CN220350090U - Aggregate component for diode production and material box thereof - Google Patents

Abstract

The utility model discloses an aggregate component for diode production and a material box thereof, which comprises a support component; comprises a hydraulic rod, a first rod sleeve and a second rod sleeve sleeved on two ends of the hydraulic rod; and, an aggregate assembly; comprises a collecting hopper, a spiral disc welded on the inner wall of the collecting hopper, and a collecting pipe welded on the upper side wall of the collecting hopper; a material box; the upper side wall of the base is welded with a support column, and the support column is connected with the bottom side wall of the material box through an electric rotary connector; and the universal wheel is assembled on the bottom side wall of the base.

Description

Aggregate component for diode production and material box thereof

Technical Field

The utility model relates to the technical field of diode production equipment, in particular to an aggregate component for diode production and a material box thereof.

Background

The diode is now the most important accessory in electronic technology, the quality of the diode plays a decisive role in electronic technology equipment, and the quality and production speed of the diode are determined by the production equipment, so that the performance of the production equipment for the diode is also extremely important in the electronic technology industry, and an aggregate component and an aggregate box for collecting raw materials of the diode are included.

However, the existing collecting assembly for collecting diode raw materials adopts a collecting box to store the diode raw materials, the collecting box is arranged at the tail end of a conveying belt, and materials on the conveying belt fall into the collecting box at the moment, so that the diode raw materials are easy to be damaged due to the fact that the raw materials are thrown in from a high place in the process;

at present, a material box for containing diode raw materials is used for containing raw materials, a plastic frame is used for containing raw materials, but the material box can only be used for centralized storage, and can not be used for classifying and containing different raw materials, if the material box is required to be classified, the material box can only be used for carrying out the classification by adopting a mode that a plurality of frame bodies are mutually alternated and stacked, and the material box is complex in procedure and delays the production progress.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the utility model and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description summary and in the title of the application, to avoid obscuring the purpose of this section, the description summary and the title of the utility model, which should not be used to limit the scope of the utility model.

The utility model has been made in view of the above-mentioned problem that the existing aggregate assembly for diode production uses an aggregate box to store diode raw materials, and the aggregate box is placed at the end of a conveyor belt, at which time the materials on the conveyor belt will fall into the aggregate box, and this process will cause the phenomenon that the raw materials are thrown in from a high place to easily damage the diode raw materials.

It is therefore an object of the present utility model to provide an aggregate assembly for diode production.

In order to solve the technical problems, the utility model provides the following technical scheme: an aggregate assembly for diode production, comprising, a support assembly; comprises a hydraulic rod, a first rod sleeve and a second rod sleeve sleeved on two ends of the hydraulic rod; and, an aggregate assembly; comprises a collecting hopper, a spiral disc welded on the inner wall of the collecting hopper, and a collecting pipe welded on the upper side wall of the collecting hopper.

The utility model has the following beneficial effects:

1. through the height that utilizes the hydraulic stem on the supporting component adjustable subassembly that gathers materials, and then make its different grade conveyer belt of adaptation, and the collecting hopper in the subassembly that gathers materials passes through collecting pipe and conveyer belt's discharge port assorted, and then reaches the effect of buffering unloading, avoids directly dropping the phenomenon that causes the damage of diode raw materials to take place, simultaneously, utilizes the spiral disc in the collecting hopper can form decurrent rotation force when the pan feeding, avoids the occurence of blockage phenomenon of pan feeding process.

2. The four material tanks in the material box can be used for collecting the diode raw materials of four different types or the same type, wherein the angle of the material tank on the material box can be adjusted through the electric rotary connector on the base at the bottom of the material box when the diode raw materials of different types are collected, so that the angle corresponds to the tail end of the conveying belt, and the effect of classified storage is achieved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are required to be used in the description of the embodiments will be briefly described below.

FIG. 1 is a schematic view of the aggregate assembly and its cartridge for diode production according to the present utility model.

Fig. 2 is a cross-sectional view of the aggregate assembly and its cartridge for diode production of the present utility model.

Fig. 3 is an exploded view of the aggregate assembly and its cartridge for diode production of the present utility model.

Fig. 4 is a schematic view of the aggregate assembly and support assembly of the present utility model.

Fig. 5 is an exploded view of the material box according to the present utility model.

100. A material box; 101. a detection assembly; 101a, a pressure sensor; 101b, abutment plates; 102. a central slot; 103. a material tank; 104. a clamping groove; 105. an electric telescopic rod; 106. a partition plate; 200. a base; 201. a support column; 202. an electrical rotary connector; 300. a universal wheel; 400. a support assembly; 401. a hydraulic rod; 402. a first sleeve; 403. a second sleeve; 500. an aggregate assembly; 501. a collecting hopper; 502. a spiral disc; 503. a collecting pipe; 504. a rubber plate.

