CN216071422U - Intelligent equipment for feeding ingredients - Google Patents

Abstract

The utility model provides intelligent equipment for feeding and batching, and relates to the technical field of feeding and batching. According to the vibration device, when the vibration motor operates, vibration can be transmitted to the inside of the vibration source block, the vibration source block is attached to the transmission rod, the conical vibration block can vibrate, the vibration is transmitted to the top of the top plate, the material storage shell vibrates, the blanking shell receives the vibration, the whole device vibrates, the material is fed in quickly, and the internal blockage of the device is reduced.

Description

Intelligent equipment for feeding ingredients

Technical Field

The utility model relates to the technical field of dosing, in particular to intelligent equipment for dosing.

Background

In general, an intelligent terminal is a type of embedded computer system device, and therefore, the architecture framework of the intelligent terminal is consistent with the architecture of an embedded system; meanwhile, the intelligent terminal is used as an application direction of the embedded system, and the application scene setting is clear, so that the system structure is more clear than that of a common embedded system, the granularity is finer, and the system has certain characteristics.

However, in the prior art, the existing dosing intelligent terminal can intelligently manage dosing when in use, but some dosing intelligent terminals are not provided with a vibration system, fine particles can be clamped in the device when in dosing, and the machine can be blocked and cannot be used.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects in the prior art.

In order to achieve the purpose, the utility model adopts the following technical scheme: the utility model provides an intelligent equipment for throw batching, includes the bottom plate, the top welding of bottom plate has damping spring, damping spring's top fixed mounting has T shape pole, the top welding of T shape pole has branch, the top welding of bottom plate has hollow shell, the internal surface of hollow shell and damping spring's surface looks adaptation, the top welding of branch has the roof, the top fixed mounting of roof has the storage shell, the bottom fixed mounting of roof has toper vibrations piece, the bottom fixed mounting of toper vibrations piece has the transmission pole, the top fixed mounting of bottom plate has the shock attenuation steel sheet, the top fixed mounting of shock attenuation steel sheet has shock dynamo, shock dynamo's output fixed mounting has the vibrations source piece, the surface of vibrations source piece and the surface looks adaptation of transmission pole.

As a preferred embodiment, the front surface of the storage shell is fixedly provided with a controller, the right side of the storage shell is rotatably connected with a baffle plate through a hinge, the right side of the baffle plate is fixedly provided with a magnetic block, and the left side of the magnetic block is magnetically adsorbed with the right side of the storage shell.

As a preferred embodiment, the top of the storage shell is fixedly communicated with a blanking shell, a first screen plate is fixedly arranged in the blanking shell, and a rotary shell penetrates through the inner part of the blanking shell.

As a preferred embodiment, the bottom of the rotating shell is welded with a second filter plate, and the top of the storage shell is fixedly provided with a fixed frame.

As a preferred embodiment, a driving motor is fixedly mounted at the top of the fixing frame, a shaft lever is fixedly mounted at the output end of the driving motor, slotted holes are formed in the left side of the blanking shell and the left side of the rotating shell, and the inner surfaces of the two slotted holes are matched with the outer surface of the shaft lever.

As a preferred embodiment, a turning plate is fixedly mounted on the outer surface of the shaft rod, a weight sensor is fixedly mounted on the top of the turning plate, and the outer surface of the turning plate is matched with the inner surface of the rotating shell.

Compared with the prior art, the utility model has the advantages and positive effects that,

1. according to the vibration device, when the vibration motor operates, vibration can be transmitted to the inside of the vibration source block, the vibration source block is attached to the transmission rod, the conical vibration block can vibrate, the vibration is transmitted to the top of the top plate, the material storage shell vibrates, the blanking shell receives the vibration, the whole device vibrates, the material is fed in quickly, and the internal blockage of the device is reduced.

2. According to the utility model, a first sieving plate arranged inside a blanking shell and a second sieving plate arranged at the bottom of a rotary shell can be overlapped together, the rotary shell can rotate, a sieving hole formed in the first sieving plate is larger than a sieving hole formed in the second sieving plate, and when the second sieving plate rotates and moves at the top of the first sieving plate, the size of a sieving hole can be changed, materials with different particle sizes can be screened, and the materials can be screened by combining the action of a bottom vibrating motor.

Drawings

Fig. 1 is a schematic front perspective view of an intelligent device for dosing ingredients according to the present invention;

FIG. 2 is a schematic view of a cross-sectional perspective structure of an intelligent device for dosing ingredients according to the present invention;

fig. 3 is a schematic top perspective view of an intelligent device for dosing ingredients according to the present invention;

fig. 4 is a schematic perspective view of a bottom plate of an intelligent device for dosing ingredients according to the present invention.

