CN221223938U - Automatic weighing equipment - Google Patents

Abstract

The utility model discloses automatic weighing equipment which comprises a raw material extruding mechanism, a cutting conveying mechanism arranged on one side of the raw material extruding mechanism, a transferring mechanism arranged on one side of the cutting conveying mechanism, a weighing mechanism arranged on one side of the cutting conveying mechanism and a fine feeding mechanism arranged above the weighing mechanism, wherein one end, close to the cutting conveying mechanism, of the raw material extruding mechanism is provided with a discharge hole, a material length sensing component for detecting the length of raw materials extruded from the discharge hole and a cutting component for segmenting the raw materials extruded from the discharge hole are arranged on the cutting conveying mechanism, the transferring mechanism transfers segmented raw materials to the weighing mechanism, and the fine feeding mechanism is provided with a feeding extruding component and a cutting component for cutting the raw materials extruded from the feeding extruding component. The automatic weighing equipment can carry out fine feeding, so that the gram weight of the weighed raw materials meets the requirement of target gram weight; and the raw material weighing efficiency can be improved, and the labor cost is reduced.

Description

Automatic weighing equipment

Technical Field

The utility model relates to the technical field of weighing equipment, in particular to automatic weighing equipment.

Background

In the industries of chemical industry, construction and the like, a plurality of plastic raw materials are required to be weighed, the weighed raw materials are transferred to the next forming process, in the forming process, if the gram weight of the raw materials is insufficient, the formed product has the defects of hollowness, gaps, cracks and the like, and if the gram weight of the raw materials is excessive, the formed product has the defects of burrs, unevenness and the like, and the product is disqualified no matter the gram weight is insufficient or the gram weight is excessive.

The existing plastic raw materials are weighed and configured manually, a certain amount of raw materials are manually taken and placed on a weighing table, and feeding or blanking is carried out according to the actual gram weight, so that the gram weight of the raw materials entering the next forming process meets the process requirements, the serious inefficiency problem exists in manual gram weight balancing, toxic gas exists in chemical and building processing raw materials, and the health of workers can be influenced in long-term work. Therefore, it is desirable to invent an automated weighing apparatus that replaces the existing manual raw material weights.

Disclosure of utility model

In order to solve the problems, the technical scheme provided by the utility model is as follows:

The utility model provides an automatic change weighing device, is in including raw materials extrusion mechanism, setting blank transport mechanism, setting of raw materials extrusion mechanism one side are in the transfer mechanism of blank transport mechanism one side, set up the weighing mechanism of blank transport mechanism one side and set up the meticulous feed supplement mechanism of weighing mechanism top, raw materials extrusion mechanism is close to the one end of blank transport mechanism is equipped with the discharge gate, be equipped with on the blank transport mechanism to the length detection's of the raw materials extruded by the discharge gate material length sensing subassembly and will the raw materials extruded by the discharge gate carry out sectioning cutting off assembly, transfer mechanism shifts sectioning raw materials to weighing mechanism is last, be equipped with on the meticulous feed supplement mechanism and feed supplement extrusion assembly with the cutting assembly that the raw materials extruded by the feed supplement extrusion assembly sheared.

The feeding extrusion assembly comprises a feeding barrel, an extrusion rod movably connected in the feeding barrel and a servo motor for providing extrusion movement travel for the extrusion rod, wherein a feeding bin is arranged in the feeding barrel, the extrusion rod is movably connected in the feeding bin, and a feeding inlet and a feeding outlet are respectively formed in the upper end and the lower end of the feeding bin.

The utility model further provides that the cutting assembly comprises a cutting tool bit, a first power source for driving the cutting tool bit to perform cutting action and a second power source for driving the cutting tool bit to lift, and the cutting tool bit is positioned between the material supplementing outlet and the weighing mechanism.

The utility model is further characterized in that a travel plate is arranged above the feeding cylinder, a guide sliding rail and a screw rod are arranged on the travel plate, the servo motor is directly connected with the screw rod in a transmission way or through a transmission belt, a nut seat is arranged on the screw rod, a travel seat is connected to the extrusion rod, the travel seat is fixedly connected with the nut seat, the travel seat is movably connected to the guide sliding rail, and an extrusion part which is matched with the inner diameter of the feeding cylinder is arranged at one end of the extrusion rod, which is close to the feeding cylinder.

