CN117342223B

CN117342223B - Quantitative feeding device for insulating powder coating processing

Info

Publication number: CN117342223B
Application number: CN202311639899.7A
Authority: CN
Inventors: 赵正科; 宋家栋
Original assignee: Taizhou Runchen New Materials Co ltd
Current assignee: Taizhou Runchen New Materials Co ltd
Priority date: 2023-12-04
Filing date: 2023-12-04
Publication date: 2024-02-20
Anticipated expiration: 2043-12-04
Also published as: CN117342223A

Abstract

The invention relates to the technical field of quantitative feeding equipment for insulating coating powder, and discloses a quantitative feeding device for processing insulating powder coating, which comprises a first conveying belt, a control center, a crushing device, a collecting bin and a crushing barrel, wherein four mutually symmetrical hydraulic cylinders are arranged on the first conveying belt, the top output end of each hydraulic cylinder is connected with a hydraulic rod in a differential mode, the hydraulic rods are fixedly connected with the bottom of the first conveying belt, the outer surfaces of the rightmost front end and the rear end of the first conveying belt are fixedly connected with a first sliding block, one end of the first conveying belt, which is close to the first sliding block, is provided with a second conveying belt, the front end and the rear end of one end of the second conveying belt, which is close to the first sliding block, are respectively provided with a first sliding groove matched with the first sliding block, the bottom of the second conveying belt is fixedly connected with a first quality sensor, and the front end of the second conveying belt is provided with the control center.

Description

Quantitative feeding device for insulating powder coating processing

Technical Field

The invention relates to the technical field of insulating powder coating quantitative feeding equipment, in particular to a quantitative feeding device for processing insulating powder coating.

Background

With the continuous development of society and the continuous improvement of living standard of people, the application scene of powder coating processing is more and more wide, and powder coating refers to a finishing process, which relates to the application of free-flowing, dry, thermosetting or thermoplastic powder materials to the surfaces of parts, and is one of the most durable finishing processes aiming at different materials, and the powder coating is perfectly suitable for metal, plastic and other materials for custom manufacturing, and is usually processed with the aid of quantitative feeding equipment when insulating powder coating processing is carried out.

Publication No.: CN218690582U discloses a ration feed arrangement for environmental protection insulating powder coating processing, including high-pressure module and fuselage and the sleeve of setting on the fuselage, high-pressure module with the sleeve is connected, its characterized in that still includes mashing assembly, mashing assembly is including rotating the output pole of connecting on the fuselage, swing joint has mashing frame on the output pole, be circumference array swing joint on the mashing frame has the cutting board, fixedly connected with helical blade on the mashing frame, the discharge opening has been seted up to mashing frame's first end, the discharge opening with the sleeve is linked together, swing joint has series excitation motor on the fuselage, series excitation motor's output is provided with the action wheel, swing joint has the follow driving wheel on the output pole, the action wheel meshes with the follow driving wheel, threaded connection has the sprinkler head on the sleeve, be provided with the stopper on the sprinkler head, the joint has the sealing washer on the stopper, the sprinkler cup joint cover with the stopper contacts, the device through making even improvement powder coating to spray effect, however can't carry out the comparatively poor ration feeding to the difficult to the actual ration material, can't carry out the step in the difficult and the difficult to carry out the ration feeding to the material, the ration is difficult to the step is carried out in the actual ration feeding.

Disclosure of Invention

Aiming at the defects that in the prior art, the effect of quantitatively feeding a powder material is poor in actual use, the quantitative feeding of the powder material of a coating is relatively complicated, the quantitative feeding of the powder material of the coating cannot be relatively fast, and part of equipment does not have the quantitative feeding function, the quantitative feeding cannot be automatically and quantitatively fed by manual regulation and control, and the daily use of a user is not facilitated, the invention provides the quantitative feeding device for processing the insulating powder coating, which has the advantages of fast quantitative feeding, spontaneous quantitative feeding, no need of manual real-time regulation and control and the like.

In order to achieve the above purpose, the present invention provides the following technical solutions: a quantitative feeding device for processing insulating powder coating, comprising: the device comprises a first conveying belt, a hydraulic cylinder, a hydraulic rod, a first sliding block, a second conveying belt, a first sliding groove, a baffle, a first quality sensor, a first support, a control center, a crushing device, a feed inlet, a shaft rod, a first crushing roller, a second crushing roller, crushing teeth, a pressing plate, a discharge hole, a second quality sensor, a clamp, a collecting bin, a crushing barrel, a feed groove, a second support, a discharge hole, a servo motor, a first rotating shaft, crushing leaves, a driving device, a driving motor, a through groove, a second rotating shaft, a screw rod, a push rod, an inner screw hole, a second sliding block, a movable groove, a second sliding groove, a sliding rail, a fixed rod, a movable rod, a sliding rod, a limiting plate, a spring, a telescopic rod, a limiting groove, a first through hole, a third sliding groove, a limiting plate, a second through hole and a third sliding block.

