CN220722690U - Portable feeding structure - Google Patents

Abstract

The utility model provides a portable feeding structure, which comprises: the novel air blowing device comprises a conveying belt I, a guide bin, a sealing plate, a ventilation shell, a main body, lifting columns and an air blowing head, wherein the guide bin is arranged on the right side of the conveying belt I, the main body is arranged on the outer side of the guide bin, a cutting bin is arranged at the upper end of the left side of the main body, the ventilation shell is arranged at the upper end of the cutting bin, a group of sliding grooves are formed in the middle positions of the front side and the rear side of the main body, a connecting plate is arranged in the sliding grooves, and a top plate is arranged at the upper end of the connecting plate. Through using conveyer belt one, can lead the material of sending the inside of chamber one and send the chamber two through using fly leaf and leading, can carry out the vertical guide to the material of sending the second derivation of area, through using ventilation shell and blowing head, can blow off the dust in the material outside of the inside material of guide silo, through using push pedal and electric jar, can push away to the upper end of conveyer belt to the material of fly leaf upper end.

Description

Portable feeding structure

Technical Field

The utility model belongs to the technical field of machine tool machining of aviation accessories, and relates to a portable feeding structure.

Background

A portable feeding device is a device for transferring raw materials or products from one location to another. Its design purpose is to improve production efficiency and reduce the human cost, makes the production process more high-efficient and convenient. However, portable feeding devices have some problems and drawbacks, including the inability to feed at different heights.

Firstly, the portable feeding equipment is usually designed according to a specific height, and cannot flexibly adapt to the feeding requirements of different heights. If the apparatus is to be used with different levels of loading, additional adjustments or changes in the apparatus settings may be required, which would increase the complexity of the operation and the time costs. This is a significant inconvenience for lines that require frequent replacement of loading locations or handling of products of different heights.

Secondly, when the portable feeding equipment is used for feeding materials at different heights, potential safety hazards possibly exist. If the equipment is not provided with proper safety measures and protection devices, accidents in the feeding process can be caused, and personnel injury or equipment damage can be caused. Therefore, when feeding materials at different heights by using the portable feeding equipment, proper safety measures, such as arranging guard rails, limiting the feeding height and the like, must be taken.

In addition, when portable feeding equipment carries out not co-altitude material loading, still probably has the problem that production efficiency is low. Due to design constraints of the apparatus, more time and operating steps may be required to complete the loading tasks at different heights. This will lead to an increase in downtime of the production line and a decrease in production efficiency, thereby affecting the smooth progress of the whole production process, and therefore, a convenient feeding structure is now needed to solve the above problems.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model aims to provide a portable feeding structure which solves the problems in the background art.

The utility model is realized by the following technical scheme: portable material loading structure includes: conveyer belt one, guide silo, closing plate, ventilation shell, main part, lifting column, roof, connecting plate, spout, conveyer belt two, fly leaf, backing plate, guide send chamber one, guide send chamber two, electric jar, push pedal and blow the head, its characterized in that: a guide bin is arranged on the right side of the conveyor belt;

the guide bin is characterized in that a main body is arranged on the outer side of the guide bin, a cutting bin is arranged at the upper end of the left side of the main body, a ventilation shell is arranged at the upper end of the cutting bin, a group of sliding grooves are formed in the middle positions of the front side and the rear side of the main body, a connecting plate is arranged in each sliding groove, a top plate is arranged at the upper end of each connecting plate, a lifting column is arranged at the lower end of the left side of each top plate, and a movable plate is arranged at the inner side of each connecting plate;

the movable plate upper end is equipped with the backing plate, guide chamber right side is equipped with and leads and send chamber one, guide chamber one right side upper end is equipped with and leads and send chamber two, guide chamber two lower extreme right sides is equipped with the push pedal, the push pedal right side is equipped with the electric jar, guide chamber two upper end right sides is equipped with the conveyer belt two, guide chamber upper end is equipped with the blowing head.

As a preferable implementation mode, the cross section length of the conveyor belt is larger than that of the guide bin, a bottom cavity is formed in the lower end of the right side of the conveyor belt, the cross section depth of the bottom cavity is consistent with the cross section height of the movable plate, and materials in the guide cavity can be guided through the conveyor belt.

As a preferable implementation mode, the cross section length and width of the movable plate are the same as the cross section length and width length of the guide cavity II, the outer side of the movable plate is movably sealed and embedded with the inner side of the guide cavity II, and the material guided out of the conveying belt II can be vertically guided by the movable plate and the guide cavity II.

