CN220449109U - Automatic change even transportation solid feeding machine - Google Patents

Abstract

The utility model relates to the technical field of solid particle material feeding and conveying, in particular to an automatic uniform conveying solid feeder which comprises a conveying cylinder which is horizontally hung, wherein a left end cover and a right end cover are respectively arranged at the left end and the right end of the conveying cylinder in a blocking manner, a spiral conveying mechanism is arranged in a conveying cavity of the conveying cylinder, the right end of the spiral conveying mechanism movably penetrates out of the right end cover and is connected with a bidirectional driving part, a feeding bin is arranged at the top of the middle section of the conveying cylinder, a diversion conveying unit is respectively arranged at the bottom of each discharging vertical pipe at the bottom of the conveying cylinder, and each diversion conveying unit is respectively used for conveying solid particle materials to each material station in a workshop. The utility model is used in the total diversion station of the granular materials in the workshop, can realize the quantitative feeding to the material stations after the granular materials are rapidly diverted and conveyed to a plurality of material stations in the workshop, and has easy control of feeding precision.

Description

Automatic change even transportation solid feeding machine

Technical Field

The utility model relates to the technical field of solid particle material feeding and conveying, in particular to an automatic uniform conveying solid feeder.

Background

The method is characterized in that raw materials with different shapes and different forms are generally required to be prepared in advance when chemical products are generally produced in a chemical production workshop, wherein liquid materials are generally mainly pumped, the current main conveying modes of powder or granular solid materials mainly comprise pumping, mechanical conveying and closed pneumatic conveying, and the pumping and pneumatic conveying can realize quick conveying but have the problem that the feeding precision of the control materials is not easy to control, so that the method is generally not adopted when the chemical auxiliary materials serving as solid particles are conveyed and fed, and the transportation and feeding of the solid chemical raw materials are mainly realized in a mechanical conveying mode at present.

For example, in the patent document with the publication number CN204487871U, an environment-friendly chemical mixing auxiliary agent production device is disclosed, which is a general material conveying structure in practice, and the main structure comprises a jet mill, a screw feeder, a high-speed stirrer, a feeding conveyor belt, a granulator and a vibrating screen, and the whole structure is relatively large, so that relevant auxiliary agent powder materials with different purposes can be mixed in advance according to the requirements of different plastic rubber products.

However, the above-described prior art structure can only carry in one direction and in one work position when used in a workshop, and when there are a plurality of carrying work positions, high-efficiency carrying cannot be completed.

Therefore, the novel solid particle feeder is optimized and improved aiming at the problems existing in the prior art when similar solid particle materials are conveyed in a chemical production workshop, and the novel solid particle feeder can be automatically and uniformly conveyed and is used for better solving the problems existing in the prior art.

Disclosure of Invention

The utility model aims to solve one of the technical problems, and adopts the following technical scheme: the utility model provides an automatic change even transportation solid feeding machine, includes the horizontal feed cylinder of hanging the setting the left end cover, right-hand member cover are installed in the shutoff respectively to the left and right sides of feed cylinder feed cavity internally mounted of feed cylinder has spiral feeding mechanism, spiral feeding mechanism's right-hand member activity wears out to the outside of right-hand member cover and is connected with a two-way drive part feed bin is installed at the middle section top of feed cylinder the reposition of redundant personnel conveying unit is installed respectively to the bottom of each ejection of compact riser of the bottom of feed cylinder, each reposition of redundant personnel conveying unit is used for respectively to the inside each material station of workshop transport solid granule material.

In any of the above schemes, preferably, the spiral feeding mechanism comprises a horizontally arranged spiral transmission shaft, the spiral transmission shaft is coaxially arranged in the feeding cavity, two ends of the spiral transmission shaft movably penetrate through the mounting holes in the center of the left end cover and the right end cover at corresponding positions, spiral auger blades arranged along the length direction of the spiral transmission shaft are fixedly welded on the outer side wall of the spiral transmission shaft, the spiral transmission shaft drives the spiral auger blades to convey solid particles entering the feeding cavity through fixed shaft rotation, and the right end of the spiral transmission shaft is connected with the output end of the bidirectional driving component.