The positions and connection relations of the structures are as follows: the quantitative feeding device for processing the insulating powder coating comprises a first conveying belt, a control center, a crushing device, a collecting bin and a crushing barrel, wherein four hydraulic cylinders which are symmetrical to each other are arranged at the bottom of the first conveying belt, the top output ends of the hydraulic cylinders are in differential connection with hydraulic rods, the hydraulic rods are fixedly connected with the bottom of the first conveying belt, the first sliding blocks are fixedly connected with the outer surfaces of the rightmost front end and the rear end of the first conveying belt, a second conveying belt is arranged at one end, close to the first sliding blocks, of the first conveying belt, first sliding grooves matched with the first sliding blocks are formed in the front end and the rear end, close to the first sliding blocks, of the second conveying belt, the first sliding groove is arranged on the front end and the rear end surface inside the second conveying belt in a numerical value, the first conveying belt is in sliding connection with the second conveying belt through the first sliding blocks and the first sliding grooves, one end of the second conveyor belt, which is close to the first conveyor belt, is fixedly connected with a baffle plate, the baffle plate is arranged on the right side of the first chute, the bottom of the second conveyor belt is fixedly connected with a first quality sensor, the bottom of the first quality sensor is fixedly connected with a first bracket, the front end of the second conveyor belt is provided with a control center, the control center and a hydraulic cylinder are electrically connected with the first quality sensor, one end of the second conveyor belt, which is far away from the first conveyor belt, is fixedly connected with a crushing device, the uncrushed coating material is placed on the first conveyor belt for transportation, the first conveyor belt is used for transporting the coating material onto the second conveyor belt, the first quality sensor at the bottom of the second conveyor belt presets the numerical value of the sum of the weight of the second conveyor belt and the weight of the coating powder fed once, when the first conveyor belt is used for transporting a certain amount of coating material, the first quality sensor detects that the second conveyer belt measured at the top and the transported coating materials reach the set value and transmit electric signals to the control center, the control center controls the hydraulic cylinder to drive the hydraulic rod to move downwards, the hydraulic rod moves downwards to drive the first conveyer belt to move downwards through the first sliding block and the first sliding groove, at the moment, the position of the baffle is located on the right side of the first conveyer belt to block the non-transported coating materials, the second conveyer belt conveys the detected coating materials into the smashing device to be smashed, then the collection bin is connected with the spraying equipment to spray insulating coating materials, then the first quality sensor stops transmitting electric signals to the control center after the second conveyer belt top coating materials are conveyed, the control center controls the hydraulic rod to drive the hydraulic rod to move upwards, the first conveyer belt is enabled to continue to convey the coating materials to the second conveyer belt to carry out quantitative transportation after being reset through the first sliding block and the first sliding groove, the device can carry out smashing after quantifying on the coating materials, the quantitative accuracy of the device and the quantitative smashing degree of the device are improved, and daily use of the device is facilitated.

Preferably, the feed inlet has been seted up at reducing mechanism's top, reducing mechanism's inside is transferred and is connected with two axostylus axostyles of mutual symmetry, one of them axostylus axostyle rear end external has three-phase motor, the front end fixedly connected with of left side axostylus axostyle first crushing roller, the front end fixedly connected with of right side axostylus axostyle and the second crushing roller of first crushing roller looks adaptation smash the roller, intermesh between first crushing roller and the second crushing roller, after the second conveyer belt transports the coating material after transporting to reducing mechanism, the coating material enters into reducing mechanism inside from the feed inlet by dropping to between first crushing roller and the second crushing roller, drive two axostylus axostyles respectively through opening two three-phase motor and make first crushing roller and the relative rotation of second crushing roller carry out the powdering, some fragments can fall to reducing mechanism's inner wall or the clamp plate department when first crushing roller and second crushing roller will smash the coating, first crushing roller cooperates with the crushing tooth of reducing mechanism left side inner wall and second crushing roller and the crushing roller cooperatees the crushing tooth that supports fixed clamp plate and disintegrates and will go out the fragment to carry out the powder, the device does not completely to reduce the powder to the coating material.

Preferably, the inside right side fixedly connected with of reducing mechanism supports the clamp plate, and the inside one end inner wall that is close to first crushing roller of reducing mechanism and the one end surface that supports the clamp plate and be close to the second crushing roller equal fixedly connected with crushing tooth, the discharge gate has been seted up to the slope of reducing mechanism's right side bottom, and the inclination of discharge gate is 45-60, and coating powder falls to the discharge gate that the slope set up and falls to collect in the storehouse under the effect of earth's gravity and carry out quantitative collection, and the external spraying equipment feed in storehouse is collected afterwards, has certain clearance between second crushing roller and the clamp plate, guarantees the normal operating of device.

Preferably, the right side of reducing mechanism is provided with second quality sensor, and second quality sensor external has control switch, second quality sensor and control switch and control center electric connection, and the top fixedly connected with fixture of second quality sensor, the top joint of fixture has the collection storehouse, and the collection storehouse sets up the bottom at the discharge gate, and second quality sensor sets up in advance and collects the numerical value of storehouse and fixture plus needs single feed coating powder, and the second sensor is in the state of closing when using first conveyer belt, second conveyer belt and reducing mechanism to carry out quantitative feed, and the fixture is used for carrying out the joint to the position of collection storehouse fixedly, guarantees the normal operating of device.

Preferably, the top of collecting the storehouse is provided with crushing bucket, and the front end fixedly connected with second support of crushing bucket, crushing bucket rear end fixedly connected with feed chute, a plurality of discharge opening has been seted up to the bottom of crushing bucket, and the aperture of discharge opening is greater than insulating powder's diameter, and the second support that crushing bucket bottom set up is used for supporting crushing bucket, and the feed chute is used for carrying out the powdering with coating material transmission to crushing bucket in, and the discharge opening is used for dropping coating powder to the limit inslot under the effect of earth's gravity and carries out quantitative feeding, guarantees the normal operating of device.

Preferably, the top fixedly connected with servo motor of crushing bucket, the bottom output fixedly connected with first axis of rotation of servo motor, the surface fixedly connected with of first axis of rotation is a plurality of crushing leaf that is circumference distribution, servo motor and control center electric connection, when coating material enters into crushing bucket inside through the feed chute, utilizes control center to open servo motor and drives first axis of rotation and rotate, and first axis of rotation rotates and drives crushing leaf and rotate and carry out the powdering treatment with coating material, guarantees the normal operating of device.

Preferably, the front end of smashing the bucket is provided with drive arrangement, drive arrangement's inside top layer fixedly connected with driving motor, driving motor and control center electric connection, driving motor's bottom output fixedly connected with second axis of rotation, the bottom fixedly connected with screw rod of second axis of rotation, the bottom of screw rod is provided with the push rod, the one end that the push rod is close to the screw rod has been seted up with the interior screw of screw rod looks adaptation, interior screw extends to inside the push rod, the push rod passes through interior screw and screw rod threaded connection, the bottom fixedly connected with second slider of push rod, when the coating powder drops to the limit inslot through the discharge opening, the powder drops to the collection storehouse through the limit inslot, it detects to collect the inside coating powder quality of storehouse to open by control center control second quality sensor, when the numerical value of collection storehouse and fixture plus coating powder reaches the second sensor and presets the setting, the inside driving motor of control center control screw hole opens the corotation, the driving motor corotation drives the second axis of rotation, the second axis of rotation drives the screw rod rotation, the screw rod rotation is driven through interior drive push rod, the push rod moves towards push rod drive arrangement rear end, the slide rail moves, the device provides the normal feed through the power to the device for the coating powder, it moves to carry out the device to the powder to quantitatively move.