Detailed Description

In order that the above-recited objects, features and advantages of the present utility model will become more readily apparent, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

Example 1

Referring to fig. 1, in a first embodiment of the present utility model, an aggregate assembly 500 and a support assembly 400 for diode production are provided, which avoid the occurrence of an unfit phenomenon when the aggregate assembly 500 collects diode raw materials on conveyor belts with different heights, and simultaneously, the aggregate assembly 500 also serves to buffer the blanking and avoid the blanking blockage phenomenon.

Specifically, the aggregate assembly 500 and the three support assemblies 400 at the bottom thereof are a group, and each group of aggregate assemblies 500 and the corresponding support assemblies 400 are provided with four aggregate assemblies 500, which are respectively disposed above the four material slots 103 of the material box 100.

Further, the support assembly 400 includes a hydraulic rod 401, and a top side wall of the hydraulic rod 401 is connected with a bottom side wall of a collecting hopper 501 in the collecting assembly 500 through a first rod sleeve 402, and a bottom side wall of the hydraulic rod 401 is connected with an upper side wall of the material box 100 through a second rod sleeve 403, a spiral disc 502 is welded on an inner wall of the collecting hopper 501, and the upper side wall of the collecting hopper 501 is opposite to a tail end of the diode raw material conveying belt through a collecting pipe 503, and a rubber plate 504 is bonded on a top side wall of the collecting pipe 503.

The operation process comprises the following steps: when in use, the height of the aggregate assembly 500 on the top end of the aggregate assembly 500 can be adjusted through the hydraulic column 401 in the support assembly 400, so that the top side wall of the aggregate tube 503 on the aggregate assembly 500 is in clearance with the bottom side wall of the diode raw material conveying belt, the effect of improving the aggregate assembly 500 to be applicable to production running water conveying belts with different heights is achieved, then when aggregate work is carried out, raw materials are input to the tail end by the diode raw material conveying belt, then enter the aggregate tube 503 and slide into the aggregate hopper 501 downwards along the aggregate tube 503, and at that time, a spiral downward sliding force can be formed under the action of the spiral disc 502 in the aggregate hopper 501, so that the aggregate work is ensured to be completed, and blockage is avoided.

Example 2

Referring to fig. 2, for a second implementation of the present utility model, this embodiment differs from the first embodiment in that: the material box 100, four ends of the material box 100 can respectively classify and store different types of diode raw materials, the middle chamber can play a role in temporarily expanding a certain side storage area, and the detection component 101 in the bottom of the four-end storage area can detect the weight of the materials falling into the area at any time, so that the phenomenon of excessive storage and accumulation of the diode raw materials is avoided.

Specifically, the material box 100 is in a cross structure, the four ends of the material box 100 are provided with material grooves 103, the center of the material box 100 is provided with a center groove 102, meanwhile, the joint between the center groove 102 and the material grooves 103 is connected with a partition plate 106 in a clamping way through a clamping groove 104, two sides of the inner wall of the bottom of the material groove 103 are connected with the bottom side wall of a propping plate 101b in the detection assembly 101 through an electric telescopic rod 105, and the bottom side wall of the center of the propping plate 101b is propped against the pressure sensor 101 a.

The rest of the structure is the same as in embodiment 1.

The operation process comprises the following steps: the material tank 103 in the material box 100 can collect the diode raw materials passing through the aggregate component 500 in a concentrated manner, the four different types of raw materials can be respectively collected in a classified manner, the central tank 102 in the center of the material tank 103 can assist the material tank 103 in enlarging a collecting chamber, the accommodating chamber is improved, when the accommodating chamber is enlarged, only the partition plate 106 is required to be pulled out, the pressure sensor 101a in the detection component 101 can weigh the diode raw materials accommodated on the upper side wall of the abutting plate 101b, when the weight of the diode raw materials reaches a preset value, the situation that the raw materials accommodated in the material tank 103 are full and can not be accommodated continuously is judged, the data are transmitted to the computer terminal at the side of the production line through the data line, and when the diode raw materials in the material box 100 are taken out, the abutting plate 101b can be driven to rise through the extension of the electric telescopic rod 105, and then the diode raw materials placed on the diode raw materials are lifted up, so that the taking and placing work can be carried out conveniently.

Example 3

Referring to fig. 2, for a third implementation of the present utility model, this embodiment is different from the above embodiment in that: base 200 and universal wheel 300 make equipment push removal through universal wheel 300, and can ensure through base 200 that material box 100 is rotatable, guarantee categorised depositing work and can go on smoothly.

