CN113304687A - Particle forming device for veterinary drug production and using method thereof - Google Patents

Abstract

The invention discloses a particle forming device for veterinary drug production and a using method thereof. According to the invention, because the opposite surfaces of the two third mounting plates are abutted together, the two third mounting plates can be in an autonomous locking state, so that the operation is simple, all movable half dies can be matched on the fixed half dies simultaneously through the second driving assembly, all clamping blocks can be clamped on the outer sides of the fixed half dies and the movable half dies simultaneously through the clamping assembly, the movable half dies are prevented from being separated from the fixed half dies when materials are extruded, the equipment is simple, the processing precision is improved, and the production efficiency is improved.

Description

Particle forming device for veterinary drug production and using method thereof

Technical Field

The invention relates to the technical field of drug granulation devices, in particular to a particle forming device for veterinary drug production and a using method thereof.

Background

The veterinary drug means a substance (drug-containing feed additive) for preventing, treating, diagnosing animal diseases or purposefully regulating animal physiological functions, and mainly comprises: serum products, vaccines, diagnostic products, microecological products, traditional Chinese medicinal materials, Chinese patent medicines, chemicals, antibiotics, biochemical medicines, radiopharmaceuticals, topical insecticides, disinfectants, etc. Theoretically, the chemical substances affecting the physiological functions of organs or metabolic activities of cells belong to the category of drugs. In China, fish drugs, bee drugs and silkworm drugs are also managed by veterinary drugs. The new veterinary drug refers to a veterinary drug raw material drug newly developed in China and a preparation thereof. The new veterinary medicine preparation is prepared with animal medicine material and through new research and processing. The approved and produced veterinary drug preparation also belongs to a novel veterinary drug preparation when the prescription, the dosage form and the administration route are changed and new indications are added.

Present animal remedy granule forming device structure is complicated, and the operation is inconvenient, and need put into the drying cabinet collective stoving with the medicine after the extrusion is stereotyped, wastes time and energy, and some simple and easy animal remedy granule forming device, and the machining precision is not high, and animal remedy shaping effect is poor.

Disclosure of Invention

The present invention aims to solve the above problems and provide a pellet forming apparatus for veterinary drug production and a method for using the same.

The invention realizes the purpose through the following technical scheme:

the utility model provides a granule forming device for animal remedy production, includes the guipure conveyor, guipure conveyor top one side is provided with the ejection of compact machine, the ejection of compact machine bottom is provided with forming mechanism, guipure conveyor top opposite side is provided with drying mechanism, forming mechanism includes fixed half module, third mounting panel, fixed plate, first drive assembly, activity half module, second drive assembly, joint subassembly, fixed pin, fixed half module is provided with two rows, and two rows the breach that the radian is 180 degrees is seted up at the fixed half module looks back, and this breach inboard is provided with the activity half module that matches with it, one side that the activity half module kept away from fixed half module is provided with the second drive assembly that the activity half module moved that drives simultaneously all, fixed half module with the activity half module outside still is provided with the joint subassembly, the two rows of fixed half modules are respectively arranged on the tops of the two third mounting plates and are positioned at opposite ends of the two third mounting plates, the third mounting plates are of T-shaped structures, the front side and the rear side of the lower ends of the third mounting plates are fixedly connected with the fixed pins, one ends of the fixed pins, far away from the third mounting plates, are connected into the fixed plates through bearings, the fixed plates are arranged on one sides of the tops of the mesh belt type conveyors, the inner sides of the fixed plates are provided with the first driving assemblies which simultaneously drive the two fixed pins to rotate reversely, when the two third mounting plates are horizontal, opposite surfaces of the two third mounting plates are abutted together, so that when the feeding extrusion assembly is used for tabletting materials, the opposite surfaces of the two third mounting plates are abutted together, the two third mounting plates are in an autonomous locking state, and the operation is simple, can make all activity half moulds cooperate on fixed half mould simultaneously through second drive assembly, can make all fixture blocks joint simultaneously in fixed half mould and activity half mould outside through the joint subassembly, the half mould that moves about breaks away from fixed half mould when preventing to extrude the material for equipment becomes simply and has improved the machining precision, and has improved production efficiency.

Preferably, the second driving assembly comprises a first mounting frame, a bidirectional air cylinder, a first connecting plate and a first connecting block, the first mounting frame is connected with the rear part of the mesh belt type conveyor through a bolt, the top part of the first mounting frame is connected with the bidirectional cylinder through a bolt, two output ends of the bidirectional cylinder are connected with the first connecting plate through bolts, the opposite surfaces of the two first connecting plates are connected with a plurality of first connecting blocks corresponding to the fixed half moulds through bolts, one end of the first connecting block, which is far away from the first connecting plate, is connected with the movable half mold through a bolt, in this way, two first connecting plates can be driven to move by the bidirectional cylinder, the first connecting plates drive the first connecting blocks to move, the first connecting blocks drive the movable half-moulds to move, moving the movable mold half away from the stationary mold half and mating the movable mold half with the stationary mold half.

