CN218809168U - Digital feed production impeller feeder device - Google Patents

Abstract

The utility model discloses a digital feed production impeller feeder device, including the feeder, be equipped with feed inlet and storage case on the feeder, install rotating-structure in the storage case, rotating-structure is last to install sliding structure, sliding structure is last to install vibrations structure, vibrations structrual installation is in one side of storage case, the utility model discloses, through set up motor and stopper on rotating-structure, the motor rotates and drives the connecting rod and rotate, the connecting rod rotates and drives the stopper and rotate and be convenient for drive transfer line and do reciprocating motion, through set up the baffle on sliding structure, be convenient for quick push away the material of raw materials whereabouts in the unloading hole completely, through set up semicircle board and strike the hammer in vibrations structure, drive the storage case that strikes that the hammer and does not stop when the semicircle board removes, make the unloading that the unloading hole can be smooth, avoid the raw materials to pile up in the unloading hole, unable normal unloading leads to the extravagant many electric power resources of whitish and a large amount of labour dredge many times.

Description

Digital feed production impeller feeder device

Technical Field

The utility model relates to a feeder technical field specifically is a digital feed production impeller feeder device.

Background

The impeller type feeder is a device for outputting feed from a discharge port by utilizing rotation of an impeller, and a feed machine host mainly comprises a feeding system, a stirring system, a granulating system, a transmission system, a lubricating system and the like. The raw materials enter a feeding device from a hopper, the material flow is obtained by adjusting the rotating speed of a stepless speed regulating motor, then the raw materials enter a stirrer, are stirred and mixed by a stirring rod, and finally enter a pressing chamber for granulation.

In the prior art, the impeller feeder for feed production with the publication number of CN215624572U comprises a first box body, a second box body and a water tank, wherein the second box body is fixedly connected to the top of the first box body, a partition board is fixedly connected to the bottom of the inner wall of the first box body, a conveyor belt and a collecting box are arranged in the first box body, and a stirring box is fixedly connected to one side of the inner wall of the first box body. Its beneficial effect is, through setting up third motor, third pivot, puddler and filter, can stir the separation to the fodder, at actual feeder operation in-process, has following technical problem: 1 the flow of automatic control feeding can not be carried out in the device of current in when throwing in the raw materials, the speed control flow of reinforced when only can relying on manual feeding, thereby cause the raw materials can not be abundant when getting into the teeter chamber with biological fungus homogeneous mixing, 2 do not set up the device that the mediation stopped up in the device in feed opening department, but during the actual production of fodder, the raw materials blocks up the feed opening because the moisture regain is very easy, lead to the raw materials to pile up in the feed opening, unable normal unloading, in time when not getting the material in the blender, also can not rotate with stopping, lead to white waste a lot of power resources and a large amount of labours to dredge many times.

Therefore, a digital feed production impeller feeder device is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a digital feed production impeller feeder device to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a digital feed production impeller feeder device, includes the feeder, be equipped with feed inlet and storage case on the feeder, install rotating-structure in the storage case, the last sliding construction that installs of rotating-structure, the last vibrations structure of installing of sliding construction, vibrations structural mounting is in one side of storage case.

Preferably, the vibrations structure includes the fixed block, and the fixed block is installed on the storage case, installs the motor on the fixed block, installs the drive shaft on the motor, installs the connecting rod in the drive shaft, rotates on the connecting rod and installs the stopper, and the both ends of stopper all contact with the inner wall of storage case.

Preferably, the limiting block is provided with a limiting hole, the connecting rod is provided with a rotating shaft, and the rotating shaft is rotatably arranged on the limiting hole.

Preferably, sliding construction includes the transfer line, and the one end of transfer line is installed on the stopper, and the baffle is installed to the other end of transfer line, has seted up the spout on the bottom side inner wall of storage case, and baffle slidable mounting is in the spout, the baffle respectively with unloading hole and discharge gate looks adaptation.

Preferably, two positioning grooves are formed in the sliding groove, two sliding blocks are mounted on two sides of the baffle, and the two sliding blocks are respectively slidably mounted in the positioning grooves.

Preferably, a return spring is installed in the chute, the other end of the return spring is installed on the baffle, and a telescopic rod is sleeved on the return spring.

