CN218663789U - Variable-frequency impeller feeder - Google Patents

Abstract

The utility model discloses a frequency conversion impeller feeder relates to material and carries technical field. The utility model discloses a defeated material shell, splice frame, cooperation frame and inverter motor, one side in the defeated material shell is fixed with the swash plate, and the defeated material shell top of swash plate top is fixed with the splice frame, and the cooperation frame is including pivot and commentaries on classics board, and the pivot is rotated and is connected in the splice frame, and the week side of pivot is the annular array and is fixed with the commentaries on classics board, and one side of defeated material shell the place ahead keeping away from the splice frame is provided with inverter motor. The utility model discloses a set up defeated material shell, splice frame, cooperation frame and inverter motor, it is not convenient enough to plug up the mediation when having solved frequency conversion impeller feeder input material, and the material causes the problem that the material splashes out easily in transportation process, the utility model has the advantages of: when the variable-frequency impeller feeder inputs materials, the materials are plugged up to be conveniently dredged, and the materials can be better prevented from splashing out when being conveyed.

Description

Variable-frequency impeller feeder

Technical Field

The utility model belongs to the technical field of the material is carried, especially, relate to a frequency conversion impeller feeder.

Background

The impeller feeder is used for continuously and uniformly feeding dry powdery materials or small granular materials in an upper bin to a next mechanical tool and is a quantitative feeding mechanical tool, the general impeller feeder comprises a feed feeding frame, a shell and an impeller, when the materials in the upper feed feeding frame fall down by self weight and are filled between blades of the impeller, the materials are discharged at the lower part along with the rotation of the blades, therefore, the impeller feeder can quantitatively and continuously discharge materials, a motor used by the impeller feeder is basically a variable frequency motor, and the variable frequency motor can change the rotating speed in a variable frequency mode when working so as to change the conveying speed, but the impeller feeder still has the following defects in practical use:

when the variable-frequency impeller feeder is used for conveying materials, input materials are directly guided into the variable-frequency impeller feeder through the conveying hopper, when the variable-frequency impeller feeder is used for conveying large-size materials, the materials are easy to block in the conveying process, the conveying materials can be restarted after the variable-frequency impeller feeder is stopped and manually dredged manually, and when the variable-frequency impeller feeder is used for working, loss is easy to cause once the materials are blocked, and the variable-frequency impeller feeder is inconvenient to use;

the variable frequency impeller feeder is characterized in that materials are led out through rotation of the blades when the variable frequency impeller feeder works, in the process of leading out the materials, partial materials are easily led out in time, the materials are splashed, and in the process of splashing the materials, the materials are easily splashed out of the variable frequency impeller feeder, so that potential safety hazards and environmental pollution are caused.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a frequency conversion impeller feeder, through setting up defeated material shell, connection frame, cooperation frame and inverter motor, it is not convenient enough to plug up the mediation when having solved frequency conversion impeller feeder input material, and the material causes the problem that the material splashes out easily in transportation process.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to a frequency conversion impeller feeder, including defeated material shell, splice frame, cooperation frame and inverter motor, one side in the defeated material shell is fixed with the swash plate, the defeated material shell top of swash plate top is fixed with the splice frame, the cooperation frame is including pivot and commentaries on classics board, the pivot is rotated and is connected in the splice frame, the week side of pivot is that the annular array is fixed with the commentaries on classics board, one side of far away from the splice frame in defeated material shell the place ahead is provided with inverter motor, the during operation, the utility model discloses a defeated material shell transfer material leads the material to defeated material shell through the splice frame in, through the cooperation frame during the during operation, through rotating, prevents that the material from plugging up in the splice frame to prevent that the material from spilling out defeated material shell, produce the rotatory power of drive commentaries on classics roller through inverter motor.

Furthermore, a variable frequency speed regulator is fixed on one side, far away from the variable frequency motor, of the front side of the material conveying shell, an output frame is fixedly communicated with one side, far away from the connecting frame, of the bottom of the material conveying shell, the material conveying shell adjusts the rotating speed of the variable frequency motor through the variable frequency speed regulator on the front side of the material conveying shell, and materials in the material conveying shell are led out through the output frame.

Furthermore, the top of the material conveying shell is provided with an input port corresponding to the connecting frame, one side of the front side of the material conveying shell, which is far away from the connecting frame, is provided with a rotary hole, the material conveying shell guides the material in the connecting frame into the rotary hole through the input port, and the rotary hole is movably connected with the driving shaft.

Furthermore, the front side of the connecting frame is provided with a movable hole, the top of the connecting frame is fixed with an input hopper, the connecting frame is movably connected with the rotating frame through the movable hole, and materials are guided into the connecting frame through the input hopper.

Further, the matching frame further comprises a rotating frame, the rotating frame is fixed to the front end of the rotating shaft, the rear end portion of the rotating frame is movably connected into the movable hole, the rotating frame is rotated through rotation, the rotating plate is rotated, and materials in the connecting frame are dredged.