Preferably, the joint subassembly includes second mounting bracket, fourth cylinder, second connecting plate, second connecting block, fixture block, the second mounting bracket passes through bolted connection and is in guipure belt conveyor the place ahead, second mounting bracket top sets up through bolted connection around the fourth cylinder, there is bolted connection at the output rear of fourth cylinder the second connecting plate, a plurality of has all been welded in second connecting plate both sides the second connecting block, there is bolted connection at second connecting block rear the fixture block, so set up and can drive the second connecting plate through the fourth cylinder and remove, the connecting rod drives the second connecting block and remove, and the second connecting block drives the fixture block and removes for the fixture block joint is in the stationary half outside and movable half outside to and make the fixture block remove the restriction to stationary half and movable half.

Preferably, the fixture block is provided with four clamping jaws which are respectively clamped at the upper end and the lower end of the outer sides of the fixed half mold and the movable half mold, so that the movable half mold and the fixed half mold are more stably matched.

Preferably, first drive assembly includes the third cylinder, rotates seat, connecting rod, the third cylinder passes through bolted connection and is in the fixed plate is inboard, there is bolted connection at the third cylinder top the seat rotates, it has two to rotate the seat inboard through the round pin hub connection connecting rod, two the connecting rod is kept away from rotate the seat one end respectively with two the third mounting panel passes through the round pin hub connection, sets up like this and to drive through the third cylinder and rotate the seat and rise, rotates the seat and rises to drive the connecting rod and rotate, and the rotation of connecting rod drives the third mounting panel and rotates for the slice material after the extrusion comes out from the fixed half mould, and falls on the guipure conveyor through the water conservancy diversion of third mounting panel.

Preferably, first drive assembly includes motor, first chain group, second chain group, the motor passes through bolted connection and is in the fixed plate is inboard, there is first chain group the output of motor through the coupling joint, the output of motor still is connected with through gear engagement the second chain group, first chain group with the second chain group respectively with two fixed pin transmission is connected, sets up like this and can drive first chain group and second chain group antiport through the motor, and then makes two fixed pin antiport, finally makes two third mounting panels antiport, and the third mounting panel is in the state of slope this moment for the slice material after being extruded comes out from the stationary half mould, and falls on the guipure formula conveyer through the water conservancy diversion of third mounting panel.

Preferably, the discharging machine comprises a feeding machine body and a feeding extrusion assembly, the feeding extrusion assembly is arranged at the bottom of the feeding machine body and comprises a transverse slide rail pair, an I-shaped plate, a first cylinder, a first mounting plate, a discharging nozzle, a second cylinder, a second mounting plate and an extrusion rod, the I-shaped plate is connected with the feeding machine body through the transverse slide rail pair, one end of the bottom of the I-shaped plate is connected with the first cylinder through a bolt, the first mounting plate is connected with the lower part of the output end of the first cylinder through a bolt, a plurality of discharging nozzles are fixedly mounted at the bottom of the first mounting plate, the discharging nozzle is communicated with the feeding machine body, the other end of the bottom of the I-shaped plate is connected with the second cylinder through a bolt, the lower part of the output end of the second cylinder is connected with the second mounting plate through a bolt, the bottom of the second mounting plate is fixedly provided with a plurality of the extrusion rods, so that the I-shaped plate can be moved through the transverse sliding rail pair, until the discharge nozzle is positioned right above the fixed half die, then the first cylinder is started, the first cylinder drives the first mounting plate to descend, the first mounting plate drives the discharge nozzle to descend, the discharge nozzle is aligned to the fixed half die, then the material quantitatively enters the fixed half die and the movable half die through the discharge nozzle through the feeder body, the I-shaped plate can be moved through the transverse sliding rail pair until the extrusion rods are positioned right above the fixed half die, then the second cylinder is started, the second cylinder drives the second mounting plate to descend, the second mounting plate drives the extrusion rods to descend, so that the extrusion rods enter the fixed half die and the movable half die to extrude the material, and the material is extruded into a sheet.

Preferably, the first mounting plate and the second mounting plate are U-shaped structures, and the two U-shaped structures are alternately arranged, so that the feeding extrusion assembly is compact in structure, and the length of the transverse sliding rail pair can be reduced.

Preferably, the drying mechanism comprises a fixing frame, a fan, a heating box and a reflecting plate, the fixing frame is connected to the other side of the top of the mesh belt type conveyor through bolts, a plurality of mounting holes are further formed in the top of the fixing frame, the fan is installed in the mounting holes, the heating box is arranged on the top of the inner side of the fixing frame, the heating box is hollow and is provided with an opening at the top, vent holes distributed in an array mode are formed in a bottom plate of the heating box, heating elements are arranged in the heating box, the reflecting plate is installed in the mesh belt type conveyor and is located on the inner side of a conveying mesh belt in the mesh belt type conveyor, an arc-shaped groove is formed in the upper surface of the reflecting plate, the heating elements in the heating box can generate heat through the fan, and air flow generated by the fan is blown to the top of the flaky materials after being heated by the heating elements, part of the air flow is blown to the reflecting plate through the mesh belt type conveyor and then reflected by the reflecting plate, so that the part of the air flow is blown to the bottom of the flaky material, and the flaky material is dried and shaped.

