CN113148685A - Automatic feeder - Google Patents

Abstract

The invention discloses an automatic feeder which comprises a feeding mechanism and a feeding mechanism connected with the feeding mechanism, wherein the feeding mechanism comprises a feeding barrel, a feeding pipe, a telescopic corrugated pipe, a vibration feeding assembly and a flat transferring driving assembly, one end of the feeding pipe is inserted into the feeding barrel and is connected with the feeding mechanism, the telescopic corrugated pipe is sleeved on the periphery of the feeding pipe and is connected with the outer side edge of the feeding barrel, the vibration feeding assembly is connected with the feeding pipe, and the flat transferring driving assembly is connected with the feeding barrel. The automatic feeder provided by the invention has the advantages of high automation degree, high efficiency and low cost, can effectively prevent the blockage of materials in the conveying process, and is beneficial to orderly, smooth and stable feeding operation.

Description

Automatic feeder

Technical Field

The invention relates to a feeding device, in particular to an automatic feeder.

Background

At present, in the processing and production process of materials such as crystal materials and the like, a manual or mechanical feeding mode is adopted, and the defects of the manual feeding mode are as follows: the workload is large, the operation is troublesome, the labor cost is high, the automation degree is low, and the efficiency is low; the mechanical feeding mode has the following disadvantages: the phenomenon that materials such as crystal materials are blocked in a pipeline is easy to occur, and the smooth and stable operation of the feeding process is influenced.

Disclosure of Invention

In view of the above disadvantages, the present invention provides an automatic feeder, which has high automation degree, high efficiency, and low cost, and can effectively prevent the material from being blocked during the transportation process, and facilitate the orderly, smooth, and stable feeding operation.

The technical scheme adopted by the invention to achieve the aim is as follows:

an automatic feeder is characterized by comprising a feeding mechanism and a feeding mechanism connected to the feeding mechanism, wherein the feeding mechanism comprises a feeding barrel, a feeding pipe, a telescopic corrugated pipe, a vibration feeding assembly and a flat transferring driving assembly, one end of the feeding pipe is inserted into the feeding barrel and is connected to the feeding mechanism, the telescopic corrugated pipe is sleeved on the periphery of the feeding pipe and is connected to the outer side edge of the feeding barrel, the vibration feeding assembly is connected to the feeding pipe, and the flat transferring driving assembly is connected to the feeding barrel.

As a further improvement of the present invention, the vibration feeding assembly includes a feeding linear vibrator disposed in the feeding barrel, and a receiving hopper disposed on the feeding linear vibrator and positioned at the head end of the feeding pipe, and a blanking port is formed at the head end of the feeding pipe corresponding to the receiving hopper.

As a further improvement of the invention, the head end of the feeding pipe is positioned in the feeding cylinder, and the tail end of the feeding pipe extends to the outside of the feeding cylinder.

As a further improvement of the present invention, the translational feeding driving assembly includes a base, a servo motor disposed on the base, a ball screw erected on the base and connected to the servo motor, and a nut sleeved on the periphery of the ball screw, wherein the nut is connected to the feeding barrel through a nut seat and disposed on the base through a connecting block.

As a further improvement of the invention, a translation guide assembly is arranged on the base, and the translation guide assembly comprises two conveying rails arranged in parallel along the length extension direction of the feeding pipe, a plurality of conveying slide blocks arranged on the two conveying rails in a sliding manner and connected to the feeding barrel, and a chain arranged on the base and connected to the feeding barrel.

As a further improvement of the invention, the tail end of the telescopic corrugated pipe is connected with a connecting pipeline which is connected with a gate valve.

As a further improvement of the invention, a connecting plate connected with the connecting pipeline is arranged at the tail end of the telescopic corrugated pipe, at least one guide rod is connected between the connecting plate and the feeding barrel, and the guide rod is movably inserted into the feeding barrel.

As a further improvement of the invention, the feeding mechanism comprises a feeding cylinder arranged on the feeding cylinder and a material containing hopper arranged in the feeding cylinder, and the material containing hopper is positioned above the material receiving hopper.

As a further improvement of the invention, the feeding cylinder is erected in the feeding cylinder through a weighing bracket, a plurality of weighing sensors are arranged at the lower end of the weighing bracket, and the vibration feeding assembly is arranged on the weighing bracket.