Preferably, the rear end intermediate position of second slider has seted up the movable groove, the movable groove is circular-arc, the inside left and right sides of movable groove has all been seted up with the different second spout of movable groove shape the same proportion, drive arrangement's inside front end fixedly connected with slide rail, slide rail and second slider sliding connection, the inside dead lever that is provided with of movable groove, the bottom of dead lever is provided with the limiting plate, the bottom fixedly connected with movable rod of limiting plate, the slide bar of the equal fixedly connected with of the left and right sides of movable rod and second spout looks adaptation, the rear end fixedly connected with spring of limiting plate, the dead lever cup joints inside the spring, when the second slider passes through slide rail downwardly moving, the second slider removes to drive the dead lever and passes through the movable rod, slide bar and second spout limit groove rear end slip in the movable groove department of second slider, guarantee the normal operating of device.

Preferably, the through groove matched with the fixed rod is formed in the rear end surface of the driving device, one end of the fixed rod, which is far away from the limiting plate, is fixedly connected with the telescopic rod, the diameter of the telescopic rod is larger than the diameter of the through groove, one end of the through groove, which is close to the fixed rod, is fixedly connected with the spring, when the fixed rod slides at the rear end of the limiting groove at the movable groove of the second sliding block through the movable rod, the sliding rod and the second sliding groove, the fixed rod moves and drives the telescopic rod to move towards the rear end of the limiting groove through the through groove, the space between the through groove and the fixed rod is reduced in the moving process of the fixed rod, so that the spring is compressed and elastic deformation is formed, and a part of power is provided for resetting the limiting plate in the limiting groove after the single quantitative feeding is finished, so that the normal operation of the device is ensured.

Preferably, a limiting trough is arranged at the bottom of the crushing barrel, a plurality of first through holes are formed in the bottom of the limiting trough, a third chute is formed in the front end surface and the rear end surface of the inside of the limiting trough, a limiting plate is arranged at the top of the limiting trough, the limiting plate is telescopically and fixedly connected to the front end surface of the limiting plate, a plurality of second through holes with the same aperture as the first through holes are formed in the top of the limiting plate, third sliding blocks are fixedly connected to the left side surface and the right side surface of the limiting plate, the limiting plate is in sliding connection with the limiting trough through the third sliding blocks and the third chute, the length of the third chute is the interval distance between the two first through holes, the fixing rod moves and drives the telescopic rod to move towards the rear end of the limiting trough through the through grooves, the telescopic rod moves to drive the limiting plate to move in the limiting trough through the third sliding blocks and the third chute, and the first through holes and the second through holes are staggered with each other when the third sliding blocks move to the rearmost end of the third chute, at this time, the coating powder can not fall into the collecting bin through the first through hole to finish quantitative feeding in a short time, and the collecting bin does not contain the coating powder after finishing single quantitative feeding in a short time, at this time, the control center is used for controlling the driving motor to reversely rotate, the driving motor reversely rotates to drive the second rotating shaft and the screw rod to reversely rotate, the screw rod reversely rotates to drive the push rod to move towards the driving motor through the inner screw hole, the push rod moves to drive the second slide block to move towards the driving motor in the direction of the slide rail, the second slide block moves to drive the fixed rod and the telescopic rod to do linear motion far away from the limiting groove through the movable rod, the second slide groove and the slide rod, the telescopic rod moves to drive the limiting plate to the foremost end of the third slide groove through the third slide block and the third slide groove to enable the first through hole to coincide with the second through hole, then coating powder accessible second through-hole drops to collect the storehouse and continue carrying out single ration feeding from first through-hole, the elasticity that elastic deformation recovery produced in this in-process spring has accelerated the coincidence efficiency of first through-hole and second through-hole on the dead lever for the device can be quick smash back ration feeding to coating material, and for the ration feeding that adopts this scheme of first conveyer belt, second conveyer belt and reducing mechanism more stable, promoted the ration feeding efficiency of device simultaneously, the user of being convenient for daily use.

The beneficial effects are that: 1, this quantitative feed arrangement is used in insulating powder coating processing, through quantitative feed arrangement is used in insulating powder coating processing, including first conveyer belt, control center, reducing mechanism, collection storehouse and crushing bucket, be provided with four mutual symmetrical pneumatic cylinders between two liang of first conveyer belt, the top output differential connection of pneumatic cylinder has the hydraulic stem, the bottom fixed connection of hydraulic stem and first conveyer belt, the equal fixedly connected with first slider of the right side front end and rear end surface of first conveyer belt, the one end that first conveyer belt is close to first slider is provided with the second conveyer belt, the first spout with first slider looks adaptation has all been seted up to the inside front end of one end and rear end that second conveyer belt is close to first slider, first spout numerical value is seted up at the inside front end and rear end surface of second conveyer belt, the one end fixedly connected with baffle of second conveyer belt is close to first conveyer belt through first slider and first spout, the bottom fixedly connected with first quality sensor of second conveyer belt, first quality sensor is close to first quality sensor is convenient for carry out the first quantitative feed arrangement, the first quality sensor is good at first quality sensor is connected with the first end, the first quality sensor is far away from the first user, the first quality sensor is convenient for use to carry out the quantitative feed arrangement, the first quality sensor is connected with the first conveyer belt, the user has the quality sensor is good for the quality control, and the quality sensor is convenient to carry out.

2. This ration feed arrangement is used in insulating powder coating processing is provided with second quality sensor through reducing mechanism's right side, second quality sensor external has control switch, second quality sensor and control switch and control center electric connection, the top fixedly connected with fixture of second quality sensor, the top joint of fixture has the collection storehouse, collect the storehouse setting in the bottom of discharge gate, second quality sensor sets up in advance and collects the numerical value of storehouse and fixture plus the sum that needs single feed coating powder, the fixture is used for carrying out the joint to the position of collecting the storehouse fixedly, make the device need not to carry out real-time control and can spontaneous carry out the ration feeding to coating powder, guarantee the normal operating of device.