The invention also provides a use method of the particle forming device for veterinary drug production, which comprises the following steps:

the method comprises the following steps: enabling the I-shaped plate to move through the transverse sliding rail pair until the discharging nozzle is positioned right above the fixed half die, then starting the first air cylinder, enabling the first air cylinder to drive the first mounting plate to descend, enabling the first mounting plate to drive the discharging nozzle to descend, enabling the discharging nozzle to be aligned to the fixed half die, enabling materials to quantitatively enter the fixed half die and the movable half die through the discharging nozzle through the feeder body, and then enabling the first air cylinder to reset;

step two: enabling the I-shaped plate to move through the transverse sliding rail pair until the extrusion rod is positioned right above the fixed half die, then starting a second air cylinder, driving a second mounting plate to descend through the second air cylinder, driving the extrusion rod to descend through the second mounting plate, enabling the extrusion rod to enter the fixed half die and the movable half die to extrude materials, enabling the materials to be extruded into sheets, and then resetting the second air cylinder;

step three: starting a fourth cylinder, driving a second connecting plate to move forwards by the fourth cylinder, driving a second connecting block to move forwards by a connecting rod, and driving a clamping block to move forwards by the second connecting block until the clamping block is separated from the fixed half mould and the movable half mould;

step four: starting a bidirectional cylinder, wherein the bidirectional cylinder drives two first connecting plates to move, the first connecting plates drive a first connecting block to move, and the first connecting block drives a movable half die to move so that the movable half die is far away from a fixed half die;

step five: starting a third air cylinder, wherein the third air cylinder drives a rotating seat to ascend, the rotating seat ascends to drive a connecting rod to rotate, the connecting rod rotates to drive a third mounting plate to rotate, and at the moment, the extruded sheet material comes out of the fixed half-mold and falls on the mesh belt conveyor through the diversion of the third mounting plate;

step six: the sheet materials falling on the mesh belt type conveyor are conveyed to the inside of the drying mechanism by the mesh belt type conveyor, and the third mounting plate, the second driving assembly and the clamping assembly are sequentially reset and the actions are repeated in the process, so that the function of continuous production is realized;

step seven: the fan is started and heating elements inside the heating box generate heat, air flow generated by the fan blows to the top of the flaky material after being heated by the heating elements, partial air flow blows to the reflecting plate through the mesh belt type conveyor and then is reflected by the reflecting plate, so that the partial air flow blows to the bottom of the flaky material, and the flaky material is dried and shaped.

Has the advantages that:

1. when the feeding extrusion assembly is used for tabletting materials, the opposite surfaces of the two third mounting plates are abutted together, so that the two third mounting plates are in an autonomous locking state, and the operation is simple;

2. can make all activity half moulds cooperate on fixed half mould simultaneously through second drive assembly, can make all fixture blocks joint simultaneously in fixed half mould and activity half mould outside through the joint subassembly, the half mould that moves about breaks away from fixed half mould when preventing to extrude the material for equipment becomes simply and has improved the machining precision, and has improved production efficiency.

Additional features of the invention and advantages thereof will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic structural diagram of a particle forming device for veterinary drug production according to the present invention;

fig. 2 is a schematic structural view of a feeding extrusion assembly of a particle forming device for veterinary drug production according to the present invention;

fig. 3 is a schematic structural diagram of a forming mechanism of a particle forming device for veterinary drug production according to the invention;

fig. 4 is a schematic structural diagram of a forming mechanism of a particle forming device for veterinary drug production in another state;

fig. 5 is a schematic structural view of a first embodiment of a first driving assembly of the particle forming apparatus for veterinary drug manufacture according to the present invention;

fig. 6 is a schematic structural view of a second driving assembly of the particle forming device for veterinary drug production according to the present invention;

fig. 7 is a schematic structural view of a clamping assembly of the particle forming device for veterinary drug production according to the present invention;

fig. 8 is an exploded view of a drying mechanism of a particle forming device for veterinary drug production according to the present invention;

fig. 9 is a schematic structural diagram of a second embodiment of the first driving assembly of the particle forming device for veterinary drug production according to the present invention.

The reference numerals are explained below:

1. a mesh belt conveyor; 2. a discharging machine; 3. a molding mechanism; 4. a drying mechanism; 201. a feeder body; 202. a feed extrusion assembly; 2021. a transverse sliding rail pair; 2022. i-shaped plates; 2023. a first cylinder; 2024. a first mounting plate; 2025. a discharge nozzle; 2026. a second cylinder; 2027. a second mounting plate; 2028. an extrusion stem; 31. a stationary half-mold; 32. a third mounting plate; 33. a fixing plate; 34. a first drive assembly; 35. a movable half-mold; 36. a second drive assembly; 37. a clamping assembly; 38. a fixing pin; 341. a third cylinder; 342. a rotating seat; 343. a connecting rod; 3401. a motor; 3402. a first chain set; 3403. a second chain set; 361. a first mounting bracket; 362. a bidirectional cylinder; 363. a first connecting plate; 364. a first connection block; 371. a second mounting bracket; 372. a fourth cylinder; 373. a second connecting plate; 374. a second connecting block; 375. a clamping block; 401. a fixed mount; 402. a fan; 403. a heating box; 404. a reflective plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1