As a preferred implementation mode, the ventilation shell penetrates through the sealing plate and the main body, the inside of the ventilation shell is communicated with a plurality of groups of blowing heads, a plurality of groups of blowing heads are connected with a group of air guide pumps, and dust outside materials in the guide bin can be blown off through the ventilation shell and the blowing heads.

As a preferred implementation mode, the second guide cavity is communicated with the first guide cavity, the first guide cavity is communicated with the inside of the guide bin, and the inner side of the connecting plate is movably embedded with the inside of the sliding groove.

As a preferable implementation mode, the height of the lower end of the push plate is consistent with that of the upper end of the conveyor belt, the two left sides of the conveyor belt are mutually communicated with the two upper end positions of the guide cavity, and materials at the upper end of the movable plate can be pushed to the upper end of the conveyor belt through the push plate and the electric cylinder.

After the technical scheme is adopted, the utility model has the beneficial effects that: through using conveyer belt one, can lead the material of sending the inside of chamber one and send the chamber two through using fly leaf and leading, can carry out the vertical guide to the material of sending the second derivation of area, through using ventilation shell and blowing head, can blow off the dust in the material outside of the inside material of guide silo, through using push pedal and electric jar, can push away to the upper end of conveyer belt to the material of fly leaf upper end.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic structural view of a portable feeding structure of the present utility model;

FIG. 2 is a right-side view of the inside of a movable plate in a portable feeding structure according to the present utility model;

FIG. 3 is a front view of a connection between a first guide cavity and a second guide cavity in a portable feeding structure according to the present utility model;

FIG. 4 is a right-side view of the inside of a guide bin in a portable feeding structure;

in the figure: 100-conveyor belt I, 110-guide bin, 120-sealing plate, 130-ventilation shell, 140-main body, 150-lifting column, 160-top plate, 170-connecting plate, 180-chute, 190-conveyor belt II, 200-movable plate, 210-backing plate, 220-guide cavity I, 230-guide cavity II, 240-electric cylinder, 250-push plate and 260-blowing head.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, a portable feeding structure includes: conveyor belt one 100, guide bin 110, closing plate 120, ventilation shell 130, main part 140, lift post 150, roof 160, connecting plate 170, spout 180, conveyor belt two 190, fly leaf 200, backing plate 210, lead and send chamber one 220, lead and send chamber two 230, electric jar 240, push pedal 250 and blow head 260, its characterized in that: a guide bin 110 is arranged on the right side of the first conveyor belt 100;

the outer side of the guide bin 110 is provided with a main body 140, the upper end of the left side of the main body 140 is provided with a cutting bin, the upper end of the cutting bin is provided with a ventilation shell 130, the middle positions of the front side and the rear side of the main body 140 are provided with a group of sliding grooves 180, the inside of each sliding groove 180 is provided with a connecting plate 170, the upper end of each connecting plate 170 is provided with a top plate 160, the lower end of the left side of each top plate 160 is provided with a lifting column 150, and the inner side of each connecting plate 170 is provided with a movable plate 200;

the upper end of the movable plate 200 is provided with a base plate 210, the right side of the guide bin 110 is provided with a first guide cavity 220, the right upper end of the first guide cavity 220 is provided with a second guide cavity 230, the right side of the lower end of the second guide cavity 230 is provided with a push plate 250, the right side of the push plate 250 is provided with an electric cylinder 240, the right side of the upper end of the second guide cavity 230 is provided with a second conveyor belt 190, and the upper end of the guide bin 110 is provided with a blowing head 260.

The cross section length of the first conveyor belt 100 is greater than that of the guide bin 110, a bottom cavity is formed in the lower end of the right side of the first conveyor belt 100, the cross section depth of the bottom cavity is identical to that of the movable plate 200, and materials in the first guide cavity 220 can be guided through the first conveyor belt 100.

The length and width of the cross section of the movable plate 200 are the same as those of the second guide cavity 230, the outer side of the movable plate 200 is movably and hermetically embedded with the inner side of the second guide cavity 230, and the materials guided out of the second conveyor belt 190 can be vertically guided by the movable plate 200 and the second guide cavity 230.

The ventilation shell 130 penetrates through the sealing plate 120 and the main body 140, the inside of the ventilation shell 130 is communicated with a plurality of groups of blowing heads 260, a group of air guide pumps are connected to the upper ends of the groups of blowing heads 260, and dust outside materials in the guide bin 110 can be blown off through the ventilation shell 130 and the blowing heads 260.

The second guide cavity 230 is communicated with the first guide cavity 220, the inside of the first guide cavity 220 is communicated with the inside of the guide bin 110, and the inner side of the connecting plate 170 is movably embedded with the inside of the sliding groove 180.