3. This ration feed arrangement is used in insulating powder coating processing, be provided with the limit silo through smashing the bottom of bucket, a plurality of first through-hole has been seted up to the bottom of limit silo, the third spout has all been seted up on limit silo inside front end and rear end surface, the top of limit silo is provided with the limited flitch, flexible fixed connection is at the front end surface of limit flitch, a plurality of second through-hole the same with first through-hole aperture has been seted up at the top of limit flitch, the third slider of the equal fixedly connected with in left and right sides surface of limit flitch, limit flitch passes through third slider and third spout and limit silo sliding connection, the length of third spout is the interval between two first through-holes, make the device can be quick smash the back ration feeding to coating material, for adopting first conveyer belt, the ration feeding of this scheme of second conveyer belt and reducing mechanism is more stable, the ration feeding efficiency of device has been promoted simultaneously, the daily use of user of being convenient for.

Drawings

FIG. 1 is a schematic view of the appearance and structure of a quantitative feeding device for processing insulating powder coating;

FIG. 2 is a schematic diagram showing the rear view of a quantitative feeding device for processing insulating powder coating according to the present invention;

FIG. 3 is a schematic diagram of the structure of a first conveyor belt and a second conveyor belt of a quantitative feeding device for processing insulating powder coating;

FIG. 4 is a schematic diagram showing the structure of a crushing device of a quantitative feeding device for processing insulating powder coating;

FIG. 5 is a schematic diagram showing the rear view of a pulverizing barrel of a quantitative feeding device for processing insulating powder coating according to the present invention;

FIG. 6 is a schematic diagram showing the side view of the inside of a pulverizing barrel of a quantitative feeding device for processing insulating powder coating;

FIG. 7 is a schematic diagram showing the internal side view and transverse arrangement of a driving device of a quantitative feeding device for processing insulating powder coating;

FIG. 8 is a schematic view of a rotary transverse structure of a second slider of a quantitative feeding device for processing insulating powder coating according to the present invention;

FIG. 9 is a schematic view showing a transverse structure of a fixing rod of a quantitative feeding device for processing insulating powder coating;

FIG. 10 is a schematic diagram showing the top view of a material limiting groove and a material limiting plate of a quantitative feeding device for processing insulating powder coating;

FIG. 11 is a schematic diagram of a first operation logic structure of a control center of a quantitative feeding device for processing an insulating powder coating according to the present invention;

FIG. 12 is a schematic diagram of a second operational logic of a control center of a metering device for processing an insulating powder coating according to the present invention.

In the figure: 1. a first conveyor belt; 10. a hydraulic cylinder; 100. a hydraulic rod; 11. a first slider; 12. a second conveyor belt; 120. a first chute; 121. a baffle; 122. a first mass sensor; 123. a first bracket; 2. a control center; 3. a pulverizing device; 30. a feed inlet; 31. a shaft lever; 32. a first pulverizing roller; 33. a second pulverizing roller; 34. crushing teeth; 35. a pressing plate; 36. a discharge port; 4. a second mass sensor; 40. a clamp; 41. a collecting bin; 5. crushing a barrel; 50. a feed chute; 500. a second bracket; 501. a discharge hole; 51. a servo motor; 510. a first rotation shaft; 511. crushing leaves; 52. a driving device; 520. a driving motor; 5200. a through groove; 521. a second rotation shaft; 53. a screw; 54. a push rod; 540. an inner screw hole; 55. a second slider; 550. a movable groove; 551. a second chute; 56. a slide rail; 57. a fixed rod; 570. a movable rod; 571. a slide bar; 572. a limiting plate; 58. a spring; 59. a telescopic rod; 6. a material limiting groove; 60. a first through hole; 600. a third chute; 61. a material limiting plate; 610. a second through hole; 62. and a third slider.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. 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.

Example 1: referring to fig. 1-11, a quantitative feeding device for processing insulating powder coating comprises a first conveyor belt 1, a control center 2, a crushing device 3, a collecting bin 41 and a crushing barrel 5, wherein four symmetrical hydraulic cylinders 10 are arranged at the bottom of the first conveyor belt 1, a hydraulic rod 100 is connected with the top output end of the hydraulic cylinder 10 in a differential mode, the hydraulic rod 100 is fixedly connected with the bottom of the first conveyor belt 1, the outer surfaces of the front end and the rear end of the rightmost side of the first conveyor belt 1 are fixedly connected with a first sliding block 11, one end of the first conveyor belt 1 close to the first sliding block 11 is provided with a second conveyor belt 12, the front end and the rear end of one end of the second conveyor belt 12 close to the first sliding block 11 are provided with first sliding grooves 120 matched with the first sliding block 11, the first sliding grooves 120 are formed in the front end and the rear end surface of the inner part of the second conveyor belt 12 in a numerical mode, the first conveyor belt 1 is in sliding connection with the second conveyor belt 12 through the first sliding block 11 and the first sliding groove 120, one end of the second conveyor belt 12, which is close to the first conveyor belt 1, is fixedly connected with a baffle plate 121, the baffle plate 121 is arranged on the right side of the first sliding groove 120, the bottom of the second conveyor belt 12 is fixedly connected with a first mass sensor 122, the bottom of the first mass sensor 122 is fixedly connected with a first bracket 123, the front end of the second conveyor belt 12 is provided with a control center 2, the control center 2 and the hydraulic cylinder 10 are electrically connected with the first mass sensor 122, one end of the second conveyor belt 12, which is far away from the first conveyor belt 1, is fixedly connected with a crushing device 3, the uncrushed coating material is placed on the first conveyor belt 1 for transportation, the first conveyor belt 1 transports the coating material onto the second conveyor belt 12, the first mass sensor 122 at the bottom of the second conveyor belt 12 presets the value of the sum of the weight of the second conveyor belt 12 and the weight of the coating powder fed once, the first mass sensor 122 at the bottom of the second conveyor belt 12 is internally provided with a 51 single-chip microcomputer, an amplifying circuit and other components, the value of the sum of the weight of the second conveyor belt 12 and the weight of the coating powder fed once is preset in the 51 single-chip microcomputer, the value is converted into an electric signal when the first mass sensor 122 detects the sum of the total masses of the materials at the top of the second conveyor belt 12 and the second conveyor belt 122, the electric signal is transmitted to the 51 single-chip microcomputer, the 51 single-chip microcomputer outputs the electric signal to the control center 2 through the amplifying circuit when the analysis detection mass exceeds or is equal to the preset sum (the prior art and is not repeated here), when the first conveyor belt 1 conveys a certain amount of coating materials, the first quality sensor 122 detects that the second conveyor belt 12 measured at the top and the conveyed coating materials reach a set value, an electric signal is transmitted to the control center 2, the control center 2 controls the hydraulic cylinder 10 to drive the hydraulic rod 100 to move downwards, the hydraulic rod 100 moves downwards to drive the first conveyor belt 1 to move downwards through the first sliding block 11 and the first sliding groove 120, at the moment, the position of the baffle plate 121 is positioned at the right side of the first conveyor belt 1 to block the non-conveyed coating materials, the second conveyor belt 12 conveys the detected coating materials into the crushing device 3 to be powdered and then is collected by the collecting bin 41, the collecting bin 41 can be externally connected with spraying equipment to spray insulating coating powder, then after the top coating materials of the second conveyor belt 12 are conveyed, the first quality sensor 122 stops transmitting the electric signal to the control center 2, the control center 2 controls the hydraulic cylinder 10 to drive the hydraulic rod 100 to rise, the hydraulic stem 100 rises to enable the first conveyor belt 1 to continue to transport the coating material to the second conveyor belt 12 for quantitative transportation after resetting through the first sliding block 11 and the first sliding groove 120, so that the device can crush the coating material after quantifying rapidly, the quantitative accuracy of the device and the quantitative crushing degree of the device are improved, and the daily use of a user is facilitated.