As shown in fig. 1-8, a particle forming device for veterinary drug production comprises a mesh belt conveyor 1, a discharging machine 2 is disposed on one side of the top of the mesh belt conveyor 1, a forming mechanism 3 is disposed at the bottom of the discharging machine 2, a drying mechanism 4 is disposed on the other side of the top of the mesh belt conveyor 1, the forming mechanism 3 includes a fixed half mold 31, a third mounting plate 32, a fixing plate 33, a first driving assembly 34, a movable half mold 35, a second driving assembly 36, a clamping assembly 37, and a fixing pin 38, two rows of fixed half molds 31 are disposed, a notch with an arc of 180 degrees is disposed on the opposite side of each of the two rows of fixed half molds 31, a movable half mold 35 matched with the notch is disposed on the inner side of the movable half mold 35, a second driving assembly 36 is disposed on the side of the movable half mold 35 away from the fixed half mold 31, the second driving assembly 36 is disposed on the outer sides of the fixed half mold 31 and the movable half mold 35, the two rows of fixed half moulds 31 are respectively arranged on the tops of the two third mounting plates 32 and are positioned at opposite ends of the two third mounting plates 32, the third mounting plates 32 are of a T-shaped structure, the front side and the rear side of the lower end of each third mounting plate are fixedly connected with fixing pins 38, one ends of the fixing pins 38 far away from the third mounting plates 32 are connected inside the fixing plates 33 through bearings, the fixing plates 33 are arranged on one side of the top of the mesh belt conveyor 1, first driving assemblies 34 which simultaneously drive the two fixing pins 38 to rotate reversely are arranged on the inner sides of the fixing plates 33, when the two third mounting plates 32 are horizontal, opposite surfaces of the two third mounting plates 32 are abutted together, so that when the feeding extrusion assembly 202 is used for carrying out tabletting treatment on materials, because the opposite surfaces of the two third mounting plates 32 are abutted together, the two third mounting plates 32 are in an autonomous locking state, the operation is simple, and all the movable half moulds 35 can be simultaneously matched on the fixed half moulds 31 through the second driving assemblies 36, all the clamping blocks 375 can be clamped on the outer sides of the fixed half mold 31 and the movable half mold 35 through the clamping assembly 37, the movable half mold 35 is prevented from separating from the fixed half mold 31 when materials are extruded, so that the equipment becomes simple, the processing precision is improved, and the production efficiency is improved, the second driving assembly 36 comprises a first mounting frame 361, a two-way cylinder 362, a first connecting plate 363 and a first connecting block 364, the first mounting frame 361 is connected to the rear of the mesh belt type conveyor 1 through bolts, the top of the first mounting frame 361 is connected with the two-way cylinder 362 through bolts, two output ends of the two-way cylinder 362 are connected with the first connecting plate 363 through bolts, a plurality of first connecting blocks 364 corresponding to the fixed half mold 31 are connected to opposite surfaces of the two first connecting plates 363 through bolts, one end of the first connecting block 364 far away from the first connecting plate 363 is connected with the movable half mold 35 through bolts, the arrangement is that two first connecting plates 363 can be driven to move through the bidirectional cylinder 362, the first connecting plates 363 drive the first connecting blocks 364 to move, the first connecting blocks 364 drive the movable half-moulds 35 to move, so that the movable half-moulds 35 are far away from the fixed half-moulds 31 and the movable half-moulds 35 are matched with the fixed half-moulds 31, the clamping assembly 37 comprises a second mounting frame 371, a fourth cylinder 372, a second connecting plate 373, a second connecting plate 374 and a clamping block 375, the second mounting frame 371 is connected in front of the mesh belt conveyor 1 through bolts, the top of the second mounting frame 371 is connected with a fourth cylinder 372 arranged in front and back through bolts, the rear of the output end of the fourth cylinder 372 is connected with the second connecting plate 373 through bolts, a plurality of second connecting blocks 374 are welded on two sides of the second connecting plate 373, the rear of the second connecting plate is connected with the clamping block 375 through bolts, the arrangement is that the fourth cylinder 372 can drive the second connecting plate 373 to move, the connecting rod 343 drives the second connecting block 374 to move, the second connecting block 374 drives the fixture block 375 to move, so that the fixture block 375 is clamped at the outer sides of the fixed half die 31 and the movable half die 35, and the fixture block 375 is free from limiting the fixed half die 31 and the movable half die 35, the fixture block 375 is provided with four clamping jaws, the four clamping jaws are respectively clamped at the upper end and the lower end of the outer sides