CN216544066U - Prevent feeding device that builds bridge - Google Patents

Abstract

The utility model discloses a bridging-preventing feeding device, which comprises: a bin component, a feeding component and a stirring component, wherein the bin component comprises a discharge bin, the interior of the discharge bin is hollow, and is provided with a first discharge hole, the feeding component is horizontally arranged below the first discharge hole, and the feeding end of the feeding component is arranged opposite to the first discharge hole, used for conveying materials along the arrangement direction, the stirring component comprises a first stirring piece, the first stirring piece comprises a first stirring paddle, a driving piece and a limiting piece, the first stirring paddle is movably arranged in the discharging bin, and is obliquely arranged above the first discharge hole, the driving piece is provided with a fixed end and a movable end, the fixed end of the driving piece is connected with the discharge bin, the movable end is connected with the first stirring paddle, used for driving the first stirring paddle to rotate around the rotation axis of the first stirring paddle, the limiting piece is connected with the first stirring paddle, and is detachably connected with the movable end of the driving piece and used for limiting the first stirring paddle to move along the axis of the movable end of the driving piece. The utility model can solve the problem of blockage of the feeding machine.

Description

Bridging-preventing feeding device

Technical Field

The utility model relates to the technical field of feeding machines, in particular to an anti-bridging feeding device.

Background

In the plastic modification process, powder with low bulk density such as calcium carbonate and talcum powder needs to be added by a feeder, but the powder is easy to form a bridging phenomenon at a discharge port in the conveying and feeding processes.

In order to reduce or prevent the bridging phenomenon, a method of disposing a blender in the storage bin or blowing compressed air is generally adopted, for example, the application numbers are: CN 201520490702.2's the utility model patent of china, the name is a novel prevent spherical feeding mechanism of bridging, including mixer, blanking machine, extruder, be equipped with the mixer feed opening on the mixer, on the blanking machine hopper was arranged in to the mixer feed opening, be equipped with on the blanking machine and prevent the device of bridging, be equipped with spiral unloading pivot in the blanking machine, the one end of spiral unloading pivot is equipped with first motor, blanking machine output connection has the extruder, the simple science of its structural design, convenient operation prevents that the spherical feeding mechanism of bridging can effectively prevent that the bridging phenomenon from appearing in the feed. However, in such a structure, when the powder material falls vertically in the material passage from the stirring device to the feeding device, the powder material is easily compacted, agglomerated and the like in the material passage under the action of gravity, and an outlet similar to a funnel is formed in the central area, and the diameter of the outlet of the funnel in the central area is gradually reduced with the passage of time, and finally the material passage is blocked.

Therefore, a bridging-preventing feeding device is urgently needed, and the problem that in the prior art, powder is easy to form compaction and caking in a feeding channel, so that the material channel is blocked is solved.

SUMMERY OF THE UTILITY MODEL

In view of this, it is necessary to provide an anti-bridging feeding device, which solves the technical problem in the prior art that powder is easy to form compaction and agglomeration in a feeding channel, thereby causing the blockage of the material channel.

In order to achieve the technical purpose, the technical scheme of the utility model provides an anti-bridging feeding device, which comprises:

the bin assembly comprises a discharge bin, the interior of the discharge bin is hollow, and a first discharge hole is formed in the discharge bin;

the feeding assembly is horizontally arranged below the first discharge hole, and the feeding end of the feeding assembly is arranged opposite to the first discharge hole and used for conveying materials along the arrangement direction of the feeding assembly;

stirring subassembly, including first stirring piece, first stirring piece includes first stirring rake, driving piece and locating part, place in the activity of first stirring rake in go out the feed bin to the slope set up in the top of first discharge gate, the driving piece has stiff end and expansion end, the stiff end of driving piece connect in go out feed bin, expansion end connect in first stirring rake is used for the drive first stirring rake rotates around its self axis of rotation, the locating part connect in first stirring rake to can dismantle connect in the expansion end of driving piece is used for the restriction first stirring rake is followed the axis motion of the expansion end of driving piece.

Further, the feed bin subassembly still includes the baffle, place in the baffle slope go out the feed bin, and be connected in go out the inner wall of feed bin, the baffle with the inner wall that goes out the feed bin forms first discharge gate, just it reduces gradually along being close to go out the feed bin the direction cross sectional area of first discharge gate.