The utility model further provides that the blanking conveying mechanism comprises a conveying belt and a third power source for driving the conveying belt to drive, the conveying head end of the conveying belt is arranged close to the discharge hole, the cutting assembly and the material length sensing assembly are sequentially arranged along the driving direction of the conveying belt, and the distance between the cutting assembly and the material length sensing assembly is the sectional length of the raw material.

The utility model further provides that the cutting assembly comprises a vertical frame arranged on the conveyor belt, a cutter movably connected to the vertical frame through a sliding rod, a transverse plate connected to one end of the sliding rod, a fourth power source and a speed reducer, wherein the fourth power source is connected with the speed reducer, the speed reducer is connected with a rotary table, a screw rod is connected between the rotary table and the transverse plate, one end of the screw rod is connected with the end part of the transverse plate, and the other end of the screw rod is connected with a non-axle center position of the rotary table.

The utility model is further arranged in that the conveyor belt is also provided with an in-place sensing assembly, the in-place sensing assembly is positioned at one side of the material length sensing assembly, which is far away from the cutting assembly, and the transfer mechanism comprises a transfer side plate, a fifth power source movably connected to the transfer side plate, a sixth power source connected to the fifth power source, a seventh power source connected to the sixth power source and a clamping plate connected to the seventh power source, wherein the clamping plate is used for transferring raw materials on the conveyor belt to the weighing mechanism.

The utility model further provides that the weighing mechanism comprises a weighing tray, a pressure sensing assembly positioned on the weighing tray and an eighth power source for driving the weighing tray to transversely move.

The utility model further provides that the raw material extruding mechanism comprises an extruding cylinder, a feed hopper, a toothed chain rotating shaft and a ninth power source, wherein the feed hopper, the toothed chain rotating shaft and the ninth power source are connected to the extruding cylinder, the discharge port is located at one end of the extruding cylinder, a stirring screw is connected to the extruding cylinder, a transmission main shaft is connected to the stirring screw, an extruding roller is arranged in the feed hopper, a gear shaft is connected to the extruding roller, the ninth power source is connected with the transmission main shaft through a chain wheel transmission assembly, the transmission main shaft is connected with the toothed chain rotating shaft through a chain wheel transmission assembly, and the toothed chain rotating shaft is connected with the gear shaft through a gear set.

The utility model is further arranged to further comprise a controller which is electrically connected with the input and output electric appliances in the extrusion mechanism, the blanking conveying mechanism, the transferring mechanism, the weighing mechanism and the fine feeding mechanism respectively.

Compared with the prior art, the technical scheme provided by the utility model has the following beneficial effects:

According to the technical scheme, in order to weigh the accurate plastic raw materials, the automatic weighing equipment preliminarily cuts off the raw materials extruded by the raw material extrusion mechanism through the material length sensing assembly and the cutting assembly, and controls the gram weight of the cut raw materials to be insufficient but close to the target gram weight; and transferring the cut raw materials to a weighing mechanism, peeling the weighing mechanism before transferring, avoiding continuous feeding and amplifying errors, feeding the segment raw materials on the weighing mechanism by a feeding extrusion assembly and a cutting assembly until the segment raw materials on the weighing mechanism reach the target gram weight, and completing automatic weighing.

According to the utility model, the automatic weighing equipment can perform fine feeding, so that the gram weight of the weighed raw material meets the gram weight requirement of the next forming processing procedure, and the production quality of the product of the next procedure is improved; and the raw material weighing efficiency can be greatly improved, the labor cost is reduced, and toxic gas inhalation by workers can be avoided.

Drawings

FIG. 1 is a perspective view of an automated weighing apparatus in accordance with an embodiment of the present utility model.

Fig. 2 is a perspective view of a blanking conveying mechanism, a transferring mechanism and a weighing mechanism according to an embodiment of the present utility model.

