical body (72) is hollow and is correspondingly communicated with the feeding barrel (71); the section of the conical body (72) is gradually contracted along the direction away from the feeding barrel (71); the temperature control body (73) is sleeved on the periphery of the feeding barrel (71) in a fitting manner; a delivery pipe (731) is embedded in the temperature control body (73); a temperature conducting medium flows in the conveying pipe (731).

8. The negative ion interior wall coating process system of claim 7, wherein: the feeding barrel (71) is connected with the conical body (72) through threads; an expansion ring (711) is embedded on the end surface of the feeding barrel (71) close to the conical body (72); an inflation nozzle (712) is embedded in the side wall of the feeding barrel (71); the inflation nozzle (712) is communicated and connected with the expansion ring (711); an annular groove (721) is arranged on the end surface of the conical body (72) close to the feeding barrel (71); the annular groove (721) is correspondingly matched with the expansion ring (711).

9. The filling process method of the anion inner wall paint process system according to any one of claims 1 to 8, characterized in that: comprises the following steps of (a) carrying out,

s1, adding the raw materials of the coating into the cylinder (4) and stirring to obtain a uniform mixture;

s2, the motor (331) drives the screw rod (332) to rotate, and the barrel (4) is driven to move to the upper position corresponding to the opening of the material containing barrel (21) along the guide rail (31);

s3, pulling the rope body (301) through the puller (32) to drive the cylinder body (4) to turn over; the mixture in the cylinder (4) is poured into the screening component (6);

s4, in the process that the barrel (4) of S3 is toppled, the wheel disc (23) is used for driving the screening assembly (6) to rotate; the mixture in the screening component (6) passes through the filter screen pockets (62) at the bottom and around under the stirring of the baffle (63), and the filtered mixture falls into the bottom of the material containing barrel (21);

s5, enabling the mixture in the material containing barrel (21) to pass through the nozzle assembly (7) and fall into each empty material barrel to finish filling; during filling, temperature conducting media flow in the conveying pipe (731), and the feeding barrel (71) in the temperature control body (73) can be heated or cooled according to the requirements of the filling process.