The top of reducing mechanism 3 has offered feed inlet 30, the inside of reducing mechanism 3 is transferred and is connected with two mutually symmetrical axostylus axostyles 31, the external three-phase motor that has of axostylus axostyle 31 rear end, the front end fixedly connected with first crushing roller 32 of left side axostylus axostyle 31, the front end fixedly connected with of right side axostylus axostyle 31 with the second crushing roller 33 of first crushing roller 32 looks adaptation, intermesh between first crushing roller 32 and the second crushing roller 33, after the second conveyer 12 transports the coating material after transporting to reducing mechanism 3, the coating material enters into reducing mechanism 3 from feed inlet 30 inside by dropping to between first crushing roller 32 and the second crushing roller 33, drive two axostylus axostyles 31 rotation respectively and make first crushing roller 32 and second crushing roller 33 relative rotation carry out the powdering treatment, some crushing rollers 32 and second crushing roller 33 will fall to the inner wall or support clamp plate 35 department of reducing mechanism 3 when the coating will smash, under the drive of 31 first crushing roller 32 and crushing device 3 left side inner wall crushing tooth and second crushing roller 34 and the subsides of the complete device of the subsidence of powder material of fragment and prevent the subsidence of fragment device.

The inside right side fixedly connected with of reducing mechanism 3 supports clamp plate 35, the inside one end inner wall that is close to first crushing roller 32 of reducing mechanism 3 and the one end surface that supports clamp plate 35 and is close to second crushing roller 33 all fixedly connected with crushing tooth 34, the discharge gate 36 has been seted up to the slope of reducing mechanism 3's right side bottom, the inclination of discharge gate 36 is between 45-60, the coating powder falls in the discharge gate 36 that the slope set up and falls under the effect of earth's gravity and collect in storehouse 41 to carry out quantitative collection, collect the external spraying equipment feeding in storehouse 41 afterwards, guarantee the normal operating of device, fig. 11 is the operational flow diagram of embodiment one.

Example 2: referring to fig. 1-4, a second mass sensor 4 is disposed on the right side of the crushing device 3, a control switch is externally connected to the second mass sensor 4, the second mass sensor 4 and the control switch are electrically connected with the control center 2, a clamp 40 is fixedly connected to the top of the second mass sensor 4, a collecting bin 41 is clamped to the top of the clamp 40, the collecting bin 41 is disposed at the bottom of the discharge port 36, a value of the sum of the required single-time feeding of coating powder is preset by the second mass sensor 4 and the collecting bin 41, the second mass sensor is in a closed state when the first conveyor belt 1, the second conveyor belt 12 and the crushing device 3 are used for carrying out clamping and fixing on the position of the collecting bin 41, so that the device does not need to carry out real-time control and can spontaneously carry out quantitative feeding on the coating powder, and normal operation of the device is ensured.

Example 3: referring to fig. 1-12, a crushing barrel 5 is arranged at the top of the collecting bin 41, a second bracket 500 is fixedly connected to the front end of the crushing barrel 5, a feeding groove 50 is fixedly connected to the rear end of the crushing barrel 5, a plurality of discharging holes 501 are formed in the bottom of the crushing barrel 5, the aperture of each discharging hole 501 is larger than the diameter of insulating powder, the second bracket 500 arranged at the bottom of the crushing barrel 5 is used for supporting the crushing barrel 5, the feeding groove 50 is used for conveying coating materials into the crushing barrel 5 for powdering treatment, the discharging holes 501 are used for enabling the coating powder to fall into a limiting groove 6 for quantitative feeding under the action of gravity, and normal operation of the device is guaranteed.

The top fixedly connected with servo motor 51 of crushing bucket 5, servo motor 51's bottom output fixedly connected with first pivot axle 510, the surface fixedly connected with of first pivot axle 510 is a plurality of crushing leaf 511 that are circumference distribution, servo motor 51 and control center 2 electric connection, when the coating material enters into crushing bucket 5 inside through feed chute 50, utilize control center 2 to open servo motor 51 and drive first pivot axle 510 and rotate, first pivot axle 510 rotates and drives crushing leaf 511 and rotate and carry out the powdering treatment with the coating material, guarantee the normal operating of device.

The front end of the crushing barrel 5 is provided with a driving device 52, the top layer inside the driving device 52 is fixedly connected with a driving motor 520, the driving motor 520 is electrically connected with a control center 2, the bottom output end of the driving motor 520 is fixedly connected with a second rotating shaft 521, the bottom of the second rotating shaft 521 is fixedly connected with a screw 53, the bottom of the screw 53 is provided with a push rod 54, one end of the push rod 54 close to the screw 53 is provided with an inner screw hole 540 matched with the screw 53, the inner screw hole 540 extends to the inside of the push rod 54, the push rod 54 is in threaded connection with the screw 53 through the inner screw hole 540, the bottom of the push rod 54 is fixedly connected with a second sliding block 55, when paint powder falls into a limiting groove 6 through a discharging hole 501, the powder falls into a collecting bin 41 through the limiting groove 6, the second quality sensor 4 is controlled by the control center 2 to detect the quality of the paint powder in the collecting bin 41, when the value of the sum of the paint powder in the collecting bin 41 and a clamp 40 reaches the preset setting of the second sensor, the second quality sensor 4 is emitted to the control center 2, the driving motor 520 in the inside the control center 2 controls the driving motor 520 to be in a positive rotation, the push rod 54 is in the driving device 52 to be in the positive rotation, the sliding rail 53 is driven by the sliding block 55 to be driven by the second quality sensor, the second sliding block 53 to be driven by the second sliding block 53 to normally to rotate, and the second sliding block 53 is driven to normally to move forward, and the second sliding block 53 to rotate, and the paint powder is guaranteed to rotate.