Preferably, the vibrations structure includes the installation pole, has seted up the position fixing hole on the storage case, and the one end of installation pole runs through the position fixing hole and installs on the stopper, and the fly leaf is installed to the other end of installation pole, and equidistance installs a plurality of semicircle boards on the fly leaf, and the L template is installed to one side of storage case, has seted up the movable orifice on the L template, and slidable mounting has the trace in the movable orifice, and the movable block is installed to the one end of trace, and the movable block contacts with the semicircle board, installs on the opposite side of trace and strikes the hammer, strikes the hammer and contacts with the storage case.

Preferably, the linkage rod is sleeved with a compression spring, one end of the compression spring is installed on the L-shaped plate, and the other end of the compression spring is installed on the moving block.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) The utility model discloses a setting of baffle and motor, can be effectual the problem that the flow of solution raw materials unloading can not be controlled in actual production, after the workman drops into the raw materials from the feed inlet, the raw materials is left from the unloading is downthehole, under driving motor's drive, it is reciprocating motion to drive the baffle on the horizontal direction, it can be accurate to release completely from the discharge gate the raw materials to move forward at the baffle, baffle on the baffle can be totally stifled the unloading hole simultaneously, thereby can control the speed and the quality of raw materials whereabouts, be convenient for let the raw materials can abundant stirring when the stirring, avoid because the flow of uncontrollable raw materials whereabouts, the finished product quality that causes is unqualified.

(2) The utility model discloses a strike setting of hammer and semicircle board, after in the feeder is put in the raw materials that wets, it removes to drive the semicircle board at the fly leaf and removes, the semicircle board removes and drives the trace and move back-and-forth movement ceaselessly, it strikes the storage case to drive the hammer back-and-forth movement and strike to drive under the removal that the trace does not stop, be convenient for let the storage case produce the vibration, make the raw materials that blocks up at the unloading hole produce the vibration, thereby the not hard up whereabouts of the raw materials that lets the jam that can relax dredge the unloading hole, make the unloading that the unloading hole can be smooth, avoid the raw materials to pile up at the unloading hole, unable normal unloading, in time when not obtaining the material in the mixer, also can not stop the rotation, lead to the extravagant very many electric power resources of whitish and a large amount of labour to dredge many times.

Drawings

Fig. 1 is a schematic view of the main structure of a digital impeller feeder device for feed production of the present invention;

fig. 2 is a schematic cross-sectional structure view of the impeller feeder apparatus for digital feedstuff production according to the present invention;

fig. 3 is a schematic cross-sectional structure diagram of a material storage box of the impeller feeder apparatus for digital feed production according to the present invention;

fig. 4 is a schematic view of a connection structure of a motor, a baffle and a storage box of the impeller feeder device for digital feed production of the present invention;

fig. 5 is a schematic view of the connection structure of the movable plate, the linkage rod and the knocking hammer of the impeller feeder device for digital feed production.

In the figure: 1. feeder, 2, feed inlet, 3, storage case, 4, fixed block, 41, motor, 42, drive shaft, 43, connecting rod, 44, axis of rotation, 45, stopper, 46, spacing hole, 5, transfer line, 51, baffle, 52, spout, 53, discharge gate, 54, unloading hole, 55, constant head tank, 56, slider, 57, telescopic link, 58, reset spring, 6, installation pole, 61, fly leaf, 62, the position fixing hole, 63, semicircle board, 64, the movable block, 65, the trace rod, 66, compression spring, 67, activity hole, 68, strike hammer, 69, L template.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The embodiment is as follows: referring to fig. 1-5, the present invention provides a technical solution: the utility model provides a digital feed production impeller feeder device, including feeder 1, be equipped with feed inlet 2 and storage case 3 on the feeder 1, install rotating-structure in the storage case 3, rotating-structure is last to install sliding structure, sliding structure is last to install vibrations structure, vibrations structrual installation is in one side of storage case 3, through set up motor 41 and stopper 45 on rotating-structure, motor 41 rotates and drives connecting rod 43 and rotate, connecting rod 43 rotates and drives stopper 45 and rotate and be convenient for drive transfer line 5 and do reciprocating motion, through set up baffle 51 on sliding structure, be convenient for quick push away the material of whereabouts in the feed opening 54 completely, through setting up semicircle board 63 and strike hammer 68 on vibrating-structure, drive strike hammer 68 strike case 3 that does not have a failure when semicircle board 63 removes, make the unloading that feed opening 54 can be smooth unloading, avoid the raw materials to pile up at feed opening 54, unable normal unloading, in time when not getting the material in the blender, also can not have a lot of rotating of stopping, lead to the extravagant very many power resources of white and a large amount of labour to dredge many times.