Furthermore, a driving shaft is fixed at the output end of the variable frequency motor, the rear end of the driving shaft is movably connected in a rotating hole, a rotating roller is fixed at the rear end of the driving shaft, the rear end of the rotating roller is rotatably connected to the rear part of the inner wall of the material conveying shell, material pushing plates are fixed on the periphery of the rotating roller in an annular array mode, and the variable frequency motor drives the rotating roller to rotate when working, drives the material pushing plates to rotate and pushes materials to move to an output frame in the material conveying shell.

The utility model discloses following beneficial effect has:

the utility model discloses a set up defeated material shell, connecting frame and cooperation frame, plug up the not convenient enough problem of mediation when having solved frequency conversion impeller feeder input material, carry great material, when causing the input to fight in and plug up, rotate the revolving rack with the hand, at the rotatory in-process of revolving rack, make the material driven fall to defeated material shell, make the material back in the input frequency conversion impeller feeder, can dredge fast, it is more convenient to dredge, it is littleer to the influence of frequency conversion impeller feeder continuous operation.

The utility model discloses a set up defeated material shell, the connection frame, cooperation frame and inverter motor, the problem that the material caused the material to splash easily in transportation process in the variable frequency impeller feeder has been solved, the scraping wings is when defeated material shell is rotatory in, make the material splash in the defeated material shell, back in spattering the connection frame, it is kept off by pivot and the commentaries on classics board of week side thereof, prevent the defeated material shell of material splash, can prevent better that the material from causing the material to splash out in transportation process in the variable frequency impeller feeder.

Drawings

FIG. 1 is a perspective view of the assembly structure of the present invention;

FIG. 2 is a perspective view of a sectional structure of a feeding shell of the present invention;

FIG. 3 is a perspective view of the connecting frame structure of the present invention;

FIG. 4 is a perspective view of the fitting frame structure of the present invention;

fig. 5 is a perspective view of the structure of the variable frequency motor of the present invention.

Reference numerals:

100. a feeding shell; 101. an input port; 102. a sloping plate; 103. a variable frequency governor; 104. hole turning; 105. outputting a frame; 200. a connecting frame; 201. a movable hole; 202. an input hopper; 300. a fitting frame; 301. a rotating shaft; 302. rotating the plate; 303. rotating the frame; 400. a variable frequency motor; 401. a drive shaft; 402. rotating the roller; 403. a material pushing plate.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Please refer to fig. 1-5, the utility model relates to a frequency conversion impeller feeder, including defeated material shell 100, the connection frame 200, cooperation frame 300 and inverter motor 400, one side in the defeated material shell 100 is fixed with swash plate 102, defeated material shell 100 is used for accepting and the material that the transfer needs carried in work, make the material that gets into in defeated material shell 100 guide the drive shaft 401 below through swash plate 102, lead the position of scraping wings 403 again, defeated material shell 100 top of swash plate 102 top is fixed with connection frame 200, connection frame 200 leads the material to defeated material shell 100 in, cooperation frame 300 includes pivot 301 and commentaries on classics board 302, pivot 301 rotates to be connected in connection frame 200, the week side of pivot 301 is the annular array and is fixed with commentaries on classics board 302, make commentaries on classics board 302 can be rotatory in connection frame 200 through pivot 301, one side of keeping away from connection frame 200 in defeated material shell 100 the place ahead is provided with inverter motor 400, inverter motor 400 is in work, the rotatory power of drive scraping wings 403 is produced.

As shown in fig. 1 and 2, a variable frequency speed governor 103 is fixed on a side of the front side of the feeding shell 100 away from the variable frequency motor 400, the driving speed of the variable frequency motor 400 during operation is adjusted by the variable frequency speed governor 103 to transport materials to be transported, an output frame 105 is fixedly communicated with a side of the bottom of the feeding shell 100 away from the connecting frame 200, and the materials transported in the feeding shell 100 are guided to the processing equipment through the output frame 105.

As shown in fig. 1 and 2, the top of the feeding shell 100 is provided with an input port 101 corresponding to the connecting frame 200, the feeding shell 100 is communicated with the connecting frame 200 through the input port 101, a rotary hole 104 is provided on the front side of the feeding shell 100 far away from the connecting frame 200, and the feeding shell 100 is movably connected with a driving shaft 401 through the rotary hole 104.

As shown in fig. 1 and 3, a movable hole 201 is formed in the front side of the connection frame 200, the connection frame 200 is movably connected to the rotating frame 303 through the movable hole 201, an input hopper 202 is fixed to the top of the connection frame 200, and materials are guided into the connection frame 200 through the input hopper 202.

As shown in fig. 1 and 4, the matching frame 300 further includes a rotating frame 303, the rotating frame 303 is fixed at the front end of the rotating shaft 301, the rear end of the rotating frame 303 is movably connected in the movable hole 201, and the connecting frame 200 is guided by the material and then drives the rotating plate 302 to rotate, so that the material falls into the material conveying shell 100, the rotating frame 303 is rotated to drive the rotating shaft 301 to rotate, and the rotating plate 302 is driven to rotate through the rotation of the rotating shaft 301, so that the material blocked in the connecting frame 200 is guided into the material conveying shell 100.