Furthermore, the baffle has been seted up along perpendicular its direction of setting and has been rotated the hole, the driving piece includes screw rod and first motor, the one end of screw rod is rotatable to be passed rotate the hole, first stirring rake cover is located the one end of screw rod, and can follow the axis of screw rod slides, first motor fixed connection in go out the feed bin, and its output shaft in the other end of screw rod.

Further, the locating part includes two nuts and two elastic gasket, and two nut screw thread intervals set up to all connect in the one end of screw rod, first stirring rake activity set up in two between the nut, elastic gasket set up in the nut with between the first stirring rake, and respectively the butt in the nut with first stirring rake.

Further, the stirring subassembly still includes at least one second stirring rake, the one end of second stirring rake articulate in first stirring rake to circumference sets up in keeping away from the furthest of the axis of rotation of first stirring rake.

Further, go out the feed bin and still seted up first feed inlet, the feed bin subassembly still includes the feeding storehouse, the feeding storehouse set up in go out the top of feed bin to can dismantle connect in go out the feed bin, the inside cavity in feeding storehouse to seted up the second discharge gate, the second discharge gate with first feed inlet is linked together.

Further, the stirring subassembly still includes the second stirring piece, the second stirring piece includes at least one third stirring rake and second motor, place in the third stirring rake rotates the feeding storehouse, second motor fixed connection in the feeding storehouse, and its output shaft in the third stirring rake.

Furthermore, the feeding bin is also provided with a second feeding hole for feeding and an exhaust hole for exhausting.

Furthermore, the feeding assembly comprises a pushing screw rod and a third motor, the pushing screw rod is arranged below the discharging bin, is arranged opposite to the first discharging port and is connected to the bin, the third motor is fixedly connected to the discharging bin, and an output shaft of the third motor is connected to the pushing screw rod and is used for driving the pushing screw rod to rotate around the axis of the third motor so that the material moves along the axis of the pushing screw rod.

Furthermore, the diameter of the pushing screw rod is continuously reduced along the direction far away from the output shaft of the third motor.

Compared with the prior art, the utility model has the beneficial effects that: the feeding assembly is horizontally arranged below the discharging bin and used for conveying materials along the setting direction of the feeding assembly, the first stirring paddle is obliquely arranged relative to the first discharging port and can be rotatably arranged in the discharging bin under the driving of the movable end of the driving piece and used for stirring and scattering the materials passing through the first discharging port, meanwhile, the first stirring paddle can be close to or far away from the driving piece along the axis of the movable end of the driving piece and is connected to the first stirring paddle in a limiting way and detachably connected to the movable end of the driving piece and used for limiting the first stirring paddle to move along the axis of the movable end of the driving piece, and by the structure, not only can the powder be prevented from being caked and blocked in the feeding process, but also the distance between the first stirring paddle and the movable end of the driving piece can be adjusted according to the use condition, and meanwhile, the replacement of the first stirring paddle is convenient, and the problem that the powder in the prior art is easy to form compaction and compaction in a feeding channel, The phenomenon of agglomeration, thereby causing the technical problem of blockage of material channels.

Drawings

FIG. 1 is a schematic cross-sectional structural diagram of an anti-bridging feeding device provided by an embodiment of the utility model;

fig. 2 is a cross-sectional view of a connection portion of the first motor, the screw, the first paddle, the nut, and the elastic washer according to the embodiment of the present invention.

Detailed Description

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate preferred embodiments of the utility model and together with the description, serve to explain the principles of the utility model and not to limit the scope of the utility model.

Referring to fig. 1 and 2, the utility model provides a bridge-preventing feeding device, comprising: the feed bin assembly 1, the feeding assembly 2 and the stirring assembly 3, the feed bin assembly 1 comprises a discharge bin 11, the discharge bin 11 is hollow and provided with a first discharge port, the feeding assembly 2 is horizontally arranged below the first discharge port, and the feeding end of the feeding assembly is arranged opposite to the first discharge port and used for conveying materials along the arrangement direction of the feeding assembly, the stirring assembly 3 comprises a first stirring piece 31, the first stirring piece 31 comprises a first stirring paddle 311, a driving piece 312 and a limiting piece 313, the first stirring paddle 311 is movably arranged in the discharge bin 11 and is obliquely arranged above the first discharge port, the driving piece 312 is provided with a fixed end and a movable end, the fixed end of the driving piece 312 is connected to the discharge bin 11, the movable end is connected to the first stirring paddle 311 and used for driving the first stirring paddle 311 to rotate around the rotation axis of the first stirring paddle 311, the limiting piece 313 is connected to the first stirring paddle 311 and is detachably connected to the movable end of the driving piece 312, for limiting the movement of the first paddle 311 along the axis of the movable end of the driving member 312.