Referring to fig. 3-4, the vibration structure includes a fixing block 4, the fixing block 4 is installed on the material storage box 3, a motor 41 is installed on the fixing block 4, a driving shaft 42 is installed on the motor 41, a connecting rod 43 is installed on the driving shaft 42, a limiting block 45 is installed on the connecting rod 43 in a rotating manner, two ends of the limiting block 45 are in contact with the inner wall of the material storage box 3, the driving shaft 42 is driven by the motor 41 to rotate, the driving shaft 42 drives the connecting rod 43 to rotate, the connecting rod 43 drives the limiting block 45 to move, and the driving rod 5 is driven to reciprocate conveniently.

Referring to fig. 3, a limiting hole 46 is formed in the limiting block 45, a rotating shaft 44 is mounted on the connecting rod 43, the rotating shaft 44 is rotatably mounted in the limiting hole 46, and the rotating shaft 44 rotates in the limiting hole 46, so that the rotation of the motor 41 is converted into the reciprocating motion of the limiting block 45.

Referring to fig. 4, the sliding structure includes a transmission rod 5, one end of the transmission rod 5 is mounted on the limiting block 45, the other end of the transmission rod 5 is mounted with a baffle 51, the inner wall of the bottom side of the storage box 3 is provided with a chute 52, the baffle 51 is slidably mounted in the chute 52, the baffle 51 is respectively matched with the blanking hole 54 and the discharge hole 53, the baffle 51 can reciprocate by the movement of the transmission rod 5, and the raw material can be rapidly pushed out from the discharge hole 53.

Referring to fig. 4, two positioning grooves 55 are formed in the sliding groove 52, two sliding blocks 56 are mounted on two sides of the baffle 51, the two sliding blocks 56 are respectively slidably mounted in the positioning grooves 55, and the sliding blocks 56 slide in the positioning grooves 55, so that the baffle 51 is limited to move only in the horizontal direction.

Referring to fig. 4, a return spring 58 is installed in the chute 52, the other end of the return spring 58 is installed on the baffle 51, an expansion link 57 is sleeved on the return spring 58, and the return spring 58 and the expansion link 57 are installed on one side of the baffle 51, so that the baffle 51 can be quickly restored after the material is pushed out.

Referring to fig. 4-5, the vibration structure includes a mounting rod 6, a fixing hole 62 is formed in the storage box 3, one end of the mounting rod 6 penetrates through the fixing hole 62 and is mounted on a limiting block 45, a movable plate 61 is mounted at the other end of the mounting rod 6, a plurality of semicircular plates 63 are mounted on the movable plate 61 at equal intervals, an L-shaped plate 69 is mounted on one side of the storage box 3, a movable hole 67 is formed in the L-shaped plate 69, a linkage rod 65 is slidably mounted in the movable hole 67, a movable block 64 is mounted at one end of the linkage rod 65, the movable block 64 is in contact with the semicircular plates 63, a striking hammer 68 is mounted on the other side of the linkage rod 65, the striking hammer 68 is in contact with the storage box 3, the mounting rod 6 is driven to move in the fixing hole 62 in the storage box 3 by the movement of the limiting block 45, the mounting rod 6 drives the movable plate 61 to move, the movable plate 61 is driven by the movement of the movable plate 61, the semicircular plates 63 move to drive the movable block 64 to move, the movable plate 65 to move in the movable hole 67 in the L-shaped plate 69, and the linkage rod 65 drives the movable hole 67 in the storage box 3, so that the linkage rod 65 to move and drive the striking hammer 68.

Referring to fig. 5, a compression spring 66 is sleeved on the linkage rod 65, one end of the compression spring 66 is installed on the L-shaped plate 69, the other end of the compression spring 66 is installed on the moving block 64, and the linkage rod 65 moves to drive the compression spring 66 to continuously extrude and stretch, so that the striking hammer 68 can be restored to the original position after striking, and striking can be performed next time.