of the fixed half die 31 and the movable half die 35, the arrangement is such that the movable half die 35 and the fixed half die 31 are more stably matched, the first driving assembly 34 comprises a third cylinder 341, a rotating seat 342 and a connecting rod 343, the third cylinder 341 is connected at the inner side of the fixed plate 33 through bolts, the top of the third cylinder 341 is connected with the rotating seat 342 through bolts, the inner side of the rotating seat 342 is connected with two connecting rods 343 through pins, one ends of the two connecting rods 343 far away from the rotating seat 342 are respectively connected with the two third mounting plates 32 through pins, so that the rotating seat 342 can be driven by the third cylinder 341 to rise, the rotating seat 342 ascends to drive the connecting rod 343 to rotate, the rotating of the connecting rod 343 drives the third mounting plate 32 to rotate, so that the extruded sheet-like material comes out from the fixed half-die 31 and falls on the mesh belt conveyor 1 through the diversion of the third mounting plate 32, the discharging machine 2 comprises a feeding machine body 201 and a feeding extrusion assembly 202, the feeding extrusion assembly 202 is arranged at the bottom of the feeding machine body 201, the feeding extrusion assembly 202 comprises a transverse slide rail pair 2021, an I-shaped plate 2022, a first cylinder 2023, a first mounting plate 2024, a discharging nozzle 2025, a second cylinder 2026, a second mounting plate 2027 and an extrusion rod 2028, the I-shaped plate 2022 is connected with the feeding machine body 201 through two groups of transverse slide rail pairs 2021, one end of the bottom of the I-shaped plate 2022 is connected with the first cylinder 2023 through a bolt, the first mounting plate 2024 is connected below the output end of the first cylinder 2023 through a bolt, a plurality of discharging nozzles 2025 are fixedly mounted at the bottom of the, the discharging nozzle 2025 is communicated with the feeder body 201, the other end of the bottom of the i-shaped plate 2022 is connected with a second air cylinder 2026 through a bolt, the lower part of the output end of the second air cylinder 2026 is connected with a second mounting plate 2027 through a bolt, a plurality of extrusion rods 2028 are fixedly mounted at the bottom of the second mounting plate 2027, the i-shaped plate 2022 can be moved through a transverse sliding rail pair 2021 in such a way until the discharging nozzle 2025 is positioned right above the fixed half die 31, then the first air cylinder 2023 is started, the first air cylinder 2023 drives the first mounting plate 2024 to descend, the first mounting plate 2024 drives the discharging nozzle 2025 to descend, so that the discharging nozzle 2025 is aligned with the fixed half die 31, then the materials quantitatively enter the fixed half die 31 and the movable half die 35 through the feeder body 201 through the discharging nozzle 2025, the i-shaped plate 2022 can also be moved through the transverse sliding rail pair 2021 until the extrusion rods 2028 are positioned right above the fixed half die 31, then the second air cylinder 2026 is started, the second cylinder 2026 drives the second mounting plate 2027 to descend, the second mounting plate 2027 drives the extrusion rod 2028 to descend, so that the extrusion rod 2028 enters the inside of the fixed half mold 31 and the movable half mold 35 to extrude the material into sheets, the first mounting plate 2024 and the second mounting plate 2027 are both of a U-shaped structure, and the two U-shaped structures are alternately arranged, so that the structure of the feeding extrusion assembly 202 is more compact, and further the length of the transverse sliding rail pair 2021 can be reduced, the drying mechanism 4 comprises a fixing frame 401, a fan 402, a heating box 403 and a reflection plate 404, the fixing frame 401 is connected to the other side of the top of the mesh belt conveyor 1 through bolts, the top of the fixing frame 401 is further provided with a plurality of mounting holes, the fan 402 is mounted on the inner side of each mounting hole, the heating box 403 is arranged on the top of the inner side of the fixing frame 401, the heating box 403 is hollow and has an opening at the top, vent holes distributed in an array are formed on the bottom plate of the heating box 403, heating box 403 is internally provided with heating elements, the heating elements can be ceramic heating pipes, resistance heating wires and other devices capable of heating, reflecting plate 404 is installed inside mesh belt conveyor 1, and is located inside the transmission mesh belt of mesh belt conveyor 1, and the upper surface of reflecting plate 404 is provided with curved recess, it can pass through fan 402 and make the heating elements inside heating box 403 produce heat to set up like this, the air current that fan 402 produced blows to the flaky material top after the heating of heating elements this moment, partial air current blows to reflecting plate 404 through mesh belt conveyor 1, then through the reflection of reflecting plate 404, make this partial air current blow to the bottom of flaky material, make the flaky material by drying and sizing.