As shown in fig. 1 and 5, a driving shaft 401 is fixed at an output end of the variable frequency motor 400, the driving shaft 401 drives a rotating roller 402 to rotate by driving power generated by the variable frequency motor 400 to drive the rotating roller 402, a rear end portion of the driving shaft 401 is movably connected in the rotating hole 104, the rear end of the driving shaft 401 is fixed with the rotating roller 402, the rear end of the rotating roller 402 is rotatably connected to a rear portion of an inner wall of the material conveying shell 100, material pushing plates 403 are fixed on a circumferential side of the rotating roller 402 in an annular array, the material pushing plates 403 are driven to rotate when the rotating roller 402 rotates, and materials are pushed to be guided into the output frame 105 from the bottom of the material conveying shell 100 in a rotating process of the material pushing plates 403.

The utility model discloses a concrete theory of operation does: when the material splashing prevention device works, a material is poured into one side of the input hopper 202, so that the material falls into the connecting frame 200 and falls onto the rotating plate 302 to drive the rotating plate 302 and the rotating shaft 301 to rotate, when the rotating shaft 301 rotates, the material falls into the material conveying shell 100 and is guided to the bottom of the material conveying shell 100 by the inclined plate 102 and below the rotating roller 402, when a large material is conveyed and is blocked in the input hopper 202, the rotating frame 303 is rotated by hand, in the rotating process of the rotating frame 303, the material is driven to fall into the material conveying shell 100, after the material falls into the material conveying shell 100 by a certain amount, the variable frequency motor 400 is started, when the variable frequency motor 400 works, the driving shaft 401 is driven to rotate to drive the rotating roller 402 to rotate to drive the material pushing plate 403 to rotate, when the material pushing plate 403 rotates, the material in the material conveying shell 100 is pushed into the output frame 105, so that the material is guided into the material processing equipment through the output frame 105, when the material conveying speed needs to be changed, the rotating speed of the variable frequency motor 400 is adjusted by the variable frequency speed regulator 103, the rotating speed of the material conveying shell 100 is guided out of the material conveying shell 100, and the material conveying shell 100 is guided out of the connecting frame 302, and the material splashing prevention device 100, and the material conveying shell 100 is prevented from splashing prevention device when the connecting plate 301.

The above is only the preferred embodiment of the present invention, and the present invention is not limited thereto, and any modifications to the technical solutions recorded in the foregoing embodiments, and equivalent replacements to some of the technical features thereof, and any modifications, equivalent replacements, and improvements made belong to the protection scope of the present invention.

Claims (6)

1. The utility model provides a frequency conversion impeller feeder, includes defeated material shell (100), linking frame (200), cooperation frame (300) and inverter motor (400), its characterized in that: one side in defeated material shell (100) is fixed with swash plate (102), defeated material shell (100) top of swash plate (102) top is fixed with connection frame (200), cooperation frame (300) are including pivot (301) and commentaries on classics board (302), pivot (301) are rotated and are connected in connection frame (200), the week side of pivot (301) is the annular array and is fixed with commentaries on classics board (302), one side of defeated material shell (100) the place ahead is kept away from connection frame (200) is provided with inverter motor (400).

2. The variable frequency impeller feeder of claim 1, wherein: the variable-frequency speed regulator is characterized in that a variable-frequency speed regulator (103) is fixed on one side, away from the variable-frequency motor (400), of the front side of the material conveying shell (100), and an output frame (105) is fixedly communicated with one side, away from the connecting frame (200), of the bottom of the material conveying shell (100).

3. The variable frequency impeller feeder of claim 1, wherein: the top of the material conveying shell (100) is provided with an input port (101) corresponding to the position of the connecting frame (200), and one side of the front side of the material conveying shell (100) far away from the connecting frame (200) is provided with a rotating hole (104).

4. The variable frequency impeller feeder of claim 1, wherein: the front side of the connecting frame (200) is provided with a movable hole (201), and the top of the connecting frame (200) is fixed with an input hopper (202).

5. The variable frequency impeller feeder of claim 4, wherein: the matching frame (300) further comprises a rotating frame (303), the rotating frame (303) is fixed at the front end of the rotating shaft (301), and the rear end of the rotating frame (303) is movably connected into the movable hole (201).

6. A variable frequency impeller feeder according to claim 3 in which: the output of inverter motor (400) is fixed with drive shaft (401), the rear end swing joint of drive shaft (401) is in changeing hole (104), the rear end of drive shaft (401) is fixed with changes roller (402), the rear end of changeing roller (402) is rotated and is connected at the rear portion of defeated material shell (100) inner wall, the week side of changeing roller (402) is that the annular array is fixed with scraping wings (403).

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