The height of the lower end of the push plate 250 is consistent with that of the upper end of the first conveyor belt 100, the left side of the second conveyor belt 190 is communicated with the upper end of the second guide cavity 230, and materials at the upper end of the movable plate 200 can be pushed to the upper end of the first conveyor belt 100 through the push plate 250 and the electric cylinder 240.

Referring to fig. 1-3, as a first embodiment of the present utility model: to solve the problem that if the equipment is required to be used under the condition of feeding at different heights, additional adjustment or change of equipment setting may be required, which increases the complexity of operation and time cost, firstly, a worker guides the material to be processed of the aircraft accessory machine tool to the upper end of the second guide cavity 230 through the second conveyor 190, when the material is located at the upper end of the second guide cavity 230, the worker receives the bearing force of the movable plate 200 and the backing plate 210, then the worker activates the two sets of lifting columns 150, so that the lifting columns 150 shrink and simultaneously drive the top plate 160 and the connecting plate 170 to move downwards, the connecting plate 170 drives the movable plate 200 to move downwards at the inner side of the chute 180, then when the movable plate 200 moves downwards into the bottom cavity, the electric cylinder 240 drives the push plate 250 to move from right to left, and pushes the material to be processed of the aircraft accessory machine tool to be processed to the upper end of the right side of the first conveyor 100, and then the material to be processed of the aircraft accessory machine tool can be fed at different heights by activating the first conveyor 100.

Referring to fig. 1-4, as a second embodiment of the present utility model: based on the above description, further, since the material of the machine tool for aircraft parts to be processed is a high precision mechanism, when dust is attached to the surface of the machine tool during the feeding process, the manufacturing rigidity and the manufacturing quality of the material can be affected, and after the external rotor blower is connected with the ventilation shell 130 in a sealing manner, the worker can introduce the external air into the ventilation head 260 from the ventilation shell 130 and rapidly spray the high-pressure air through the ventilation head 260, thereby ensuring the cleaning of the material of the machine tool for aircraft parts to be processed.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (6)

1. Portable material loading structure includes: conveyor belt one (100), guide silo (110), closing plate (120), ventilation shell (130) and hair (260) of blowing, its characterized in that: a guide bin (110) is arranged on the right side of the first conveyor belt (100);

the automatic feeding device is characterized in that a main body (140) is arranged on the outer side of the guide bin (110), a cutting bin is arranged at the upper end of the left side of the main body (140), a ventilation shell (130) is arranged at the upper end of the cutting bin, a group of sliding grooves (180) are formed in the middle positions of the front side and the rear side of the main body (140), a connecting plate (170) is arranged in the sliding grooves (180), a top plate (160) is arranged at the upper end of the connecting plate (170), a lifting column (150) is arranged at the lower end of the left side of the top plate (160), and a movable plate (200) is arranged on the inner side of the connecting plate (170);

the movable plate (200) upper end is equipped with backing plate (210), guide chamber (110) right side is equipped with and leads and send chamber one (220), guide chamber one (220) right side upper end is equipped with and leads and send chamber two (230), guide chamber two (230) lower extreme right side is equipped with push pedal (250), push pedal (250) right side is equipped with electric jar (240), guide chamber two (230) upper end right side is equipped with conveyer belt two (190), guide chamber (110) upper end is equipped with blowing head (260).

2. The portable feeding structure according to claim 1, wherein: the cross section length of the first conveyor belt (100) is greater than that of the guide bin (110), a bottom cavity is formed in the lower end of the right side of the first conveyor belt (100), and the cross section depth of the bottom cavity is consistent with the cross section height of the movable plate (200).

3. The portable feeding structure according to claim 1, wherein: the length and the width of the cross section of the movable plate (200) are the same as those of the second guide cavity (230), and the outer side of the movable plate (200) is movably sealed and embedded with the inner side of the second guide cavity (230).

4. The portable feeding structure according to claim 1, wherein: the ventilation shell (130) penetrates through the sealing plate (120) and the main body (140), the inside of the ventilation shell (130) is communicated with a plurality of groups of air blowing heads (260), and a plurality of groups of air blowing heads (260) are connected with a group of air guide pumps.

5. The portable feeding structure according to claim 1, wherein: the second guide cavity (230) is communicated with the first guide cavity (220), the inside of the first guide cavity (220) is communicated with the inside of the guide bin (110), and the inside of the connecting plate (170) is movably embedded with the inside of the sliding groove (180).

6. The portable feeding structure according to claim 1, wherein: the height of the lower end of the push plate (250) is consistent with that of the upper end of the first conveyor belt (100), and the left side of the second conveyor belt (190) is communicated with the upper end of the second guide cavity (230).