As a further improvement of the invention, an observation maintenance door is arranged on the feeding barrel and corresponding to the head end of the feeding pipe.

The invention has the beneficial effects that: feed mechanism and feeding mechanism through having special structural design combine together, adopt the mode of vibration pay-off, realize that the material from flourishing material funnel carries to conveying pipe and main furnace chamber in proper order, accomplish the automatic material conveying operation, and whole equipment operation is smooth and easy, and degree of automation is high, and is efficient, reduce cost. Meanwhile, the mode of vibration feeding is adopted, so that the phenomenon of blockage of the materials in the conveying process can be effectively prevented, and the ordered, smooth and stable feeding operation is facilitated.

The above is an overview of the technical solutions of the present invention, and the present invention is further described below with reference to the accompanying drawings and the detailed description thereof.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the present invention;

FIG. 3 is a schematic view of the combination of a feed pipe and a bellows according to the present invention;

FIG. 4 is a schematic structural view of a translational feed drive assembly of the present invention;

FIG. 5 is a schematic view showing the structure of the combination of the automatic feeder and the main furnace chamber in the present invention.

Detailed Description

To further illustrate the technical means and effects of the present invention adopted to achieve the predetermined purposes, the following detailed description of the embodiments of the present invention is provided with the accompanying drawings and the preferred embodiments.

Referring to fig. 1 and 2, an embodiment of the invention provides an automatic feeder, including a feeding mechanism 1 and a feeding mechanism 2 connected to the feeding mechanism 1, wherein the feeding mechanism 2 includes a feeding tube 21, a feeding tube 22 having one end inserted into the feeding tube 21 and connected to the feeding mechanism 1, a flexible bellows 23 sleeved on the periphery of the feeding tube 22 and connected to the outer side of the feeding tube 21, a vibration feeding assembly 24 connected to the feeding tube 22, and a flat feeding driving assembly 25 connected to the feeding tube 21. The materials are fed into the feeding pipe 22 of the feeding mechanism 2 by the feeding mechanism 1, and then are continuously conveyed forwards by the feeding pipe 22 under the vibration action of the vibration feeding component 24, and finally are conveyed into the main furnace chamber 3 by the feeding pipe 22 under the driving action of the translation feeding driving component 25, as shown in fig. 5, the whole automatic feeding process is completed. In this embodiment, the material may be a crystal material, that is, the embodiment may complete an automatic feeding operation of the crystal material.

In the present embodiment, as shown in fig. 2, the vibration feeding assembly 24 includes a feeding linear vibrator 241 disposed in the feeding barrel 21, and a receiving hopper 242 disposed on the feeding linear vibrator 241 and positioned at the head end of the feeding pipe 22, and a blanking opening 220 is formed at the head end of the feeding pipe 22 corresponding to the receiving hopper 242, as shown in fig. 3. Thereby, the feeding pipe 22 is positioned on the feeding straight vibrator 241 by the positioning function of the receiving hopper 242. The feeding pipe 22 is driven to vibrate by the vibration of the feeding straight vibrator 241, so that the material entering the feeding pipe 22 is continuously conveyed forward by the vibration and finally conveyed into the main furnace chamber 3.

Regarding the position of the feeding pipe 22, the head end of the feeding pipe 22 is located in the feeding barrel 21, and the tail end extends to the outside of the feeding barrel 21. Specifically, the feeding tube 22 of this embodiment may be a quartz tube.

In the present embodiment, as shown in fig. 1 and fig. 4, the translational feeding driving assembly 25 includes a base 251, a servo motor 252 disposed on the base 251, a ball screw 253 mounted on the base 251 and connected to the servo motor 252, and a nut 254 sleeved on the periphery of the ball screw 253, wherein the nut 254 is connected to the feeding barrel 21 through a nut seat 255 and disposed on the base 251 through a connecting block 257. The servo motor 252 provides driving force to drive the ball screw 253 to rotate continuously, so that the nut 254 drives the feeding barrel 21 to move in a translation mode, the feeding pipe 22 and the vibration feeding assembly 24 are positioned on the feeding barrel 21, the feeding pipe 22 and the vibration feeding assembly 24 are driven to move in a translation mode synchronously, materials in the feeding pipe 22 are conveyed into the main furnace chamber 3, and after feeding is completed, the feeding pipe 22 is controlled to move in a translation mode to leave the main furnace chamber 3.