Illustration of the drawings:

1. a base plate; 2. a damping spring; 3. a T-shaped rod; 4. a hollow shell; 5. a strut; 6. a top plate; 7. a material storage shell; 8. a hinge; 9. a baffle plate; 10. a magnetic block; 11. blanking shell; 12. a first screen plate; 13. rotating the housing; 14. a second sieve plate; 15. a slot; 16. a fixed mount; 17. a drive motor; 18. a shaft lever; 19. a turnover plate; 20. a weight sensor; 21. a controller; 22. a conical seismic mass; 23. a transfer lever; 24. a damping steel plate; 25. vibrating a motor; 26. and vibrating the source block.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1 to 4, the present invention provides a technical solution: an intelligent device for dosing ingredients comprises a bottom plate 1, a damping spring 2 is welded at the top of the bottom plate 1, a T-shaped rod 3 is fixedly installed at the top of the damping spring 2, a support rod 5 is welded at the top of the T-shaped rod 3, a hollow shell 4 is welded at the top of the bottom plate 1, the inner surface of the hollow shell 4 is matched with the outer surface of the damping spring 2, a top plate 6 is welded at the top of the support rod 5, a storage shell 7 is fixedly installed at the top of the top plate 6, a conical vibration block 22 is fixedly installed at the bottom of the top plate 6, a transmission rod 23 is fixedly installed at the bottom of the conical vibration block 22, a damping steel plate 24 is fixedly installed at the top of the bottom plate 1, a vibration motor 25 is fixedly installed at the top of the damping steel plate 24, a vibration source block 26 is fixedly installed at the output end of the vibration motor 25, the outer surface of the vibration source block 26 is matched with the outer surface of the transmission rod 23, a controller 21 is fixedly installed on the front surface of the storage shell 7, the right side of the storage shell 7 is rotatably connected with a baffle plate 9 through a hinge 8, a magnetic block 10 is fixedly mounted on the right side of the baffle plate 9, and the left side of the magnetic block 10 is magnetically adsorbed with the right side of the storage shell 7.

In this embodiment, when in use, the bottom plate 1 plays a role in fixing, when the top plate 6 generates vibration, the vibration can be transmitted downwards to the top of the T-shaped rod 3 through the supporting rod 5, the T-shaped rod 3 is inserted in the damping spring 2, when the T-shaped rod 3 vibrates, the damping spring 2 can buffer the vibration, the hollow shell 4 sleeves the supporting rod 5 inside, when the supporting rod 5 vibrates, the supporting rod 5 can play a role in limiting, the vibration motor 25 operates, when the vibration motor 25 starts to operate, the vibration can be transmitted to the inside of the vibration source block 26, the vibration source block 26 is attached to the transmission rod 23, the conical vibration block 22 can generate vibration and transmit the vibration to the top of the top plate 6, so that the material storage shell 7 generates vibration, the blanking shell 11 receives the vibration, the controller 21 sends an instruction, and can control the vibration motor 25 and the driving motor 17, after a large amount of materials are accumulated inside the material storage shell 7, the magnetic block 10 is separated from the outer surface of the material storage shell 7, so that the baffle 9 is opened, and the materials are taken out.

Example 2

As shown in fig. 1-4, the top of the storage shell 7 is fixedly communicated with a blanking shell 11, the inside of the blanking shell 11 is fixedly provided with a first passing sieve plate 12, the inside of the blanking shell 11 is movably penetrated by a rotating shell 13, the bottom of the rotating shell 13 is welded with a second passing sieve plate 14, the top of the storage shell 7 is fixedly provided with a fixing frame 16, the top of the fixing frame 16 is fixedly provided with a driving motor 17, the output end of the driving motor 17 is fixedly provided with a shaft rod 18, the left side of the blanking shell 11 and the left side of the rotating shell 13 are both provided with a slotted hole 15, the inner surfaces of the two slotted holes 15 are both adapted to the outer surface of the shaft rod 18, the outer surface of the shaft rod 18 is fixedly provided with a turnover plate 19, the top of the turnover plate 19 is fixedly provided with a weight sensor 20, and the outer surface of the turnover plate 19 is adapted to the inner surface of the rotating shell 13.

In this embodiment, a turnover plate 19 controlled by a driving motor 17 is installed inside the blanking shell 11, a weight sensor 20 installed on the top of the turnover plate 19 can weigh the material placed on the top of the turnover plate 19, when the weight is satisfied, the weight sensor 20 transmits a command to the controller 21, the controller 21 drives the driving motor 17, the shaft lever 18 rotates, the turnover plate 19 turns over, make the material landing to the inside of unloading shell 11, the sieve 14 can coincide together in the first sieve 12 of crossing of the internally mounted of unloading shell 11 and the second of rotatory 13 bottom installations of shell, rotatory 13 can rotate, the first sieve hole of crossing set up on the sieve 12 is bigger than the sieve hole of crossing set up on the sieve 14 of second, sieve 14 is crossed in the second when the first top swivelling movement of crossing sieve 12, can change the size of sieve mesh, filter the material of different particle sizes.