In any of the above schemes, preferably, the bidirectional driving component comprises a motor frame fixedly installed at the outer end face of the right end cover, a servo bidirectional motor is installed in the motor frame, and a motor shaft of the servo bidirectional motor is coaxially and fixedly connected with the right end of the screw transmission shaft through a coupler.

In any of the above schemes, preferably, the split-flow conveying unit comprises a funnel-shaped gathering part installed at the bottom of the discharging vertical pipe, the interior of the funnel-shaped gathering part is communicated with the inner cavity of the discharging vertical pipe, a metering unit is fixedly installed at the bottom of the funnel-shaped gathering part, the bottom outlet end of the metering unit is connected with corresponding material stations in a workshop through a pumping pipeline, and a particle conveying pump and a feeding control valve are installed on the pumping pipeline.

In any of the above schemes, preferably, the metering unit includes a vertically arranged blanking cylinder, the top and the bottom of the blanking cylinder are respectively communicated with the bottom of the funnel-shaped gathering part and the top of the pumping pipeline at corresponding positions, a horizontal swinging seat is installed in the blanking cavity of the blanking cylinder, the left end of the horizontal swinging seat is movably hinged on a left end welding ear seat, an electronic metering scale is fixedly installed at the top of the horizontal swinging seat, the electronic metering scale is in signal connection with an external display, a supporting electric cylinder is arranged in the blanking cavity below the left end welding ear seat, the top of a piston rod of the supporting electric cylinder is movably hinged on an upper ear seat, the lower end of a cylinder barrel of the supporting electric cylinder is movably hinged on a lower ear seat through a connecting piece, the top of the upper ear seat is fixed at the bottom of the horizontal swinging seat, the left end of the lower ear seat is fixed on the inner wall of the horizontal swinging seat, and the supporting electric cylinder drives the swinging part of the horizontal swinging seat around the left end through controlling the expansion and contraction of the blanking seat.

In any of the above schemes, preferably, the lower part of the blanking cavity is an inverted cone space.

In any of the above schemes, it is preferable that a discharge start-stop control valve is installed on each of the discharge risers.

In any of the above embodiments, it is preferable that the screw drive shaft has a hollow steel pipe structure.

Compared with the prior art, the utility model has the following beneficial effects:

1. the utility model is used in the total diversion station of the granular materials in the workshop, can realize the quantitative feeding to the material stations after the granular materials are rapidly diverted and conveyed to a plurality of material stations in the workshop, and has easy control of feeding precision.

2. According to the utility model, when the solid particles are conveyed into each split conveying unit, the starting of the bidirectional driving component can be controlled to drive the bidirectional driving component to operate, the materials are conveyed into each split conveying unit separately or simultaneously, the external existing control system can control the quick closing of the discharge opening and closing control valve on the discharge vertical pipe according to the metering result, and the quantitative feeding is realized.

3. The material accurately metered by the metering unit can be rapidly pumped and fed to a material station in a workshop along a pumping pipeline under the action of the particle delivery pump and the feeding control valve.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. Like elements or features are generally identified by like reference numerals throughout the drawings. In the drawings, the elements or components are not necessarily drawn to scale.

FIG. 1 is a schematic diagram of an automated homogeneously transported solids feeder of the present utility model.

Fig. 2 is a partially enlarged schematic structural view of the split-flow conveying unit of the present utility model.