It can be understood that the feeding assembly 2 is horizontally disposed below the discharging bin 11 for feeding materials along the direction of the feeding assembly 2, the first stirring paddle 311 is disposed obliquely relative to the first discharging port and can be rotatably disposed in the discharging bin 11 under the driving of the movable end of the driving element 312 for stirring and scattering the materials passing through the first discharging port, meanwhile, the first stirring paddle 311 can move close to or away from the driving element 312 along the axis of the movable end of the driving element 312, the limiting element 313 is connected to the first stirring paddle 311 and detachably connected to the movable end of the driving element 312 for limiting the movement of the first stirring paddle 311 along the axis of the movable end of the driving element 312, such a structure can not only prevent the powder from caking and blocking during the feeding process, but also can adjust the distance between the first stirring paddle 311 and the movable end of the driving element 312 according to the use situation, and at the same time, the replacement of the first stirring paddle 311 is facilitated.

As shown in fig. 1, the storage bin assembly 1 further includes a baffle 12, the baffle 12 is disposed in the discharge bin 11 in an inclined manner and is connected to the inner wall of the discharge bin 11, the baffle 12 and the inner wall of the discharge bin 11 form a first discharge hole, and the cross-sectional area of the discharge bin 11 decreases gradually along the direction close to the first discharge hole.

It can be understood that the baffle 12 is disposed obliquely and connected to the inner wall of the discharging bin 11 for forming a first discharging hole for discharging with the inner wall of the discharging bin 11.

Further, the cross sectional area of the discharging bin 11 is gradually reduced along the direction close to the first discharging port, so that the powder is prevented from being blocked inside the discharging port, and the discharging is facilitated.

As shown in fig. 1, a first feeding hole has been further opened in the discharging bin 11, the bin assembly 1 further includes a feeding bin 13, the feeding bin 13 is disposed above the discharging bin 11 and detachably connected to the discharging bin 11, the feeding bin 13 is hollow inside and is provided with a second discharging hole, and the second discharging hole is communicated with the first feeding hole.

It can be understood that the feeding bin 13 is also arranged above the discharging bin 11 in the device, so that the material storage and stirring space of the feeding device can be increased, and the device is convenient to use.

Further, in the utility model, the feeding bin 13 and the discharging bin 11 are detachably connected through a circular tube hoop, so that the feeding bin 13 and the discharging bin 11 can be conveniently detached and installed, and other structures can be replaced, which is not illustrated herein.

As shown in fig. 1, the feeding bin 13 is further opened with a second feeding hole for feeding and an exhaust hole 131 for exhausting.

Specifically, the second feed inlet that is used for throwing the material is still offered at the top in feeding storehouse 13 in this device, and gas vent 131 has still been offered to feeding storehouse 13 simultaneously, and gas vent 131 communicates with feeding storehouse 13 and the inside homogeneous phase in play feed bin 11 for the heat that produces when discharging agitating unit functions, when avoiding reinforced simultaneously, leads to the powder to spill over from the feed inlet because of the atmospheric pressure difference.

As shown in fig. 1, the feeding assembly 2 includes a pushing screw 21 and a third motor 22, the pushing screw 21 is disposed below the discharging bin 11, is disposed opposite to the first discharging port, and is connected to the bin, the third motor 22 is fixedly connected to the discharging bin 11, and an output shaft thereof is connected to the pushing screw 21 for driving the pushing screw 21 to rotate around an axis thereof, so that the material moves along the axis of the pushing screw 21.

It can be understood that the feeding assembly 2 is composed of a pushing screw 21 and a third motor 22, and the rotation of the third motor 22 drives the pushing screw 21 to rotate around its own axis, and drives the material on the pushing screw 21 to advance along the axis of the pushing screw 21.

As shown in fig. 1, the pusher screw 21 is continuously reduced in diameter in a direction away from the output shaft of the third motor 22.

It can be understood that the feeding assembly 2 adopts a conical screw, the feeding volume is reduced from large to small, and the feeding assembly has a compaction effect on materials, so that the bulk density of the materials is increased, and the materials with low bulk density are prevented from flying to generate dust and smoothly enter a subsequent extruder.