FIG. 3 is a perspective view of a fine feed mechanism according to an embodiment of the present utility model.

Fig. 4 is a perspective view of a cutting assembly according to an embodiment of the present utility model.

FIG. 5 is a perspective view of a material extrusion mechanism according to an embodiment of the present utility model.

FIG. 6 is a cross-sectional view of a feedstock extrusion mechanism according to an embodiment of the present utility model.

FIG. 7 is an electrical control block diagram of an automated weighing apparatus according to an embodiment of the utility model.

Detailed Description

For a further understanding of the present utility model, the present utility model will be described in detail with reference to the drawings and examples.

It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, integrally connected, or detachably connected; can be mechanical connection or electric connection, or can be communication between two elements; may be directly connected or indirectly connected through an intermediate medium, and the specific meaning of the above terms will be understood by those skilled in the art according to the specific circumstances.

Referring to fig. 1 to 7, the technical scheme of the utility model is an automatic weighing device, which comprises a raw material extruding mechanism 2, a cutting conveying mechanism 3 arranged on one side of the raw material extruding mechanism 2, a transferring mechanism 4 arranged on one side of the cutting conveying mechanism 3, a weighing mechanism 5 arranged on one side of the cutting conveying mechanism 3 and a fine feeding mechanism 6 arranged above the weighing mechanism 5, wherein one end of the raw material extruding mechanism 2, which is close to the cutting conveying mechanism 3, is provided with a discharging hole 211, the cutting conveying mechanism 3 is provided with a material length sensing component 33 for detecting the length of raw material extruded from the discharging hole 211 and a cutting component 34 for segmenting the raw material extruded from the discharging hole 211, the transferring mechanism 4 transfers the segmented raw material to the weighing mechanism 5, and the fine feeding mechanism 6 is provided with a feeding extruding component 61 and a cutting component 62 for cutting the raw material extruded from the feeding extruding component 61.

In this embodiment, the automatic weighing apparatus of this embodiment weighs a material that deforms when pressed at normal temperature and pressure, for example, clay, paste, or the like, and specifically may be a bakelite soft material that deforms when pressed at normal temperature and pressure, and has a pungent smell.

In the above embodiment, the raw material extrusion mechanism 2 is used for extruding a plastic raw material into a long strip shape; the blanking conveying mechanism 3 is used for synchronously conveying the strip-shaped plastic raw materials and cutting the strip-shaped plastic raw materials; the transfer mechanism 4 is used for transferring the segment-shaped plastic raw materials to the weighing mechanism 5; the weighing mechanism 5 is used for weighing the segment-shaped plastic raw materials; the fine feeding mechanism 6 is used for fine feeding of segment-shaped plastic raw materials with insufficient gram weights.

In the above embodiment, in order to obtain accurate plastic raw materials by weighing, the automatic weighing device of the embodiment performs preliminary cutting on the raw materials extruded by the raw material extrusion mechanism 2 through the material length sensing assembly 33 and the cutting assembly 34, and controls the cut raw materials to have insufficient gram weight but to be close to the target gram weight; and transferring the cut raw materials to the weighing mechanism 5, peeling the weighing mechanism 5 before transferring, avoiding continuous feeding and amplifying errors, feeding the segmented raw materials on the weighing mechanism 6 by the feeding extrusion assembly 61 and the cutting assembly 62 until the segmented raw materials on the weighing mechanism 5 reach the target gram weight, and completing automatic weighing.

In this embodiment, the feeding extrusion assembly 61 includes a feeding barrel 611, an extrusion rod 612 movably connected in the feeding barrel 611, and a servo motor 613 for providing an extrusion travel for the extrusion rod 612, a feeding bin is disposed in the feeding barrel 611, the extrusion rod 612 is movably connected in the feeding bin, and a feeding inlet 6111 and a feeding outlet 6112 are respectively disposed at the upper end and the lower end of the feeding bin.

In the above embodiment, the feeding inlet 6111 is used for feeding raw materials, and the extruding rod 612 extrudes raw materials in the feeding bin, so that the feeding outlet 6112 extrudes raw materials requiring feeding.