Specifically, the base 200 is provided in a plate structure, and an upper side wall of the base 200 is connected with a bottom side wall of the supporting column 201 through a bolt, and a top side wall of the supporting column 201 is connected with a bottom side wall of the material box 100 through an electric rotating connector 202, and a universal wheel 300 is mounted on the bottom side wall of the base 200.

Further, the supporting columns 201 and the material box 100 are arranged on the same axis, the four universal wheels 300 are arranged in total, the four universal wheels 300 are respectively arranged at four corners of the bottom of the base 200, and meanwhile, the universal wheels 300 are provided with brake structures.

The rest of the structure is the same as in embodiment 2.

The operation process comprises the following steps: when the material box 100 is used, the material box 100 can be pushed to a designated position by means of hand pushing and under the assistance of the universal wheel 300, then the brake pad on the universal wheel 300 is stepped down to achieve the purpose of stopping the material box 100, the material groove 103 on the outer wall of one end of the material box 100 is opposite to the tail end of the diode raw material conveying belt, when the material groove 103 is full of raw materials, the material box 100 is driven to rotate ninety degrees by the computer-controllable electric rotary connector 202 to further replace the new material groove 103 for collecting the materials, and meanwhile, the operation steps can be repeated when different types of materials are collected.

The foregoing is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, and any modification, equivalent replacement, and improvement of some of the technical features described in the foregoing embodiments are all within the scope of the present utility model.

Claims (10)

1. An aggregate assembly for diode production, characterized by: comprising the steps of (a) a step of,

a support assembly (400); comprises a hydraulic rod (401), a first rod sleeve (402) and a second rod sleeve (403) sleeved on two ends of the hydraulic rod; the method comprises the steps of,

an aggregate assembly (500); comprises a collecting hopper (501), a spiral disc (502) welded on the inner wall of the collecting hopper (501), and a collecting pipe (503) welded on the upper side wall of the collecting hopper (501).

2. An aggregate assembly for diode production as defined in claim 1, wherein: the support assemblies (400) are provided with three groups in total, and the three groups of support assemblies (400) are arranged in three of four quadrant points of the bottom of the aggregate assembly (500).

3. An aggregate assembly for diode production as claimed in claim 2, wherein: the top end side wall of the hydraulic rod (401) in the supporting assembly (400) is connected with the bottom side wall of the collecting hopper (501) in the collecting assembly (500) through a first rod sleeve (402), and the first rod sleeve (402) is connected with the bottom side wall of the collecting hopper (501) through bolts.

4. An aggregate assembly for diode production as defined in claim 1, wherein: the collecting hopper (501) in the collecting assembly (500) is arranged in a funnel-shaped structure, the small-caliber end of the collecting hopper (501) is arranged towards the material box (100), and the large-caliber end of the collecting hopper (501) is arranged upwards.

5. An aggregate assembly for diode production as defined in claim 4, wherein: the spiral disc (502) in the collecting hopper (501) is in a spiral downward structure, and the outer side edge of the spiral disc (502) is bent upwards.

6. An aggregate assembly for diode production as defined in claim 4, wherein: the collecting pipe (503) on the upper side wall of the collecting hopper (501) is arranged in a semi-cylindrical internal hollow structure, the collecting pipe (503) is arranged in an inclined upward structure, and the collecting pipe (503) and the collecting hopper (501) are mutually communicated.

7. An aggregate assembly for diode production as defined in claim 1, wherein: the top side wall of the collecting pipe (503) is adhered with a rubber plate (504), and the upper side wall of the collecting pipe (503) is arranged in a gap with the bottom side wall of the diode raw material conveying belt through the rubber plate (504).

8. A material box for diode production, its characterized in that: an aggregate assembly as claimed in any one of claims 1 to 7; the method comprises the steps of,

a material box (100); the base (200) is assembled below the material box (100), a supporting column (201) is welded on the upper side wall of the base (200), and the supporting column (201) is connected with the bottom side wall of the material box (100) through an electric rotary connector (202); the method comprises the steps of,

and the universal wheel (300), wherein the universal wheel (300) is assembled on the bottom side wall of the base (200).

9. The kit for diode production of claim 8, wherein: the material box is characterized in that a central groove (102) is formed in the center of the interior of the material box (100), material grooves (103) are formed in the front, rear, left and right four-end side walls of the central groove (102), and clamping grooves (104) are formed in the joint between the central groove (102) and the material grooves (103).

10. The kit for diode production as defined in claim 9, wherein: the bottom lateral wall of material groove (103) is inlayed and is had detection component (101), the last lateral wall and the butt board (101 b) butt of pressure sensor (101 a) in detection component (101) are connected, inlay on the bottom inner wall of the side, material groove (103) of pressure sensor (101 a) have electric telescopic handle (105), the inside joint of joint groove (104) is provided with division board (106).