As shown in fig. 2, the baffle 12 is provided with a rotation hole along a direction perpendicular to the arrangement direction thereof, the driving member 312 includes a screw 3121 and a first motor 3122, one end of the screw 3121 rotatably passes through the rotation hole, the first stirring paddle 311 is sleeved at one end of the screw 3121 and can slide along the axis of the screw 3121, the first motor 3122 is fixedly connected to the discharging bin 11, and the output shaft thereof is connected to the other end of the screw 3121.

It is understood that the first stirring paddle 311 is connected to the output shaft of the first motor 3122 through the screw 3121 and rotates around the output shaft of the first motor 3122.

Further, the first stirring paddle 311 can slide along the axis of the screw 3121, and is used for adjusting the distance between the first stirring paddle 311 and the output shaft of the first motor 3122 according to the use condition, so as to meet the use conditions of different powders.

As shown in fig. 1 and 2, the position-limiting member 313 includes two nuts 3131 and two elastic washers 3132, the two nuts 3131 are spaced apart from each other and are connected to one end of the screw 3121, the first paddle 311 is movably disposed between the two nuts 3131, and the elastic washer 3132 is disposed between the nut 3131 and the first paddle 311 and is abutted to the nut 3131 and the first paddle 311, respectively.

It is understood that the two nuts 3131 are spaced apart from each other, and the first paddle 311 is limited between the two nuts 3131 for adjusting the position of the first paddle 311.

Further, two elastic pads 3132 are disposed corresponding to the nuts 3131 one to one and between the nuts 3131 and the first paddles 311, and the elastic force generated by the elastic pads 3132 is used to make the nuts 3131 generate a pressing force for pressing against the first paddles 311 all the time, so as to prevent the first paddles 311 from sliding.

Furthermore, a linear motion mechanism such as a hydraulic oil cylinder and a push rod motor may be used instead of driving the first stirring paddle 311 to move along the axis of the output shaft of the first motor 3122, which will not be described in detail herein.

As shown in fig. 1, the stirring assembly 3 further includes at least one second stirring paddle 32, and one end of the second stirring paddle 32 is hinged to the first stirring paddle 311 and is circumferentially disposed at the farthest end away from the rotation axis of the first stirring paddle 311.

It can be understood that the first stirring paddle 311 is hinged with at least one second stirring paddle 32 for further stirring fully and preventing powder in the bin from blocking.

Specifically, the second paddle 32 in the present invention is disposed at the farthest end away from the rotation axis of the first paddle 311 along the circumferential direction of the first paddle 311, and is disposed perpendicular to the rotation plane of the first paddle 311.

As shown in fig. 1, the stirring assembly 3 further includes a second stirring member 33, the second stirring member 33 includes at least one third stirring paddle 331 and a second motor 332, the third stirring paddle 331 is rotatably disposed in the feeding bin, the second motor 332 is fixedly connected to the feeding bin, and an output shaft thereof is connected to the third stirring paddle 331.

In the specific working process of the utility model, the feeding component 2 is horizontally arranged below the discharging bin 11 and is used for conveying materials along the arrangement direction of the feeding component 2, the first stirring paddle 311 is obliquely arranged relative to the first discharging port and can be rotatably arranged in the discharging bin 11 under the driving of the movable end of the driving piece 312 and is used for stirring and scattering materials passing through the first discharging port, meanwhile, the first stirring paddle 311 can move close to or far away from the driving piece 312 along the axis of the movable end of the driving piece 312, the limiting piece 313 is connected to the first stirring paddle 311 and is detachably connected to the movable end of the driving piece 312 and is used for limiting the first stirring paddle 311 to move along the axis of the movable end of the driving piece 312,

further, not only can prevent the powder material from caking and blocking in the in-process of feed like this, the distance of the movable end of first stirring rake 311 relative driving piece 312 moreover can be adjusted according to in service behavior, makes things convenient for the change of first stirring rake 311 simultaneously.

When the powder is used, a user puts in powder from the second feeding hole, the second motor 332 drives the third stirring paddle 331 to rotate around the axis of the third motor, the material in the feeding bin 13 is stirred and scattered along the vertical direction, then the material enters the discharging bin 11 along the first feeding hole, then the first motor 3122 drives the first stirring paddle 311 to rotate around the axis of the rotation of the first motor, the material passing through the first discharging hole is scattered, finally the material enters the material pushing screw rod 21 from the first discharging hole, and the powder is transported along the setting direction of the material pushing screw rod 21 under the driving of the third motor 22.