In this embodiment, the cutting assembly 62 includes a cutting blade 621, a first power source 622 driving the cutting blade 621 to perform a cutting operation, and a second power source 623 driving the cutting blade 621 to lift, where the cutting blade 621 is located between the feeding outlet 6112 and the weighing mechanism 5; the first power source 622 and the second power source 623 are unidirectional cylinders.

In the above embodiment, the plastic raw material has viscosity, so that the extruded raw material from the feeding outlet 6112 needs to be cut, the cutting blade 621 is driven by the first power source 622 to perform the cutting operation, the structure of the cutting blade 621 is not limited, the raw material from the extruded feeding outlet 6112 may be cut, the cutting blade 621 is lowered by the second power source 623, and the cut raw material from the cutting blade 621 is adhered to the segment-shaped raw material of the weighing mechanism 5.

In this embodiment, a travel plate 614 is disposed above the feeding barrel 611, a guide slide rail 615 and a screw rod 616 are disposed on the travel plate 614, the servo motor 613 is directly or through a transmission belt in transmission connection with the screw rod 616, a nut seat 617 is disposed on the screw rod 616, a travel seat 618 is connected to the extrusion rod 612, the travel seat 618 is fixedly connected with the nut seat 617, the travel seat 618 is movably connected to the guide slide rail 615, and an extrusion portion 6121 adapted to the inner diameter of the feeding barrel 611 is disposed at one end of the extrusion rod 612 close to the feeding barrel 611.

In the above embodiment, knowing the volume of the extruded feed supplement and the density of the plastic raw material for one turn of rotation of the servo motor 613, the gram weight of the extruded feed supplement for one turn of rotation of the servo motor 613 can be known, and the servo motor 613 is driven to rotate for a corresponding turn according to the difference between the gram weight of the segment-shaped raw material transferred to the weighing mechanism 5 and the target gram weight, so that accurate feed supplement is realized.

In this embodiment, the blanking conveying mechanism 3 includes a conveying belt 31 and a third power source 32 for driving the conveying belt 31, a stepping motor or a servo motor for the third power source 32, a conveying head end of the conveying belt 31 is disposed near the discharge hole 211, the cutting assembly 34 and the material length sensing assembly 33 are sequentially disposed along a driving direction of the conveying belt 31, and a distance between the cutting assembly 34 and the material length sensing assembly 33 is a sectional length of a raw material.

In the above embodiment, knowing the cross-sectional area of the outlet 211 and the density of the plastic feedstock, the distance between the cutting assembly 34 and the feedstock length sensing assembly 33 can be set such that the cut feedstock is insufficient in gram weight but close to the target gram weight, reducing consumption of subsequent feedstock materials, thereby improving the feedstock efficiency.

In this embodiment, the cutting assembly 34 includes a vertical frame 341 disposed on the conveyor belt 31, a cutter 343 movably connected to the vertical frame 341 through a sliding rod 342, a transverse plate 344 connected to one end of the sliding rod 342, a fourth power source 345 and a speed reducer 346, the fourth power source 345 is connected to the speed reducer 346, a turntable 347 is connected to the speed reducer 346, a screw 348 is connected between the turntable 347 and the transverse plate 344, one end of the screw 348 is connected to an end of the transverse plate 344, and the other end of the screw 348 is connected to a non-axial center of the turntable 347.

In this embodiment, the conveyor belt 31 is further provided with an in-place sensor assembly 35, the in-place sensor assembly 35 is located on a side of the material length sensor assembly 33 away from the cutting assembly 34, the transferring mechanism 4 includes a transferring side plate 41, a fifth power source 42 movably connected to the transferring side plate 41, a sixth power source 43 connected to the fifth power source 42, a seventh power source 44 connected to the sixth power source 43, and a clamping plate 45 connected to the seventh power source 44, and the clamping plate 45 is used for transferring the segment-shaped raw material on the conveyor belt 31 to the weighing mechanism 5.

In the above embodiment, the fifth power source 42 is a slipway cylinder, and the sixth power source 43 and the seventh power source 44 are single-phase cylinders.