A method of using a pellet forming apparatus for veterinary drug manufacture, comprising the steps of:

the method comprises the following steps: the I-shaped plate 2022 is moved by the transverse sliding rail pair 2021 until the discharging nozzle 2025 is located right above the fixed half die 31, then the first cylinder 2023 is started, the first cylinder 2023 drives the first mounting plate 2024 to descend, the first mounting plate 2024 drives the discharging nozzle 2025 to descend, so that the discharging nozzle 2025 is aligned with the fixed half die 31, then the material quantitatively enters the fixed half die 31 and the movable half die 35 through the discharging nozzle 2025 by the feeder body 201, and then the first cylinder 2023 is reset;

step two: the I-shaped plate 2022 is moved by the transverse sliding rail pair 2021 until the extrusion rod 2028 is located right above the fixed half die 31, then the second air cylinder 2026 is started, the second air cylinder 2026 drives the second mounting plate 2027 to descend, the second mounting plate 2027 drives the extrusion rod 2028 to descend, so that the extrusion rod 2028 enters the fixed half die 31 and the movable half die 35 to extrude the material, the material is extruded into sheets, and then the second air cylinder 2026 is reset;

step three: the fourth cylinder 372 is started, the fourth cylinder 372 drives the second connecting plate 373 to move forwards, the connecting rod 343 drives the second connecting block 374 to move forwards, and the second connecting block 374 drives the fixture block 375 to move forwards until the fixture block 375 is separated from the fixed half mold 31 and the movable half mold 35;

step four: starting the bidirectional cylinder 362, the bidirectional cylinder 362 drives the two first connecting plates 363 to move, the first connecting plates 363 drive the first connecting blocks 364 to move, and the first connecting blocks 364 drive the movable half-mold 35 to move, so that the movable half-mold 35 is far away from the fixed half-mold 31;

step five: starting the third air cylinder 341, the third air cylinder 341 drives the rotating seat 342 to ascend, the rotating seat 342 ascends to drive the connecting rod 343 to rotate, the connecting rod 343 rotates to drive the third mounting plate 32 to rotate, and at the moment, the extruded sheet material comes out of the fixed half mold 31 and falls on the mesh belt conveyor 1 through the diversion of the third mounting plate 32;

step six: the flaky material falling on the mesh belt conveyor 1 is conveyed to the inside of the drying mechanism 4 by the mesh belt conveyor 1, and in the process, the third mounting plate 32, the second driving assembly 36 and the clamping assembly 37 are reset in sequence and the actions are repeated, so that the function of continuous production is realized;

step seven: the fan 402 is started and the heating elements in the heating box 403 generate heat, at this time, the airflow generated by the fan 402 is heated by the heating elements and then blown to the top of the sheet material, part of the airflow is blown to the reflecting plate 404 through the mesh belt conveyor 1 and then reflected by the reflecting plate 404, so that the part of the airflow is blown to the bottom of the sheet material, and the sheet material is dried and shaped.

Example 2

As shown in fig. 9, embodiment 2 differs from embodiment 1 in that: first drive assembly 34 includes motor 3401, first chain group 3402, second chain group 3403, motor 3401 is inboard at fixed plate 33 through bolted connection, motor 3401's output has first chain group 3402 through the coupling joint, motor 3401's output still is connected with second chain group 3403 through gear engagement, first chain group 3402 and second chain group 3403 are connected with two fixed pin 38 transmissions respectively, it can drive first chain group 3402 and second chain group 3403 antiport through motor 3401 to set up like this, and then make two fixed pin 38 antiport, finally make two third mounting panel 32 antiport, third mounting panel 32 is in the state of slope this moment, the flaky material that makes after being extrudeed comes out from fixed half 31, and fall on mesh belt conveyor 1 through the water conservancy diversion of third mounting panel 32.

A method of using a pellet forming apparatus for veterinary drug manufacture, comprising the steps of:

the method comprises the following steps: the I-shaped plate 2022 is moved by the transverse sliding rail pair 2021 until the discharging nozzle 2025 is located right above the fixed half die 31, then the first cylinder 2023 is started, the first cylinder 2023 drives the first mounting plate 2024 to descend, the first mounting plate 2024 drives the discharging nozzle 2025 to descend, so that the discharging nozzle 2025 is aligned with the fixed half die 31, then the material quantitatively enters the fixed half die 31 and the movable half die 35 through the discharging nozzle 2025 by the feeder body 201, and then the first cylinder 2023 is reset;

step two: the I-shaped plate 2022 is moved by the transverse sliding rail pair 2021 until the extrusion rod 2028 is located right above the fixed half die 31, then the second air cylinder 2026 is started, the second air cylinder 2026 drives the second mounting plate 2027 to descend, the second mounting plate 2027 drives the extrusion rod 2028 to descend, so that the extrusion rod 2028 enters the fixed half die 31 and the movable half die 35 to extrude the material, the material is extruded into sheets, and then the second air cylinder 2026 is reset;

step three: the fourth cylinder 372 is started, the fourth cylinder 372 drives the second connecting plate 373 to move forwards, the connecting rod 343 drives the second connecting block 374 to move forwards, and the second connecting block 374 drives the fixture block 375 to move forwards until the fixture block 375 is separated from the fixed half mold 31 and the movable half mold 35;

step four: starting the bidirectional cylinder 362, the bidirectional cylinder 362 drives the two first connecting plates 363 to move, the first connecting plates 363 drive the first connecting blocks 364 to move, and the first connecting blocks 364 drive the movable half-mold 35 to move, so that the movable half-mold 35 is far away from the fixed half-mold 31;

step five: starting the motor 3401, driving the first chain set 3402 and the second chain set 3403 to rotate reversely by the motor 3401, further enabling the two fixing pins 38 to rotate reversely, and finally enabling the two third mounting plates 32 to rotate reversely, wherein the third mounting plates 32 are in an inclined state, and extruded sheet materials come out from the fixed half die 31 and fall on the mesh belt type conveyor 1 through the diversion of the third mounting plates 32;

step six: the flaky material falling on the mesh belt conveyor 1 is conveyed to the inside of the drying mechanism 4 by the mesh belt conveyor 1, and in the process, the third mounting plate 32, the second driving assembly 36 and the clamping assembly 37 are reset in sequence and the actions are repeated, so that the function of continuous production is realized;