Further, the user can be according to the powder of waiting to stir, the condition of caking and jam easily takes place, through not hard up and screw up nut 3131 to along the first stirring rake 311 of the axle center slip of screw 3121, with the distance of adjusting first stirring rake 311 apart from first motor 3122 and shrouding, feeding storehouse 13 can be dismantled simultaneously and connect in ejection of compact storehouse 11, and convenience of customers changes and dismantles first stirring rake 311.

The structure can solve the technical problem that in the prior art, powder is easy to form compaction and caking in the feeding channel, so that the material channel is blocked.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are included in the scope of the present invention.

Claims (10)

1. The utility model provides an prevent feed arrangement that builds bridge which characterized in that includes:

the bin assembly comprises a discharge bin, the interior of the discharge bin is hollow, and a first discharge hole is formed in the discharge bin;

the feeding assembly is horizontally arranged below the first discharge hole, and the feeding end of the feeding assembly is arranged opposite to the first discharge hole and used for conveying materials along the arrangement direction of the feeding assembly;

stirring subassembly, including first stirring spare, first stirring spare includes first stirring rake, driving piece and locating part, place in the activity of first stirring rake in go out the feed bin to the slope set up in the top of first discharge gate, the driving piece has stiff end and expansion end, the stiff end of driving piece connect in go out feed bin, expansion end connect in first stirring rake is used for the drive first stirring rake rotates around its self axis of rotation, the locating part connect in first stirring rake to can dismantle connect in the expansion end of driving piece is used for the restriction first stirring rake is followed the axis motion of the expansion end of driving piece.

2. The bridge-preventing feeding device as claimed in claim 1, wherein the bin assembly further comprises a baffle plate, the baffle plate is obliquely arranged in the discharging bin and connected to the inner wall of the discharging bin, the baffle plate and the inner wall of the discharging bin form a first discharging port, and the cross-sectional area of the discharging bin is gradually reduced along the direction close to the first discharging port.

3. The bridge-preventing feeding device as claimed in claim 2, wherein the baffle has a rotation hole along a direction perpendicular to the setting direction of the baffle, the driving member comprises a screw rod and a first motor, one end of the screw rod can rotate to pass through the rotation hole, the first stirring paddle is sleeved at one end of the screw rod and can slide along the axis of the screw rod, the first motor is fixedly connected to the discharging bin, and the output shaft of the first motor is connected to the other end of the screw rod.

4. The bridging-preventing feeding device as claimed in claim 3, wherein the limiting member comprises two nuts and two elastic washers, the two nuts are spaced at intervals and connected to one end of the screw, the first stirring paddle is movably arranged between the two nuts, and the elastic washers are arranged between the nuts and the first stirring paddle and respectively abut against the nuts and the first stirring paddle.

5. The bridge-preventing feeding device as claimed in claim 3, wherein the stirring assembly further comprises at least one second stirring paddle, one end of the second stirring paddle is hinged to the first stirring paddle, and the second stirring paddle is circumferentially arranged at the farthest end far away from the rotation axis of the first stirring paddle.

6. The bridging-preventing feeding device as claimed in claim 1, wherein the discharging bin is further provided with a first feeding port, the bin assembly further comprises a feeding bin, the feeding bin is disposed above the discharging bin and detachably connected to the discharging bin, the feeding bin is hollow and provided with a second discharging port, and the second discharging port is communicated with the first feeding port.

7. The bridging-preventing feeding device as claimed in claim 6, wherein the stirring assembly further comprises a second stirring member, the second stirring member comprises at least one third stirring paddle and a second motor, the third stirring paddle is rotatably arranged in the feeding bin, the second motor is fixedly connected to the feeding bin, and the output shaft of the second motor is connected to the third stirring paddle.

8. The bridge-crossing preventing feeding device as claimed in claim 7, wherein the feeding bin is further provided with a second feeding hole for feeding and an exhaust hole for exhausting.

9. The bridging-preventing feeding device of claim 1, wherein the feeding assembly comprises a pushing screw and a third motor, the pushing screw is disposed below the discharging bin, is disposed opposite to the first discharging port, and is connected to the bin, the third motor is fixedly connected to the discharging bin, and an output shaft of the third motor is connected to the pushing screw for driving the pushing screw to rotate around an axis thereof, so that the material moves along the axis of the pushing screw.

10. The bridge-preventing feeding device as claimed in claim 9, wherein the diameter of the pushing screw is continuously reduced in a direction away from the output shaft of the third motor.

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