The working principle of the embodiment is as follows:

as shown in fig. 1-4, when in use, the bottom plate 1 plays a fixed role, when the top plate 6 generates vibration, the vibration can be transmitted downwards to the top of the T-shaped rod 3 through the supporting rod 5, the T-shaped rod 3 is inserted in the damping spring 2, when the T-shaped rod 3 vibrates, the damping spring 2 can buffer the vibration, the hollow shell 4 sleeves the supporting rod 5 inside, when the supporting rod 5 vibrates, the supporting rod 5 can play a limiting role, the vibration motor 25 operates, when the vibration motor 25 starts to operate, the vibration can be transmitted to the inside of the vibration source block 26, the vibration source block 26 is attached to the transmission rod 23, the conical vibration block 22 can generate vibration and transmit the vibration to the top of the top plate 6, so that the material storage shell 7 generates vibration, the blanking shell 11 receives the vibration, the controller 21 sends an instruction to control the vibration motor 25 and the driving motor 17, after a large amount of materials are accumulated in the storage shell 7, the magnetic blocks 10 are separated from the outer surface of the storage shell 7, the baffle plates 9 are opened, the materials are taken out, the turnover plate 19 which can be controlled by the driving motor 17 is arranged in the blanking shell 11, the material placed on the top of the turnover plate 19 can be weighed by the weight sensor 20 arranged on the top of the turnover plate 19, when the weight is met, the instruction is transmitted to the controller 21 by the weight sensor 20, the driving motor 17 is driven by the controller 21, the shaft rod 18 rotates to turn over the turnover plate 19, so that the material slides into the blanking shell 11, the first screening plate 12 arranged in the blanking shell 11 and the second screening plate 14 arranged at the bottom of the rotary shell 13 can be overlapped together, the rotary shell 13 can rotate, the screening holes formed in the first screening plate 12 are larger than the screening holes formed in the second screening plate 14, and when the second screening plate 14 rotates on the top of the first screening plate 12, the size of the sieve mesh can be changed, materials with different particle sizes can be screened, and the materials are screened under the action of the bottom vibrating motor 25.

The above description is only a preferred embodiment of the present invention, and not intended to limit the present invention in other forms, and any person skilled in the art may apply the above modifications or changes to the equivalent embodiments with equivalent changes, without departing from the technical spirit of the present invention, and any simple modification, equivalent change and change made to the above embodiments according to the technical spirit of the present invention still belong to the protection scope of the technical spirit of the present invention.

Claims (6)

1. An intelligent device for dosing ingredients, comprising a base plate (1), characterized in that: the shock absorption device is characterized in that the shock absorption spring (2) is welded at the top of the bottom plate (1), a T-shaped rod (3) is fixedly installed at the top of the shock absorption spring (2), a supporting rod (5) is welded at the top of the T-shaped rod (3), a hollow shell (4) is welded at the top of the bottom plate (1), the inner surface of the hollow shell (4) is matched with the outer surface of the shock absorption spring (2), a top plate (6) is welded at the top of the supporting rod (5), a storage shell (7) is fixedly installed at the top of the top plate (6), a conical shock absorption block (22) is fixedly installed at the bottom of the top plate (6), a transmission rod (23) is fixedly installed at the bottom of the conical shock absorption block (22), a shock absorption steel plate (24) is fixedly installed at the top of the bottom plate (1), a shock absorption motor (25) is fixedly installed at the top of the shock absorption steel plate (24), and a shock absorption source block (26) is fixedly installed at the output end of the shock absorption motor (25), the outer surface of the vibration source block (26) is matched with the outer surface of the transmission rod (23).

2. A smart device for dosing ingredients as claimed in claim 1, characterized in that: the positive fixed surface of storage shell (7) installs controller (21), there is baffle (9) on the right side of storage shell (7) through hinge (8) swivelling joint, the right side fixed mounting of baffle (9) has magnetic block (10), the left side of magnetic block (10) and the right side magnetic adsorption of storage shell (7).

3. A smart device for dosing ingredients as claimed in claim 1, characterized in that: the top of storage shell (7) is fixed the intercommunication and is had unloading shell (11), the inside fixed mounting of unloading shell (11) has first sieve (12) of crossing, the inside activity of unloading shell (11) is run through and is had rotatory shell (13).

4. A smart device for dosing ingredients according to claim 3, characterized in that: the bottom welding of rotatory shell (13) has second to cross sieve (14), there is fixed mounting at the top of storage shell (7) has mount (16).

5. A smart device for dosing ingredients as claimed in claim 4, characterized in that: the top fixed mounting of mount (16) has driving motor (17), the output fixed mounting of driving motor (17) has axostylus axostyle (18), slotted hole (15) have all been seted up with the left side of rotatory shell (13) in the left side of unloading shell (11), two the internal surface of slotted hole (15) all with the surface looks adaptation of axostylus axostyle (18).

6. A smart device for dosing ingredients as claimed in claim 5, characterized in that: the outer surface of the shaft rod (18) is fixedly provided with a turnover plate (19), the top of the turnover plate (19) is fixedly provided with a weight sensor (20), and the outer surface of the turnover plate (19) is matched with the inner surface of the rotating shell (13).

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