In the figure, 1, a material conveying cylinder; 2. a left end cover; 3. a motor frame; 4. a servo bi-directional motor; 5. a feeding bin; 6. a screw drive shaft; 7. spiral auger blades; 8. a discharge vertical pipe; 9. a funnel-shaped gathering part; 10. a right end cover; 11. a discharging opening and closing control valve; 12. a metering unit; 1201. a blanking cylinder; 1202. a blanking cavity; 1203. the left end is welded with an ear seat; 1204. a horizontal swinging seat; 1205. an electronic weighing scale; 1206. supporting an electric cylinder; 1207. a lower ear seat; 1208. an upper ear seat; 13. a pumping line; 14. a particulate delivery pump; 15. and a feeding control valve.

Detailed Description

Embodiments of the technical scheme of the present utility model will be described in detail below with reference to the accompanying drawings. The following examples are only for more clearly illustrating the technical aspects of the present utility model, and thus are merely examples, and are not intended to limit the scope of the present utility model. The specific structure of the utility model is shown in fig. 1-2.

Example 1: the utility model provides an automatic change even transportation solid feeding machine, includes that the level hangs the defeated feed cylinder 1 of setting the left end cover 2, right-hand member cover 10 are installed in the shutoff respectively to the left and right sides of defeated feed cylinder 1's defeated material chamber internally mounted has spiral conveying mechanism, spiral conveying mechanism's right-hand member activity wears out to the outside of right-hand member cover 10 and is connected with a two-way drive part a feeding storehouse 5 is installed at the middle section top of defeated feed cylinder 1 the reposition of redundant personnel conveying unit is installed respectively to the bottom of each ejection of compact riser 8 of the bottom of defeated feed cylinder 1, each reposition of redundant personnel conveying unit is used for carrying solid granule material to each material station inside the workshop respectively. The automatic uniform transportation solid feeder in the utility model utilizes the external dumping equipment to dump the solid particles of the corresponding type into the feeding bin 5 during operation, simultaneously starts the bidirectional driving part to realize spiral transportation of the materials entering the material conveying cavity, continuously feeds the materials into the corresponding diversion conveying units along the material conveying vertical pipes 8 when the materials are spirally transported to the positions of the material conveying vertical pipes 8 in the corresponding opening states, weighs a proper amount of materials under the metering action of the metering units 12, and after the weighing is finished, the external existing control system controls the material opening and closing control valve 11 at the current material conveying vertical pipes 8 to be closed, so that the feeding of the current part is finished, and after the metering of the materials at the current part is finished, the particles can be pumped to the material stations at the downstream in the workshop and pumped for feeding through the diversion conveying units.

In any of the above schemes, preferably, the spiral conveying mechanism includes a horizontally disposed spiral transmission shaft 6, the spiral transmission shaft 6 is coaxially disposed inside the conveying cavity, two ends of the spiral transmission shaft are movably penetrated out of the mounting hole in the center of the left end cover 2 and the right end cover 10 at the corresponding positions, a spiral auger blade 7 disposed along the length direction of the spiral transmission shaft 6 is welded and fixed on the outer side wall of the spiral transmission shaft 6, the spiral transmission shaft 6 drives the spiral auger blade 7 to convey solid particles entering the inside of the conveying cavity through fixed shaft rotation, and the right end of the spiral transmission shaft 6 is connected with the output end of the bidirectional driving component. The spiral conveying mechanism is mainly powered by a bidirectional driving component during operation, and when the spiral transmission shaft 6 rotates, the spiral auger blades 7 on the spiral conveying mechanism are driven to rotate along with the spiral conveying mechanism, so that the purpose of driving the materials in the corresponding conveying cavities to move along with the operation is finally achieved.

In any of the above schemes, preferably, the bidirectional driving component comprises a motor frame 3 fixedly installed at the outer end face of the right end cover 10, a servo bidirectional motor 4 is installed in the motor frame 3, and a motor shaft of the servo bidirectional motor 4 is coaxially and fixedly connected with the right end of the screw transmission shaft 6 through a coupling. The running direction of the servo bidirectional motor 4 can be controlled when the bidirectional driving component works, and the running speed of the servo bidirectional motor 4 can be controlled to realize the control of the feeding speed.