The working principle is as follows: when the feeder 1 is used for producing feed, raw materials are fed into the storage box 3 from the feed inlet 2, the motor 41 in the storage box 3 is started, the motor 41 rotates to drive the driving shaft 42 to rotate, the driving shaft 42 rotates to drive the connecting rod 43 to rotate, the connecting rod 43 rotates to drive the rotating shaft 44 to rotate in the limiting hole 46 on the limiting block 45, the rotating shaft 44 rotates to drive the limiting block 45 to move, the limiting block 45 moves to drive the driving rod 5 to move, the driving rod 5 moves to drive the baffle 51 to move in the chute 52, the baffle 51 moves to drive the sliding block 56 to move in the positioning groove 55 on the storage box 3, and simultaneously the baffle 51 moves to drive the telescopic rod 57 and the reset spring 58 to stretch simultaneously, so that the raw materials can be fed out from the discharge port 53 in an accurate and equivalent manner, the raw materials can be conveniently and uniformly stirred, and the flow rate of falling raw materials can not be controlled, the quality of the finished product is unqualified, meanwhile, the limiting block 45 moves to drive the installation rod 6 to move in the retention hole 62 on the storage box 3, the installation rod 6 moves to drive the movable plate 61 to move, the movable plate 61 moves to drive the semi-circular plate 63 to move, the semi-circular plate 63 moves to drive the movable block 64 to move without stopping, the movable block 64 moves to drive the linkage rod 65 to move in the movable hole 67 on the L-shaped plate 69, the linkage rod 65 moves to drive the compression spring 66 to extrude and stretch without stopping, and the linkage rod 65 moves to drive the knocking hammer 68 to knock one side of the storage box 3 without stopping, so that the storage box 3 vibrates, the raw material blocked in the blanking hole 54 vibrates, the blocked raw material is loosened and falls to dredge the blanking hole 54, the blanking hole 54 can be blanked smoothly, the raw material is prevented from being accumulated in the blanking hole 54 and cannot be normally blanked, and when the material is not obtained in the mixer in time, the device can rotate continuously, so that a lot of power resources are wasted and a lot of labor force is used for dredging for many times.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a digital feed production impeller feeder device, includes feeder (1), be equipped with feed inlet (2) and storage case (3) on feeder (1), its characterized in that: install rotating-structure in storage case (3), the last sliding construction that installs of rotating-structure, the last vibrations structure that installs of sliding construction shakes one side at storage case (3).

2. A digital feed production impeller feeder apparatus as claimed in claim 1, wherein: the vibrations structure includes fixed block (4), and fixed block (4) are installed on storage case (3), installs motor (41) on fixed block (4), installs drive shaft (42) on motor (41), installs connecting rod (43) on drive shaft (42), rotates on connecting rod (43) and installs stopper (45), and the both ends of stopper (45) all contact with the inner wall of storage case (3).

3. A digital feed production impeller feeder apparatus as claimed in claim 2, wherein: spacing hole (46) have been seted up on stopper (45), install axis of rotation (44) on connecting rod (43), axis of rotation (44) rotate and install on spacing hole (46).

4. A digital feed production impeller feeder apparatus as claimed in claim 1, wherein: the sliding structure comprises a transmission rod (5), one end of the transmission rod (5) is installed on a limiting block (45), a baffle (51) is installed at the other end of the transmission rod (5), a sliding groove (52) is formed in the inner wall of the bottom side of the storage box (3), the baffle (51) is installed in the sliding groove (52) in a sliding mode, and the baffle (51) is respectively matched with a discharging hole (54) and a discharging hole (53).

5. A digital feed production impeller feeder apparatus as claimed in claim 4, wherein: two positioning grooves (55) are formed in the sliding groove (52), two sliding blocks (56) are installed on two sides of the baffle (51), and the two sliding blocks (56) are respectively installed in the positioning grooves (55) in a sliding mode.

6. A digital feed production impeller feeder apparatus as claimed in claim 4, wherein: a return spring (58) is installed in the sliding groove (52), the other end of the return spring (58) is installed on the baffle plate (51), and a telescopic rod (57) is sleeved on the return spring (58).

7. A digital feed production impeller feeder apparatus as claimed in claim 1, wherein: the utility model discloses a vibration structure, including shock structure, location hole (62) have been seted up on storage case (3), the one end of installation pole (6) is run through location hole (62) and is installed on stopper (45), fly leaf (61) are installed to the other end of installation pole (6), equidistant a plurality of semicircle boards (63) of installing on fly leaf (61), L template (69) are installed to one side of storage case (3), movable hole (67) have been seted up on L template (69), slidable mounting has trace (65) in movable hole (67), movable block (64) are installed to the one end of trace (65), movable block (64) contact with semicircle board (63), install on the opposite side of trace (65) and strike hammer (68), strike hammer (68) and storage case (3) case contact.

8. A digital feed production impeller feeder apparatus as claimed in claim 7, wherein: the linkage rod (65) is sleeved with a compression spring (66), one end of the compression spring (66) is installed on the L-shaped plate (69), and the other end of the compression spring (66) is installed on the moving block (64).

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