The rear end intermediate position of second slider 55 has seted up movable groove 550, movable groove 550 is circular-arc, the inside left and right sides of movable groove 550 has all seted up the second spout 551 different with movable groove 550 shape the same proportion, the inside front end fixedly connected with slide rail 56 of drive arrangement 52, slide rail 56 and second slider 55 sliding connection, movable groove 550 inside is provided with dead lever 57, the bottom of dead lever 57 is provided with limiting plate 572, the bottom fixedly connected with movable lever 570 of limiting plate 572, the slide bar 571 with second spout 551 looks adaptation is all fixedly connected with in the left and right sides of movable lever 570, the rear end fixedly connected with spring 58 of limiting plate 572, dead lever 57 cup joints inside spring 58, when second slider 55 moves down through slide rail 56, second slider 55 moves and drives dead lever 57 through movable lever 570, slide bar 571 and second spout 551 limit groove 6 rear end slip in the movable groove 550 department of second slider 55, guarantee the normal operating of device.

The rear end surface of the driving device 52 is provided with a through groove 5200 which is matched with the fixed rod 57, one end, away from the limiting plate 572, of the fixed rod 57 is fixedly connected with a telescopic rod 59, the diameter of the telescopic rod 59 is larger than the aperture of the through groove 5200, one end, close to the fixed rod 57, of the through groove 5200 is fixedly connected with a spring 58, when the fixed rod 57 slides at the rear end of the limiting groove 6 at the movable groove 550 of the second sliding block 55 through the movable rod 570, the sliding rod 571 and the second sliding groove 551, the fixed rod 57 moves and drives the telescopic rod 59 to move towards the rear end of the limiting groove 6 through the through groove 5200, the distance between the through groove 5200 and the fixed rod 57 is reduced in the moving process of the fixed rod 57, so that the spring 58 is compressed and elastically deformed, a part of power is provided for resetting the limiting plate 61 in the limiting groove 6 after single quantitative feeding of the device is finished, and normal operation of the device is ensured.

The bottom of the crushing barrel 5 is provided with a limiting trough 6, the bottom of the limiting trough 6 is provided with a plurality of first through holes 60, the front end and the rear end surface inside the limiting trough 6 are respectively provided with a third chute 600, the top of the limiting trough 6 is provided with a limiting plate 61, the limiting plate 61 is telescopically and fixedly connected to the front end surface of the limiting plate 61, the top of the limiting plate 61 is provided with a plurality of second through holes 610 with the same aperture as the first through holes 60, the left side surface and the right side surface of the limiting plate 61 are respectively fixedly connected with a third slide block 62, the limiting plate 61 is in sliding connection with the limiting trough 6 through the third slide blocks 62 and the third chute 600, the length of the third chute 600 is the interval distance between the two first through holes 60, the fixed rod 57 moves and drives the telescopic rod 59 to move towards the rear end of the limiting trough 6 through a through groove 5200, the telescopic rod 59 moves to drive the limiting plate 572 to move in the limiting trough through the third slide blocks 62 and the third chute 600, when the third sliding block 62 moves to the rearmost end of the third sliding groove 600, the first through hole 60 and the second through hole 610 are staggered, at this time, the coating powder cannot fall into the collecting bin 41 through the first through hole 60 in a short time to finish quantitative feeding, and similarly, after finishing single quantitative feeding in a short time, the collecting bin 41 no longer contains the coating powder, at this time, the control center 2 is used for controlling the driving motor 520 to rotate reversely, the driving motor 520 rotates reversely to drive the second rotating shaft 521 and the screw 53 to rotate reversely, the screw 53 rotates reversely, the inner screw hole 540 drives the push rod 54 to move towards the driving motor 520, the push rod 54 moves to drive the second sliding block 55 to move towards the driving motor 520 in the direction of the sliding rail 56, the second sliding block 55 moves to drive the fixed rod 57 and the telescopic rod 59 to do linear movement away from the limiting groove 6 through the movable rod 570, the second sliding groove 551 and the sliding rod 571, the telescopic rod 59 moves to drive the limiting plate 61 to move to the forefront end of the third sliding groove 600 through the third sliding block 62 and the third sliding groove 600 so that the first through hole 60 is overlapped with the second through hole 610, then the coating powder can fall from the first through hole 60 to the collecting bin 41 through the second through hole 610 to continue single quantitative feeding, in the process, the elastic force generated by elastic deformation recovery of the spring 58 acts on the fixing rod 57 to accelerate the overlapping efficiency of the first through hole 60 and the second through hole 610, the quantitative feeding after the device can crush the coating material rapidly is enabled to be more stable, the quantitative feeding efficiency of the device is improved simultaneously, the daily use of a user is facilitated, and fig. 12 is a running flow chart of the third embodiment.

In the first embodiment, only the first conveyor belt 1, the second conveyor belt 12, the crushing device 3, the control center 2 and the collection bin 41 are used for carrying out quantitative post-powdering treatment feeding on the coating material, so that the device can rapidly carry out quantitative post-powdering on the coating material.