In order to improve the stability of the translation feeding driving assembly 25 driving the feeding tube 22 to translate, as shown in fig. 1 and 4, in this embodiment, a translation guiding assembly 256 is disposed on the base 251, and the translation guiding assembly 256 includes two parallel conveying rails 2561 arranged along the length extending direction of the feeding tube 22, a plurality of conveying sliders 2562 slidably disposed on the two conveying rails 2561 and connected to the feeding barrel 21, and a chain 2563 disposed on the base 251 and connected to the feeding barrel 21. The two conveying rails 2561, the plurality of conveying sliding blocks 2562 and the chain 2563 are combined to provide a guiding effect for translational feeding, and the translational stability is improved.

In this embodiment, a connecting pipe 26 is connected to the end of the bellows 23, and the connecting pipe 26 is connected to a gate valve 27. The opening and closing of the main furnace chamber 3 and the feeding pipe 22 are controlled by the arrangement of the gate valve 27, when the gate valve 27 is opened, the main furnace chamber 3 is communicated with the feeding pipe 22, and then the subsequent material conveying to the main furnace chamber 3 can be carried out, so that the feeding operation is completed; when the gate valve 27 is closed, the main furnace chamber 3 is disconnected from the feed pipe 22, and the material conveying operation is stopped.

This embodiment plays sealed effect through set up concertina ripple pipe 23 in a pay-off section of thick bamboo 21 periphery, is convenient for adopt the mode of evacuation to open and close push-pull valve 27. Specifically, when the feeding is not needed, the gate valve 27 is closed, and the main furnace chamber 3 is disconnected from the feeding pipe 22; when feeding, the gate valve 27 is butted with the telescopic corrugated pipe 23, the main furnace chamber 3 is communicated with the feeding pipe 22, the interior of the feeder is vacuumized, the gate valves 27 are opened for feeding when the vacuum values at two ends of the gate valve 27 (the main furnace chamber 3 and the interior of the feeder) are the same, and the gate valves 27 are closed to remove the feeder after feeding.

In the process of driving the feeding tube 22 to move horizontally left and right by the translational feeding driving assembly 25, the telescopic bellows 23 performs adaptive telescopic motion, as shown in fig. 1, a connecting plate 231 connected with the connecting pipe 26 is arranged at the tail end of the telescopic bellows 23, at least one guide rod 232 is connected between the connecting plate 231 and the feeding barrel 21, and the guide rod 232 is movably inserted into the feeding barrel 21. When translation pay-off drive assembly 25 drove conveying pipe 22 and feeding barrel 21 and moved toward 3 directions in the main furnace chamber, telescopic bellows 23 was compressed, and conveying pipe 22 moved toward 3 directions in telescopic bellows 23 in the main furnace chamber, carried the material to 3 directions in the main furnace chamber, and at this in-process, guide arm 232 activity was inserted in feeding barrel 21, and feeding barrel 21 was along guide arm 232 translation promptly. On the contrary, when the translational feeding driving assembly 25 drives the feeding tube 22 and the feeding barrel 21 to move in the direction away from the main furnace chamber 3, the telescopic bellows 23 is stretched, and the feeding tube 22 moves in the telescopic bellows 23 in the reverse direction, in this process, the feeding barrel 21 moves in the reverse direction along the guide rod 232.

In the present embodiment, as shown in fig. 1 and fig. 2, the feeding mechanism 1 includes a feeding cylinder 11 disposed on the feeding cylinder 21, and a material holding funnel 12 disposed in the feeding cylinder 11, and the material holding funnel 12 is located above the material receiving funnel 242. The material is fed from the hopper 12, falls into the feeding tube 22 through the receiving hopper 242 and the blanking port 220, and is then fed forward by the feeding tube 22.

In order to better control the feeding amount, as shown in fig. 2, the feeding cylinder 11 of this embodiment is erected in the feeding cylinder 21 by a weighing bracket 13, and a plurality of weighing sensors 14 are arranged at the lower end of the weighing bracket 13, and the vibrating feeding assembly 24 is arranged on the weighing bracket 13. Before feeding, the initial weight (the total weight of the feeding mechanism 1, the feeding pipe 22, the telescopic corrugated pipe 23, the material receiving hopper 242 and the vibrating feeding assembly 24) is weighed by the plurality of weighing sensors 14, the weight is weighed in real time in the feeding process, and the feeding is stopped after the set feeding weight is reached. Therefore, the feeding amount can be accurately controlled conveniently.