In this embodiment, the weighing mechanism 5 includes a weighing tray 51, a pressure sensing component 52 located on the weighing tray 51, and an eighth power source 53 for driving the weighing tray 51 to traverse; the eighth power source 53 is a single-phase cylinder.

In this embodiment, the raw material extruding mechanism 2 includes an extruding cylinder 21, a feed hopper 22 connected to the extruding cylinder 21, a toothed chain rotating shaft 23 and a ninth power source 24, the discharge port 211 is located at one end of the extruding cylinder 21, a stirring screw 25 is connected in the extruding cylinder 21, a transmission main shaft 251 is connected to the stirring screw 25, an extruding roller 26 is disposed in the feed hopper 22, a gear shaft 261 is connected to the extruding roller 26, the ninth power source 24 is connected to the transmission main shaft 251 through a sprocket transmission assembly, the transmission main shaft 251 is connected to the toothed chain rotating shaft 23 through a sprocket transmission assembly, and the toothed chain rotating shaft 23 is connected to the gear shaft 261 through a gear set.

In the above embodiment, the ninth power source 24 can realize synchronous rotation of the stirring screw 25 and the extrusion roller 26, so as to reduce the power source; the ninth power source 24 may be a gear motor.

In this embodiment, the device further comprises a controller 1, wherein the controller 1 is electrically connected with input and output electrical appliances in the extrusion mechanism 2, the blanking conveying mechanism 3, the transfer mechanism 4, the weighing mechanism 5 and the fine feeding mechanism 6 respectively; specifically, the controller 1 may be a Programmable Logic Controller (PLC) or a microprocessor (single-chip microcomputer); the output end of the controller 1 is connected with the input end of the first power source 622 and the input end of the second power source 621 respectively; the signal output end of the material length sensing assembly 33 is connected with the input end of the controller 1, and the output end of the controller 1 is connected with the input end of the third power source 32; the output end of the controller 1 is connected with the input end of the fourth power source 345; the signal output end of the in-place sensing assembly 35 is connected with the input end of the controller 1, and the output end of the controller 1 is respectively connected with the input end of the fifth power source 42, the input end of the sixth power source 43 and the input end of the seventh power source 44; the output end of the controller 1 is connected with the input end of the eighth power source 53; the output end of the controller 1 is connected with the input end of the ninth power source 24; the signal output end of the pressure sensing component 52 is connected with the input end of the controller 1; the output end of the controller 1 is connected with the input end of the servo motor 613.

In this embodiment, the controller further includes an operation switch, an output end of which is connected to an input end of the controller 1, and the operation switch includes a start switch, an emergency stop switch, and the like.

According to the technical scheme, the automatic weighing equipment can carry out fine feeding, so that the gram weight of the weighed raw materials meets the gram weight requirement of the next forming processing procedure, and the production quality of the product of the next procedure is improved; and the raw material weighing efficiency can be greatly improved, the labor cost is reduced, and toxic gas inhalation by workers can be avoided.

The utility model and its embodiments have been described above by way of illustration and not limitation, and the utility model is illustrated in the accompanying drawings and described in the drawings in which the actual structure is not limited thereto. Therefore, if one of ordinary skill in the art is informed by this disclosure, the structural mode and the embodiments similar to the technical scheme are not creatively designed without departing from the gist of the present utility model.

Claims (10)

1. The utility model provides an automatic change weighing device, its characterized in that, is in including raw materials extrusion mechanism, setting blank transport mechanism of raw materials extrusion mechanism one side, setting are in transfer mechanism of blank transport mechanism one side, setting are in weighing mechanism of blank transport mechanism one side and setting are in the meticulous feed supplement mechanism of weighing mechanism top, raw materials extrusion mechanism is close to the one end of blank transport mechanism is equipped with the discharge gate, be equipped with on the blank transport mechanism to the raw materials that the discharge gate extruded carries out the long sensing assembly of material that length detected and will the raw materials that the discharge gate extruded carry out sectioning cutting assembly, transfer mechanism shifts sectioning raw materials to weighing mechanism is last, be equipped with on the meticulous feed supplement mechanism and mend the cutting assembly that the raw materials that the assembly extruded was sheared.