step seven: the fan 402 is started and the heating elements in the heating box 403 generate heat, at this time, the airflow generated by the fan 402 is heated by the heating elements and then blown to the top of the sheet material, part of the airflow is blown to the reflecting plate 404 through the mesh belt conveyor 1 and then reflected by the reflecting plate 404, so that the part of the airflow is blown to the bottom of the sheet material, and the sheet material is dried and shaped.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a granule forming device for animal remedy production, includes mesh belt conveyor (1), mesh belt conveyor (1) top one side is provided with ejection of compact machine (2), ejection of compact machine (2) bottom is provided with forming mechanism (3), mesh belt conveyor (1) top opposite side is provided with drying mechanism (4), its characterized in that: the forming mechanism (3) comprises a fixed half die (31), a third mounting plate (32), a fixing plate (33), a first driving assembly (34), a movable half die (35), a second driving assembly (36), a clamping assembly (37) and a fixing pin (38), wherein the fixed half die (31) is provided with two rows, the back of the fixed half die (31) is provided with a notch with the radian of 180 degrees, the inner side of the notch is provided with the movable half die (35) matched with the notch, one side of the movable half die (35) far away from the fixed half die (31) is provided with the second driving assembly (36) which simultaneously drives all the movable half dies (35) to move, the outer sides of the fixed half die (31) and the movable half die (35) are also provided with the clamping assembly (37), and the two rows of the fixed half die (31) are respectively installed at the tops of the third mounting plate (32), and be located two the looks remote site of third mounting panel (32), third mounting panel (32) are T type structure, and the lower extreme front and back side fixedly connected with fixed pin (38), fixed pin (38) are kept away from the one end of third mounting panel (32) is passed through the bearing and is connected inside fixed plate (33), fixed plate (33) are installed on one side of mesh belt conveyor (1) top, fixed plate (33) inboard is provided with simultaneously drive two fixed pin (38) antiport first drive assembly (34), when two when third mounting panel (32) are horizontal, two the opposite face of third mounting panel (32) is to together.

2. A pellet forming apparatus for veterinary drug manufacture as claimed in claim 1, wherein: the second driving assembly (36) comprises a first mounting frame (361), a two-way cylinder (362), a first connecting plate (363) and a first connecting block (364), the first mounting frame (361) is connected to the rear of the mesh belt conveyor (1) through bolts, the top of the first mounting frame (361) is connected with the two-way cylinder (362) through bolts, two output ends of the two-way cylinder (362) are connected with the first connecting plate (363) through bolts, opposite surfaces of the two first connecting plates (363) are connected with the first connecting block (364) corresponding to the fixed half mold (31) through bolts, and one end, far away from the first connecting plate (363), of the first connecting block (364) is connected with the movable half mold (35) through bolts.

3. A pellet forming apparatus for veterinary drug manufacture as claimed in claim 1, wherein: the clamping assembly (37) comprises a second mounting frame (371), a fourth cylinder (372), a second connecting plate (373), a second connecting block (374) and a clamping block (375), the second mounting frame (371) is connected with the front of the mesh belt type conveyor (1) through bolts, the top of the second mounting frame (371) is connected with the fourth cylinder (372) through bolts, the second connecting plate (373) is connected with the rear of the output end of the fourth cylinder (372) through bolts, a plurality of clamping blocks are welded on two sides of the second connecting plate (373), and the clamping block (375) is connected with the rear of the second connecting block (374) through bolts.

4. A particle forming apparatus for veterinary medicine production according to claim 3, wherein: the clamping block (375) is provided with four clamping jaws which are respectively clamped at the upper end and the lower end of the outer side of the fixed half die (31) and the movable half die (35).

5. A pellet forming apparatus for veterinary drug manufacture as claimed in claim 1, wherein: the first driving assembly (34) comprises a third cylinder (341), a rotating seat (342) and a connecting rod (343), the third cylinder (341) is connected to the inner side of the fixed plate (33) through a bolt, the top of the third cylinder (341) is connected to the rotating seat (342) through a bolt, the inner side of the rotating seat (342) is connected with the two connecting rods (343) through pin shafts, and the connecting rods (343) are far away from one end of the rotating seat (342) and the third mounting plates (32) are connected through pin shafts respectively.

6. A pellet forming apparatus for veterinary drug manufacture as claimed in claim 1, wherein: first drive assembly (34) include motor (3401), first chain group (3402), second chain group (3403), motor (3401) pass through bolted connection and are in fixed plate (33) are inboard, there is first chain group (3402) output of motor (3401) through the coupling joint, the output of motor (3401) still is connected with through gear engagement second chain group (3403), first chain group (3402) with second chain group (3403) respectively with two fixed pin (38) transmission is connected.