Working principle: the non-crushed coating materials are placed on a first conveyor belt 1 for transportation, the first conveyor belt 1 conveys the coating materials to a second conveyor belt 12, a 51 single-chip microcomputer, an amplifying circuit and other components are arranged in a first mass sensor 122 at the bottom of the second conveyor belt 12, the numerical value of the sum of the weight of the second conveyor belt 12 and the weight of the coating powder fed once is preset in the 51 single-chip microcomputer, the first mass sensor 122 detects the sum of the total masses of the materials at the tops of the second conveyor belt 12 and the second conveyor belt 122 and converts the sum into an electric signal to be transmitted to the 51 single-chip microcomputer, the 51 single-chip microcomputer outputs the electric signal to be transmitted to a control center 2 through the amplifying circuit when the analysis detection mass exceeds or is equal to the preset sum, when the first conveyor belt 1 conveys a certain amount of coating material, the first mass sensor 122 detects that the second conveyor belt 12 measured at the top and the conveyed coating material reach a preset value, an electric signal is transmitted to the control center 2, the control center 2 controls the hydraulic cylinder 10 to drive the hydraulic rod 100 to descend, the hydraulic rod 100 descends to drive the first conveyor belt 1 to move downwards through the first sliding block 11 and the first sliding groove 120, at the moment, the position of the baffle 121 is positioned on the right side of the first conveyor belt 1 to block the non-conveyed coating material, the second conveyor belt 12 conveys the detected coating material into the crushing device 3 to be powdered, the coating material enters the crushing device 3 from the feed inlet 30 and falls between the first crushing roller 32 and the second crushing roller 33, the three-phase motor is started to respectively drive one shaft lever 31 to rotate so that the first crushing roller 32 and the second crushing roller 33 relatively rotate to carry out powdering treatment, when the first crushing roller 32 and the second crushing roller 33 crush paint, some fragments fall to the inner wall of the crushing device 3 or the pressing plate 35, a certain gap exists between the second crushing roller 33 and the pressing plate 35, the first crushing roller 32 is matched with the crushing teeth 34 on the left inner wall of the crushing device 3 under the drive of the shaft rod 31, the second crushing roller 33 is matched with the crushing teeth 34 fixedly connected with the pressing plate 35 to crush the crushed fragments, the paint powder falls to the discharge hole 36 which is obliquely arranged and falls into the collection bin 41 under the action of gravity for quantitative collection, the collection bin 41 can be externally connected with spraying equipment to spray insulating paint powder, then the first quality sensor 122 stops transmitting an electric signal to the control center 2 after the paint material at the top of the second conveyor belt 12 is conveyed, the control center 2 controls the hydraulic cylinder 10 to drive the hydraulic rod 100 to rise, the first conveyor belt 1 is reset through the first sliding block 11 and the first sliding block 120, and then the paint material is conveyed to the second conveyor belt 12 for quantitative conveying, and the quantitative crushing device is improved relative to the quantitative precision and the quantitative crushing device of the second embodiment.

When paint materials enter the crushing barrel 5 through the feed chute 50, the servo motor 51 is started by the control center 2 to drive the first rotating shaft 510 to rotate, the first rotating shaft 510 rotates to drive the crushing blade 511 to rotate so as to carry out powdering treatment on the paint materials, when the paint powder falls into the material limiting chute 6 through the discharge hole 501, the powder falls into the collecting bin 41 through the material limiting chute 6, the control center 2 controls the second mass sensor 4 to start to detect the quality of the paint powder in the collecting bin 41, the second mass sensor 4 is the same as the first mass sensor 122 in technology, when the sum of the collecting bin 41 and the clamp 40 plus the paint powder reaches the preset setting of the second sensor, the second mass sensor 4 emits an electric signal to the control center 2, the control center 2 controls the driving motor 520 in the driving device 52 to start to rotate positively, the driving motor 520 rotates positively to drive the second rotating shaft 521 to rotate, the second rotating shaft 521 rotates positively to drive the screw 53 to rotate, the screw 53 rotates to drive the push rod 54 to move towards the rear end of the driving device 52 through the inner screw hole 540, the push rod 54 moves to drive the second sliding block 55 to move through the sliding rail 56, when the second sliding block 55 moves downwards through the sliding rail 56, the second sliding block 55 moves to drive the fixed rod 57 to slide towards the rear end of the limiting groove 6 at the position of the movable groove 550 of the second sliding block 55 through the movable rod 570, the sliding rod 571 and the second sliding groove 551, when the fixed rod 57 slides towards the rear end of the limiting groove 6 at the position of the movable groove 550 of the second sliding block 55 through the movable rod 570, the sliding rod 571 and the second sliding groove 551, the fixed rod 57 moves and drives the telescopic rod 59 to move towards the rear end of the limiting groove 6 through the groove 5200, the fixed rod 57 moves in the through the groove 5200 and limits the telescopic rod 59, the telescopic rod 59 cannot move into the driving device 52 through the groove 5200, the space between the through groove 5200 and the fixing rod 57 is reduced in the moving process of the fixing rod 57, so that the spring 58 is compressed and elastically deformed, the first through hole 60 and the second through hole 610 are mutually staggered when the third sliding block 62 moves to the rearmost end of the third sliding groove 600, at this time, the coating powder cannot fall into the collecting bin 41 through the first through hole 60 to finish quantitative feeding in a short time, and meanwhile, the collecting bin 41 does not contain coating powder after finishing single quantitative feeding in a short time, at this time, the driving motor 520 is controlled to rotate reversely by the control center 2, the driving motor 520 rotates reversely to drive the second rotating shaft 521 and the screw 53 to rotate reversely, the screw 53 rotates reversely to drive the push rod 54 to move towards the driving motor 520 through the inner screw hole 540, the push rod 54 moves to drive the second sliding block 55 to move towards the driving motor 520 in the direction of the sliding rail 56, the second sliding block 55 moves to drive the fixed rod 57 and the telescopic rod 59 to do linear motion far away from the limiting groove 6 through the movable rod 570, the second sliding groove 551 and the sliding rod 571, the telescopic rod 59 moves to drive the limiting plate 61 to move to the forefront end of the third sliding groove 600 through the third sliding block 62 and the third sliding groove 600 so that the first through hole 60 is overlapped with the second through hole 610, then the coating powder can fall from the first through hole 60 to the collecting bin 41 through the second through hole 610 to continue single quantitative feeding, in the process, the elastic force generated by elastic deformation recovery of the spring 58 acts on the fixed rod 57 to accelerate the overlapping efficiency of the first through hole 60 and the second through hole 610, so that the quantitative feeding of the device after the device is used for crushing the coating material is more stable, and the quantitative feeding efficiency of the scheme is improved relative to that of adopting the first conveyor belt 1, the second conveyor belt 12 and the crushing device 3.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides an insulating powder coating processing is with ration feed arrangement, includes first conveyer belt (1), control center (2), reducing mechanism (3), fixture (40), collection storehouse (41) and crushing bucket (5), its characterized in that: the bottom of the first conveyor belt (1) is provided with four hydraulic cylinders (10) which are symmetrical to each other, the top output ends of the hydraulic cylinders (10) are differentially connected with hydraulic rods (100), the hydraulic rods (100) are fixedly connected with the bottom of the first conveyor belt (1), the first sliding block (11) is fixedly connected with the outer surfaces of the rightmost front end and the rear end of the first conveyor belt (1), one end of the first conveyor belt (1) close to the first sliding block (11) is provided with a second conveyor belt (12), one end of the second conveyor belt (12) close to the first sliding block (11) is provided with a first sliding groove (120) matched with the first sliding block (11), the first sliding groove (120) is provided with a front end and a rear end surface inside the second conveyor belt (12), the first conveyor belt (1) is fixedly connected with a first baffle plate (121) through the first sliding block (11) and the first sliding groove (120), one end of the second conveyor belt (12) close to the first conveyor belt (1) is fixedly connected with a second baffle plate (12), the first conveyor belt (12) is provided with a first sensor and the first conveyor belt (122) is connected with a first sensor (122) at the bottom of the first conveyor belt (12), the control center (2) and the hydraulic cylinder (10) are electrically connected with the first quality sensor (122), and a crushing device (3) is fixedly connected with one end of the second conveyor belt (12) far away from the first conveyor belt (1);