In any of the above schemes, preferably, the split-flow conveying unit includes a funnel-shaped gathering part 9 installed at the bottom of the discharging riser 8, the interior of the funnel-shaped gathering part 9 is communicated with the inner cavity of the discharging riser 8, a metering unit 12 is fixedly installed at the bottom of the funnel-shaped gathering part 9, the bottom outlet end of the metering unit 12 is connected with a corresponding material station in a workshop through a pumping pipeline 13, and a particle conveying pump 14 and a feeding control valve 15 are installed on the pumping pipeline 13. The diversion conveying unit is used for receiving solid particles falling from the discharging vertical pipe 8 at a corresponding position, the solid particles enter the funnel-shaped gathering part 9 after being discharged downwards through the discharging vertical pipe 8 and are gathered and fall into the metering unit 12, so that the materials can fall into the blanking barrel 1201 of the metering unit 12 downwards along the center of the funnel-shaped gathering part 9, the solid particles falling onto the metering unit 12 can be used for weighing, when the weighed materials reach the currently set weight, the external existing control system can control the discharging opening and closing control valve 11 at the current discharging vertical pipe 8 to be closed, the feeding is stopped in the current metering unit 12, the metered materials can be opened at the bottom of the metering unit 12 under the control action of the external system and the weighed materials can be quickly poured downwards, and accordingly the materials enter the pumping pipeline 13, and the downstream conveying and feeding are continuously completed under the action of the particle conveying pump 14.

In any of the above solutions, preferably, the metering unit 12 includes a vertically disposed blanking cylinder 1201, the top and bottom of the blanking cylinder 1201 are respectively communicated with the bottom of the funnel-shaped gathering part 9 and the top of the pumping pipeline 13 at corresponding positions, a horizontal swing seat 1204 is mounted in the blanking cavity 1202 of the blanking cylinder 1201, the left end of the horizontal swing seat 1204 is movably hinged to a left end welding ear seat 1203, an electronic metering scale 1205 is fixedly mounted at the top of the horizontal swing seat 1204, the electronic metering scale 1205 is in signal connection with an external display, a supporting electric cylinder 1206 is disposed in the blanking cavity 1202 below the left end welding ear seat 1203, the top of a piston rod of the supporting electric cylinder 1206 is movably hinged to an upper ear seat 1208, the lower end of the supporting electric cylinder 1206 is movably hinged to a lower ear seat 1207 through a connecting piece, the top of the upper ear seat 1208 is fixed to the bottom of the horizontal swing seat 1204, the left end of the lower ear seat 1207 is fixed to the inner wall of the blanking cavity 1202, and the supporting electric cylinder 1206 is driven to swing around the left end of the supporting electric cylinder 1206 by controlling the supporting electric cylinder to swing. The metering unit 12 is operated to receive the solid particles falling from above by the blanking cylinder 1201, and the solid particles are metered and weighed when falling on the upper part of the electronic metering scale 1205, so as to achieve the purpose of rapid metering, and when the metering reaches the standard, the supporting cylinder 1206 in the extended state is controlled to retract, and the right end of the whole electronic metering scale 1205 is driven to swing downwards at this time, so that the particles directly fall to the lower part of the blanking cavity 1202 under the action of gravity component and are pumped down through the pumping pipeline 13.

Example 2: the utility model provides an automatic change even transportation solid feeding machine, includes that the level hangs the defeated feed cylinder 1 of setting the left end cover 2, right-hand member cover 10 are installed in the shutoff respectively to the left and right sides of defeated feed cylinder 1's defeated material chamber internally mounted has spiral conveying mechanism, spiral conveying mechanism's right-hand member activity wears out to the outside of right-hand member cover 10 and is connected with a two-way drive part a feeding storehouse 5 is installed at the middle section top of defeated feed cylinder 1 the reposition of redundant personnel conveying unit is installed respectively to the bottom of each ejection of compact riser 8 of the bottom of defeated feed cylinder 1, each reposition of redundant personnel conveying unit is used for carrying solid granule material to each material station inside the workshop respectively.