7. A pellet forming apparatus for veterinary drug manufacture as claimed in claim 1, wherein: the discharging machine (2) comprises a feeding machine body (201) and a feeding extrusion assembly (202), the feeding extrusion assembly (202) is arranged at the bottom of the feeding machine body (201), the feeding extrusion assembly (202) comprises a transverse slide rail pair (2021), an I-shaped plate (2022), a first air cylinder (2023), a first mounting plate (2024), a discharging nozzle (2025), a second air cylinder (2026), a second mounting plate (2027) and an extrusion rod (2028), the I-shaped plate (2022) is connected with the feeding machine body (201) through two groups of transverse slide rail pairs (2021), one end of the bottom of the I-shaped plate (2022) is connected with the first air cylinder (2023) through a bolt, the first mounting plate (2024) is connected below the output end of the first air cylinder (2023) through a bolt, and a plurality of discharging nozzles (2025) are fixedly mounted at the bottom of the first mounting plate (2024), the discharging nozzle (2025) is communicated with the feeder body (201), the other end of the bottom of the I-shaped plate (2022) is connected with the second cylinder (2026) through a bolt, the lower part of the output end of the second cylinder (2026) is connected with the second mounting plate (2027) through a bolt, and the bottom of the second mounting plate (2027) is fixedly provided with a plurality of extrusion rods (2028).

8. A particle forming apparatus for veterinary drug production according to claim 7, wherein: the first mounting plate (2024) and the second mounting plate (2027) are both U-shaped structures, and the two U-shaped structures are alternately arranged.

9. A pellet forming apparatus for veterinary drug manufacture as claimed in claim 1, wherein: the drying mechanism (4) comprises a fixed frame (401), a fan (402), a heating box (403) and a reflecting plate (404), the fixing frame (401) is connected with the other side of the top of the mesh belt type conveyor (1) through bolts, a plurality of mounting holes are also arranged on the top of the fixing frame (401), the fan (402) is arranged at the inner side of the mounting hole, the heating box (403) is arranged at the top of the inner side of the fixing frame (401), the heating box (403) is hollow and has an open top, the bottom plate of the heating box (403) is provided with vent holes distributed in an array manner, the heating box (403) is internally provided with a heating element, the reflecting plate (404) is arranged inside the mesh belt conveyor (1), and is positioned at the inner side of a transmission mesh belt in the mesh belt type conveyor (1), and the upper surface of the reflecting plate (404) is provided with an arc-shaped groove.

10. A use method for animal remedy production's granule forming device which characterized in that: the method comprises the following steps:

the method comprises the following steps: the I-shaped plate (2022) is moved by the transverse sliding rail pair (2021) until the discharging nozzle (2025) is positioned right above the fixed half die (31), then the first air cylinder (2023) is started, the first air cylinder (2023) drives the first mounting plate (2024) to descend, the first mounting plate (2024) drives the discharging nozzle (2025) to descend, so that the discharging nozzle (2025) is aligned to the fixed half die (31), then the materials quantitatively enter the fixed half die (31) and the movable half die (35) through the discharging nozzle (2025) by the feeder body (201), and then the first air cylinder (2023) resets;

step two: the I-shaped plate (2022) is moved by the transverse sliding rail pair (2021) until the extrusion rod (2028) is positioned right above the fixed half die (31), then the second air cylinder (2026) is started, the second air cylinder (2026) drives the second mounting plate (2027) to descend, the second mounting plate (2027) drives the extrusion rod (2028) to descend, so that the extrusion rod (2028) enters the fixed half die (31) and the movable half die (35) to extrude the material, the material is extruded into sheets, and then the second air cylinder (2026) is reset;

step three: the fourth cylinder (372) is started, the fourth cylinder (372) drives the second connecting plate (373) to move forwards, the connecting rod (343) drives the second connecting block (374) to move forwards, and the second connecting block (374) drives the clamping block (375) to move forwards until the clamping block (375) is separated from the fixed half mold (31) and the movable half mold (35);

step four: starting a bidirectional cylinder (362), wherein the bidirectional cylinder (362) drives two first connecting plates (363) to move, the first connecting plates (363) drive first connecting blocks (364) to move, and the first connecting blocks (364) drive movable half moulds (35) to move, so that the movable half moulds (35) are far away from the fixed half moulds (31);

step five: the third air cylinder (341) is started, the third air cylinder (341) drives the rotating seat (342) to ascend, the rotating seat (342) ascends to drive the connecting rod (343) to rotate, the rotating rod (343) drives the third mounting plate (32) to rotate, and at the moment, the extruded sheet material comes out of the fixed half mold (31), and falls on the mesh belt conveyor (1) through the diversion of the third mounting plate (32), or starting the motor (3401), the motor (3401) drives the first chain group (3402) and the second chain group (3403) to rotate reversely, so that the two fixing pins (38) rotate reversely, and finally the two third mounting plates (32) rotate reversely, at the moment, the third mounting plates (32) are in an inclined state, the extruded sheet material comes out from the fixed half mould (31), and falls on the mesh belt conveyor (1) through the diversion of the third mounting plate (32);

step six: the flaky materials falling on the mesh belt type conveyor (1) are conveyed to the inside of the drying mechanism (4) by the mesh belt type conveyor (1), and in the process, the third mounting plate (32), the second driving assembly (36) and the clamping assembly (37) are reset in sequence and the actions are repeated, so that the function of continuous production is realized;

step seven: the fan (402) is started and heating elements in the heating box (403) generate heat, at the moment, air flow generated by the fan (402) is heated by the heating elements and then blown to the top of the sheet materials, partial air flow is blown to the reflecting plate (404) through the mesh belt conveyor (1) and then reflected by the reflecting plate (404), and the partial air flow is blown to the bottom of the sheet materials, so that the sheet materials are dried and shaped.

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