In order to facilitate real-time observation of the feeding situation and maintenance of internal equipment, as shown in fig. 1, an observation maintenance door 210 is provided on the feeding barrel 21 and corresponding to the head end of the feeding pipe 22 in this embodiment.

The working principle of the embodiment is as follows:

the method comprises the following steps of (1) loading materials (crystal materials) into a material containing hopper 12, then integrally transporting a feeder to a feeding position (beside a main furnace chamber 3), and arranging a feeding mechanism 1 and a feeding mechanism 2 on a positioning vehicle 30 for facilitating integral movement of the feeder; the telescopic bellows 23 is connected with the gate valve 27, the power supply is switched on, the weighing sensor 14 weighs the initial weight, the vacuumizing valve is opened, and the gate valve 27 is opened when the air pressure (vacuum) values at the two ends of the main furnace chamber 3 and the feeder are the same. Then, the feeding pipe 22 is fed into the main furnace chamber 3 by the translational feeding driving component 25, the feeding weight is set, the feeding linear vibrator 241 is turned on, the feeding pipe 22 feeds into the main furnace chamber 3, and the feeding linear vibrator 241 is turned off after the feeding weight value is reached. Subsequently, the translation feeding driving component 25 drives the feeding pipe 22 to return, the gate valve 27 is closed, the connection of the telescopic bellows 23 is released, and the furnace can be transferred to another furnace for recharging.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that other structures obtained by using the same or similar technical features as the above-described embodiments of the present invention are within the protection scope of the present invention.

Claims (10)

1. An automatic feeder is characterized by comprising a feeding mechanism and a feeding mechanism connected to the feeding mechanism, wherein the feeding mechanism comprises a feeding barrel, a feeding pipe, a telescopic corrugated pipe, a vibration feeding assembly and a flat transferring driving assembly, one end of the feeding pipe is inserted into the feeding barrel and is connected to the feeding mechanism, the telescopic corrugated pipe is sleeved on the periphery of the feeding pipe and is connected to the outer side edge of the feeding barrel, the vibration feeding assembly is connected to the feeding pipe, and the flat transferring driving assembly is connected to the feeding barrel.

2. The automatic feeder according to claim 1, wherein the vibrating feeder assembly comprises a feeding linear vibrator disposed in the feeding barrel, and a receiving hopper disposed on the feeding linear vibrator and positioned at a head end of the feeding pipe, and a blanking opening is formed at the head end of the feeding pipe corresponding to the receiving hopper.

3. The automatic feeder of claim 1, wherein the feed tube has a head end located within the feed cylinder and a tail end extending outside the feed cylinder.

4. The automatic feeder according to claim 1, wherein the translational feeding driving assembly comprises a base, a servo motor disposed on the base, a ball screw mounted on the base and connected to the servo motor, and a nut sleeved on the outer periphery of the ball screw, wherein the nut is connected to the feeding barrel through a nut seat and disposed on the base through a connecting block.

5. The automatic feeder according to claim 4, wherein a translational guide assembly is disposed on the base, the translational guide assembly comprises two parallel conveying rails disposed along the length of the feeding tube, a plurality of conveying sliders slidably disposed on the two conveying rails and connected to the feeding barrel, and a chain disposed on the base and connected to the feeding barrel.

6. The automatic feeder according to claim 1, wherein a connection pipe is connected to the end of the bellows, and the connection pipe is connected to a gate valve.

7. The automatic feeder according to claim 6, wherein a connection plate connected to the connection pipe is provided at the end of the bellows, and at least one guide rod is connected between the connection plate and the feeding barrel, and is movably inserted into the feeding barrel.

8. The automatic feeder according to claim 2, wherein the feeding mechanism comprises a feeding barrel disposed on the feeding barrel, and a material holding hopper disposed in the feeding barrel, and the material holding hopper is located above the material receiving hopper.

9. The automatic feeder according to claim 8, wherein the feeding cylinder is mounted in the feeding cylinder by a weighing bracket, and a plurality of weighing sensors are disposed at a lower end of the weighing bracket, and the vibration feeding assembly is disposed on the weighing bracket.

10. The automatic feeder according to claim 1, wherein an observation maintenance door is provided on the feed drum corresponding to a head end of the feed pipe.

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