In any of the above schemes, preferably, the spiral conveying mechanism includes a horizontally disposed spiral transmission shaft 6, the spiral transmission shaft 6 is coaxially disposed inside the conveying cavity, two ends of the spiral transmission shaft are movably penetrated out of the mounting hole in the center of the left end cover 2 and the right end cover 10 at the corresponding positions, a spiral auger blade 7 disposed along the length direction of the spiral transmission shaft 6 is welded and fixed on the outer side wall of the spiral transmission shaft 6, the spiral transmission shaft 6 drives the spiral auger blade 7 to convey solid particles entering the inside of the conveying cavity through fixed shaft rotation, and the right end of the spiral transmission shaft 6 is connected with the output end of the bidirectional driving component.

The spiral conveying mechanism is mainly powered by a bidirectional driving component during operation, and when the spiral transmission shaft 6 rotates, the spiral auger blades 7 on the spiral conveying mechanism are driven to rotate along with the spiral conveying mechanism, so that the purpose of driving the materials in the corresponding conveying cavities to move along with the operation is finally achieved.

In any of the above schemes, preferably, the bidirectional driving component comprises a motor frame 3 fixedly installed at the outer end face of the right end cover 10, a servo bidirectional motor 4 is installed in the motor frame 3, and a motor shaft of the servo bidirectional motor 4 is coaxially and fixedly connected with the right end of the screw transmission shaft 6 through a coupling.

The running direction of the servo bidirectional motor 4 can be controlled when the bidirectional driving component works, and the running speed of the servo bidirectional motor 4 can be controlled to realize the control of the feeding speed.

In any of the above schemes, preferably, the split-flow conveying unit includes a funnel-shaped gathering part 9 installed at the bottom of the discharging riser 8, the interior of the funnel-shaped gathering part 9 is communicated with the inner cavity of the discharging riser 8, a metering unit 12 is fixedly installed at the bottom of the funnel-shaped gathering part 9, the bottom outlet end of the metering unit 12 is connected with a corresponding material station in a workshop through a pumping pipeline 13, and a particle conveying pump 14 and a feeding control valve 15 are installed on the pumping pipeline 13.

The diversion conveying unit is used for receiving solid particles falling from the discharging vertical pipe 8 at a corresponding position, the solid particles enter the funnel-shaped gathering part 9 after being discharged downwards through the discharging vertical pipe 8 and are gathered and fall into the metering unit 12, so that the materials can fall into the blanking barrel 1201 of the metering unit 12 downwards along the center of the funnel-shaped gathering part 9, the solid particles falling onto the metering unit 12 can be used for weighing, when the weighed materials reach the currently set weight, the external existing control system can control the discharging opening and closing control valve 11 at the current discharging vertical pipe 8 to be closed, the feeding is stopped in the current metering unit 12, the metered materials can be opened at the bottom of the metering unit 12 under the control action of the external system and the weighed materials can be quickly poured downwards, and accordingly the materials enter the pumping pipeline 13, and the downstream conveying and feeding are continuously completed under the action of the particle conveying pump 14.