2. The automatic weighing equipment according to claim 1, wherein the feeding extrusion assembly comprises a feeding barrel, an extrusion rod movably connected in the feeding barrel and a servo motor for providing an extrusion movement stroke for the extrusion rod, a feeding bin is arranged in the feeding barrel, the extrusion rod is movably connected in the feeding bin, and a feeding inlet and a feeding outlet are respectively formed in the upper end and the lower end of the feeding bin.

3. The automated weighing apparatus of claim 2, wherein the cutting assembly comprises a cutting head, a first power source for driving the cutting head to perform a cutting action, and a second power source for driving the cutting head to lift, the cutting head being positioned between the feed supplement outlet and the weighing mechanism.

4. The automatic weighing equipment according to claim 2, wherein a travel plate is arranged above the feeding cylinder, a guide sliding rail and a screw rod are arranged on the travel plate, the servo motor is directly or through a transmission belt in transmission connection with the screw rod, a nut seat is arranged on the screw rod, a travel seat is connected to the extrusion rod, the travel seat is fixedly connected with the nut seat, the travel seat is movably connected to the guide sliding rail, and an extrusion part which is matched with the inner diameter of the feeding cylinder is arranged at one end of the extrusion rod, which is close to the feeding cylinder.

5. An automated weighing apparatus according to claim 1, wherein the blanking conveying mechanism comprises a conveyor belt and a third power source for driving the conveyor belt to drive, a conveying head end of the conveyor belt is arranged close to the discharge port, the cutting assembly and the material length sensing assembly are sequentially arranged along a driving direction of the conveyor belt, and a distance between the cutting assembly and the material length sensing assembly is a sectional length of the raw material.

6. The automatic weighing equipment according to claim 5, wherein the cutting assembly comprises a vertical frame arranged on the conveyor belt, a cutter movably connected to the vertical frame through a sliding rod, a transverse plate connected to one end of the sliding rod, a fourth power source and a speed reducer, the fourth power source is connected with the speed reducer, a rotary table is connected to the speed reducer, a screw is connected between the rotary table and the transverse plate, one end of the screw is connected to the end of the transverse plate, and the other end of the screw is connected to a non-axial position of the rotary table.

7. The automated weighing apparatus of claim 5, wherein the conveyor belt is further provided with an in-place sensor assembly, the in-place sensor assembly is located on a side of the material length sensor assembly away from the cutoff assembly, the transfer mechanism comprises a transfer side plate, a fifth power source movably connected to the transfer side plate, a sixth power source connected to the fifth power source, a seventh power source connected to the sixth power source, and a clamping plate connected to the seventh power source, and the clamping plate is used for transferring raw materials on the conveyor belt to the weighing mechanism.

8. An automated weighing apparatus according to any one of claims 1 to 7, wherein said weighing mechanism comprises a weighing tray, a pressure sensing assembly located on said weighing tray, and an eighth power source for driving said weighing tray to traverse.

9. The automated weighing apparatus of any one of claims 1 to 7, wherein the raw material extrusion mechanism comprises an extrusion barrel, a feed hopper connected to the extrusion barrel, a toothed chain rotating shaft and a ninth power source, the discharge port is positioned at one end of the extrusion barrel, a stirring screw is connected to the extrusion barrel, a transmission main shaft is connected to the stirring screw, an extrusion roller is arranged in the feed hopper, a gear shaft is connected to the extrusion roller, the ninth power source is connected to the transmission main shaft through a sprocket transmission assembly, the transmission main shaft is connected to the toothed chain rotating shaft through a sprocket transmission assembly, and the toothed chain rotating shaft is connected to the gear shaft through a gear set.

10. An automated weighing apparatus according to any one of claims 1 to 7, further comprising a controller electrically connected to input and output electrical appliances in said extrusion mechanism, said blanking transfer mechanism, said weighing mechanism and said fine feed mechanism, respectively.