The top of the collecting bin (41) is provided with a crushing barrel (5), the front end of the crushing barrel (5) is fixedly connected with a second bracket (500), the rear end of the crushing barrel (5) is fixedly connected with a feed chute (50), the bottom of the crushing barrel (5) is provided with a plurality of discharge holes (501), and the aperture of each discharge hole (501) is larger than the diameter of insulating powder;

the front end of the crushing barrel (5) is provided with a driving device (52), the inner top layer of the driving device (52) is fixedly connected with a driving motor (520), the driving motor (520) is electrically connected with a control center (2), the bottom output end of the driving motor (520) is fixedly connected with a second rotating shaft (521), the bottom of the second rotating shaft (521) is fixedly connected with a screw rod (53), the bottom of the screw rod (53) is provided with a push rod (54), one end, close to the screw rod (53), of the push rod (54) is provided with an inner screw hole (540) matched with the screw rod (53), the inner screw hole (540) extends into the push rod (54), the push rod (54) is in threaded connection with the screw rod (53) through the inner screw hole (540), and the bottom of the push rod (54) is fixedly connected with a second sliding block (55);

the movable groove (550) is formed in the middle position of the rear end of the second sliding block (55), the movable groove (550) is arc-shaped, second sliding grooves (551) which are different from the movable groove (550) in the same shape in proportion are formed in the left side and the right side of the inside of the movable groove (550), the sliding rail (56) is fixedly connected to the front end of the inside of the driving device (52), the sliding rail (56) is in sliding connection with the second sliding block (55), the fixed rod (57) is arranged in the inside of the movable groove (550), the limiting plate (572) is arranged at the bottom of the fixed rod (57), the movable rod (570) is fixedly connected to the bottom of the limiting plate (572), sliding rods (571) which are matched with the second sliding grooves (551) are fixedly connected to the left side and the right side of the movable rod (570), the rear end of the limiting plate (572) is fixedly connected with the spring (58), and the fixed rod (57) is sleeved inside the spring (58);

The bottom of the crushing barrel (5) is provided with a limiting trough (6), the bottom of the limiting trough (6) is provided with a plurality of first through holes (60), the front end and the rear end surface inside the limiting trough (6) are provided with third through grooves (600), the top of the limiting trough (6) is provided with a limiting plate (61), a telescopic rod (59) is fixedly connected to the front end surface of the limiting plate (61), the top of the limiting plate (61) is provided with a plurality of second through holes (610) with the same aperture as the first through holes (60), the left side surface and the right side surface of the limiting plate (61) are fixedly connected with third sliding blocks (62), the limiting plate (61) is in sliding connection with the limiting trough (6) through the third sliding blocks (62) and the third through grooves (600), the length of the third sliding grooves (600) is the distance between the two first through holes (60), the top of the crushing device (3) is provided with a feeding hole (30), the inside of the crushing device (3) is connected with two mutually symmetrical shaft rods (31), the rear end of one of the three-phase motor (31) is provided with a plurality of second through holes (610) with the same aperture as the first shaft rods (31), the front end of the first shaft rods (31) is fixedly connected with the second shaft rods (33) is meshed with the first crushing roller (32) and meshed with the first crushing roller (32), the inside right side fixedly connected with of reducing mechanism (3) supports clamp plate (35), and the inside one end inner wall that is close to first crushing roller (32) of reducing mechanism (3) and the one end surface that supports clamp plate (35) and is close to second crushing roller (33) all fixedly connected with crushing tooth (34), discharge gate (36) have been seted up to the slope of reducing mechanism (3) right side bottom, and the inclination of discharge gate (36) is between 45-60.

2. The quantitative feeding device for processing insulating powder coating according to claim 1, wherein: the right side of reducing mechanism (3) is provided with second quality sensor (4), and second quality sensor (4) external control switch, second quality sensor (4) and control switch and control center (2) electric connection, the top fixedly connected with fixture (40) of second quality sensor (4), the top joint of fixture (40) has collection storehouse (41), collects storehouse (41) and sets up in the bottom of discharge gate (36).

3. The quantitative feeding device for processing insulating powder coating according to claim 1, wherein: the top fixedly connected with servo motor (51) of smashing bucket (5), the bottom output fixedly connected with first axis of rotation (510) of servo motor (51), the surface fixedly connected with of first axis of rotation (510) is a plurality of smashing leaf (511) that are circumference distribution, servo motor (51) and control center (2) electric connection.

4. The quantitative feeding device for processing insulating powder coating according to claim 1, wherein: the rear end surface of the driving device (52) is provided with a through groove (5200) matched with the fixed rod (57), one end, away from the limiting plate (572), of the fixed rod (57) is fixedly connected with a telescopic rod (59), the diameter of the telescopic rod (59) is larger than the aperture of the through groove (5200), and one end, close to the fixed rod (57), of the through groove (5200) is fixedly connected with a spring (58).