In any of the above solutions, preferably, the metering unit 12 includes a vertically disposed blanking cylinder 1201, the top and bottom of the blanking cylinder 1201 are respectively communicated with the bottom of the funnel-shaped gathering part 9 and the top of the pumping pipeline 13 at corresponding positions, a horizontal swing seat 1204 is mounted in the blanking cavity 1202 of the blanking cylinder 1201, the left end of the horizontal swing seat 1204 is movably hinged to a left end welding ear seat 1203, an electronic metering scale 1205 is fixedly mounted at the top of the horizontal swing seat 1204, the electronic metering scale 1205 is in signal connection with an external display, a supporting electric cylinder 1206 is disposed in the blanking cavity 1202 below the left end welding ear seat 1203, the top of a piston rod of the supporting electric cylinder 1206 is movably hinged to an upper ear seat 1208, the lower end of the supporting electric cylinder 1206 is movably hinged to a lower ear seat 1207 through a connecting piece, the top of the upper ear seat 1208 is fixed to the bottom of the horizontal swing seat 1204, the left end of the lower ear seat 1207 is fixed to the inner wall of the blanking cavity 1202, and the supporting electric cylinder 1206 is driven to swing around the left end of the supporting electric cylinder 1206 by controlling the supporting electric cylinder to swing.

The metering unit 12 is operated to receive the solid particles falling from above by the blanking cylinder 1201, and the solid particles are metered and weighed when falling on the upper part of the electronic metering scale 1205, so as to achieve the purpose of rapid metering, and when the metering reaches the standard, the supporting cylinder 1206 in the extended state is controlled to retract, and the right end of the whole electronic metering scale 1205 is driven to swing downwards at this time, so that the particles directly fall to the lower part of the blanking cavity 1202 under the action of gravity component and are pumped down through the pumping pipeline 13.

In any of the above embodiments, preferably, a lower portion of the blanking cavity 1202 is an inverted cone-shaped space.

The inverted cone-shaped space can better ensure the downward blanking of the granular materials and ensure the smoothness of blanking.

In any of the above embodiments, it is preferable that a discharge opening/closing control valve 11 is installed on each of the discharge risers 8.

The remote control or manual opening of the discharging opening and closing control valve 11 can realize the opening and closing control of the discharging vertical pipe 8 at the current position.

In any of the above embodiments, it is preferable that the screw drive shaft 6 has a hollow steel pipe structure.

The hollow structure can reduce the overall weight of the screw drive shaft 6 on the premise of ensuring the overall structural strength.

The specific working principle is as follows:

the automatic even transportation solid feeding machine that designs in this application utilizes outside pouring equipment to empty the solid granule material of corresponding type to feeding storehouse 5 inside at the during operation, starts two-way drive part simultaneously and can realize carrying out screw conveying to the material that enters into the material conveying intracavity portion.

When the material is spirally conveyed to the position of the discharging vertical pipe 8 in the corresponding opening state, the granular material can be continuously conveyed to the corresponding diversion conveying unit along the discharging vertical pipe 8, a proper amount of material is weighed under the metering action of the metering unit 12, the discharging opening and closing control valve 11 at the current discharging vertical pipe 8 is controlled to be closed by the external existing control system after weighing is finished, so that the feeding of the current part is finished, and after the metering of the material at the current part is finished, the granular material can be pumped to a material station at the downstream in a workshop through the diversion conveying unit and the feeding is pumped.

The utility model is used in the total diversion station of the granular materials in the workshop, can realize the quantitative feeding to the material stations after the granular materials are rapidly diverted and conveyed to a plurality of material stations in the workshop, and has easy control of feeding precision; when the solid particles are conveyed into each split conveying unit, the starting of the bidirectional driving component can be controlled to drive the bidirectional driving component to operate, the materials are conveyed into each split conveying unit separately or simultaneously, the external existing control system can control the quick closing of the discharge opening and closing control valve 11 on the discharge vertical pipe 8 according to the metering result, and the quantitative feeding is realized; the material accurately metered by the metering unit 12 can be rapidly pumped and fed to a material station in a workshop along the pumping pipeline 13 under the action of the particle delivery pump 14 and the feeding control valve 15.

The above embodiments are only for illustrating the technical solution of the present utility model, and not for limiting the same; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the corresponding technical solutions; any alternative modifications or variations to the embodiments of the present utility model will fall within the scope of the present utility model for those skilled in the art.

The present utility model is not described in detail in the present application, and is well known to those skilled in the art.

Claims (8)

1. An automatic change even transportation solid feeding machine which characterized in that: the feeding device comprises a feeding barrel which is hung horizontally, wherein a left end cover and a right end cover are respectively plugged and mounted at the left end and the right end of the feeding barrel, a spiral feeding mechanism is mounted in a feeding cavity of the feeding barrel, the right end of the spiral feeding mechanism movably penetrates out to the outer side of the right end cover and is connected with a bidirectional driving component, a feeding bin is mounted at the top of the middle section of the feeding barrel, a diversion conveying unit is mounted at the bottom of each discharging vertical pipe at the bottom of the feeding barrel, and each diversion conveying unit is used for conveying solid particles to each material station in a workshop.

2. An automated uniform transport solids feeder according to claim 1 wherein: the spiral conveying mechanism comprises a horizontally arranged spiral transmission shaft, the spiral transmission shaft is coaxially arranged in the conveying cavity, two ends of the spiral transmission shaft movably penetrate through a mounting hole in the center of the left end cover and the right end cover at corresponding positions, spiral auger blades arranged along the length direction of the spiral transmission shaft are fixedly welded on the outer side wall of the spiral transmission shaft, the spiral transmission shaft drives the spiral auger blades to convey solid particles entering the conveying cavity through fixed shaft rotation, and the right end of the spiral transmission shaft is connected with the output end of the bidirectional driving component.

3. An automated homogeneously transported solids feeder as defined in claim 2, wherein: the bidirectional driving component comprises a motor frame fixedly arranged at the outer end face of the right end cover, a servo bidirectional motor is arranged in the motor frame, and a motor shaft of the servo bidirectional motor is coaxially and fixedly connected with the right end of the screw transmission shaft through a coupler.

4. An automated uniform transport solids feeder according to claim 3 wherein: the split-flow conveying unit comprises a funnel-shaped gathering part arranged at the bottom of the discharging vertical pipe, the interior of the funnel-shaped gathering part is communicated with the inner cavity of the discharging vertical pipe, a metering unit is fixedly arranged at the bottom of the funnel-shaped gathering part, the bottom outlet end of the metering unit is connected with a corresponding material station in a workshop through a pumping pipeline, and a particle conveying pump and a feeding control valve are arranged on the pumping pipeline.

5. An automated homogeneously transporting solid feed machine as claimed in claim 4, wherein: the metering unit comprises a vertically arranged blanking barrel, the top and the bottom of the blanking barrel are respectively communicated with the bottom of the funnel-shaped gathering part at the corresponding position and the top of the pumping pipeline, a horizontal swinging seat is arranged in a blanking cavity of the blanking barrel, the left end of the horizontal swinging seat is movably hinged to a left end welding lug seat, an electronic metering scale is fixedly arranged at the top of the horizontal swinging seat and is in signal connection with an external display, a supporting electric cylinder is arranged in the blanking cavity below the left end welding lug seat, the top of a piston rod of the supporting electric cylinder is movably hinged to an upper lug seat, the lower end of a cylinder barrel of the supporting electric cylinder is movably hinged to a lower lug seat through a connecting piece, the top of the upper lug seat is fixed to the bottom of the horizontal swinging seat, the left end of the lower lug seat is fixed to the inner wall of the blanking cavity, and the supporting electric cylinder drives the horizontal swinging seat to swing around the hinged part of the left end through controlling the telescopic driving of the supporting electric cylinder.

6. An automated homogeneously transporting solid feed machine as claimed in claim 5, wherein: the lower part of the blanking cavity is an inverted cone-shaped space.

7. An automated uniform transport solids feeder according to claim 6 wherein: and each discharging vertical pipe is provided with a discharging start-stop control valve.

8. An automated uniform transport solids feeder according to claim 7 wherein: the spiral transmission shaft adopts a built-in hollow steel pipe structure.