CN219928514U - Hopper deironing subassembly - Google Patents

Abstract

The utility model provides a hopper iron removal assembly which comprises a guide chute fixedly connected with a hopper, wherein the guide chute comprises a bottom plate fixedly connected with the hopper and a pair of first mounting plates fixedly connected with two sides of the bottom plate, the two first mounting plates are fixedly connected with the hopper, the hopper is provided with a discharge hole, and materials are led out from the discharge hole and then enter the guide chute; the magnetic rod discharging device is characterized by further comprising a pair of second mounting plates fixedly connected with one end of the bottom plate, which is away from the hopper, and a first magnetic rod which is away from one end face of the discharging hole and is away from the bottom plate is further arranged between the two second mounting plates. The utility model solves the problems that the adsorption state of the magnetic rod in the hopper is not easy to be perceived and iron impurities adsorbed in the previous step are easy to return to the material in the prior art.

Description

Hopper deironing subassembly

Technical Field

The utility model relates to the technical field of hopper discharging auxiliary components, in particular to a hopper iron removal component.

Background

In the processing of granular products (such as cat litter), the materials are required to be lifted by using machines such as a lifting machine, the materials are guided into a hopper after being lifted, and then the materials are added into subsequent processing equipment through the hopper, so that the feeding efficiency can be improved. However, the material may contain iron impurities, so as to avoid adverse effects of the iron impurities on subsequent processing, iron removal operation is often required on the material, such as setting a magnetic rod in a hopper, and the iron impurities are adsorbed by the magnetic rod, so that the possibility that the iron impurities enter the subsequent processing procedure is reduced. However, as the magnetic rod is in the hopper, the adsorption state of the magnetic rod is not easy to be observed, for example, the amount of iron impurities in the material is more, so that the magnetic rod is easy to adsorb excessive iron impurities and is not easy to be found, if the subsequent feeding is continued, the iron impurities adsorbed in the front can be impacted by the subsequent material and fall back to the material, and the iron impurities in the subsequent material are increased instead.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model provides a hopper iron removal assembly, which solves the problems that the adsorption state of a magnetic rod in a hopper in the prior art is not easy to be perceived and iron impurities adsorbed in the previous step are easy to return to materials.

According to the embodiment of the utility model, the hopper iron removal assembly comprises a guide chute fixedly connected with a hopper, wherein the guide chute comprises a bottom plate fixedly connected with the hopper and a pair of first mounting plates fixedly connected with two sides of the bottom plate, the two first mounting plates are fixedly connected with the hopper, the hopper is provided with a discharge hole, and materials are guided out from the discharge hole and then enter the guide chute; the magnetic rod discharging device is characterized by further comprising a pair of second mounting plates fixedly connected with one end of the bottom plate, which is away from the hopper, and a first magnetic rod which is away from one end face of the discharging hole and is away from the bottom plate is further arranged between the two second mounting plates.

In the above-mentioned embodiment, with first bar magnet setting outside the hopper, carry out iron impurity to the material in the ejection of compact in-process and adsorb, the adsorption state of first bar magnet can be observed more easily, consequently can in time clear up to avoid iron impurity to be strikeed by the material and return to in the material again, solved the bar magnet adsorption state in the hopper among the prior art be difficult for being perceived and lead to the problem in the material of preceding absorptive iron impurity reenter easily.

Further, two opposite faces of the second mounting plate are respectively provided with a transversely arranged adjusting groove, and two ends of the first magnetic rod are respectively in sliding contact with the two adjusting grooves.

Further, a first clamping groove is further formed in one surface, opposite to the second mounting plate, of the two second mounting plates, the first clamping groove is provided with an upward opening, and a second magnetic rod is further clamped between the corresponding two first clamping grooves on the two second mounting plates.

Further, the second magnetic bar setting height is greater than the first magnetic bar setting height.

Further, two the opposite one side of first mounting panel is seted up a plurality of pairs of second draw-in grooves respectively, and every pair still the joint has the third bar magnet between the second draw-in groove, and all the third bar magnet all with the bottom plate is from mutually.

Further, the hopper is fixedly connected with an adjusting plate above the guide chute, the adjusting plate is further connected with a plugboard in a sliding manner, and the plugboard moves up and down to open and close the discharge hole.

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

the first magnetic rod is arranged outside the hopper to carry out iron removal operation on materials, the adsorption state of the first magnetic rod can be clearly observed, so that the material can be cleaned timely, iron impurities are prevented from being impacted by the materials and then returned to the materials, and the problem that the adsorption state of the magnetic rod in the hopper is not easy to be perceived and easily causes the iron impurities adsorbed in the previous step to be returned to the materials in the prior art is solved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present utility model;

FIG. 2 is an enlarged schematic view of the partial structure at A in FIG. 1;

in the above figures:

hopper 1, baffle box 2, bottom plate 3, first mounting panel 4, second mounting panel 5, first bar magnet 6, regulating plate 7, picture peg 8, adjustment tank 9, first draw-in groove 10, second bar magnet 11, second draw-in groove 12, third bar magnet 13.

Detailed Description

The technical scheme of the utility model is further described below with reference to the accompanying drawings and examples.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model.

As shown in fig. 1 and 2, the present embodiment provides a hopper iron removal assembly, which includes a guide chute 2 fixedly connected to a hopper 1, wherein the guide chute 2 includes a bottom plate 3 fixedly connected to the hopper 1 and a pair of first mounting plates 4 fixedly connected to two sides of the bottom plate 3, and both the first mounting plates 4 are fixedly connected to the hopper 1, the hopper 1 has a discharge port, and materials are led out from the discharge port and then enter the guide chute 2; the iron removal assembly further comprises a pair of second mounting plates 5 fixedly connected with one end, away from the hopper 1, of the bottom plate 3, and a first magnetic rod 6 separated from the end face, away from the discharge port, of the bottom plate 3 is arranged between the two second mounting plates 5; further, the hopper 1 is fixedly connected with an adjusting plate 7 above the guide chute 2, the adjusting plate 7 is further connected with a plugboard 8 in a sliding manner, the plugboard 8 moves up and down to open and close the discharge port, and the discharge port can be adjusted by sliding between the plugboard 8 and the adjusting plate 7 relatively, so that materials can be conveniently guided out and blocked.

In the above embodiment, the hopper 1 is just like in the prior art and is used for feeding of subsequent processing equipment, the guide chute 2 is arranged behind the discharge hole of the hopper 1 for guiding materials, the materials guided out from the discharge hole enter the subsequent processing equipment after passing through the guide chute 2, then the first magnetic rod 6 is arranged behind the guide chute 2 for removing iron, specifically, the first magnetic rod 6 is arranged outside the hopper 1, iron impurities are adsorbed to the materials in the discharging process, the adsorption state of the first magnetic rod 6 can be observed more easily, and therefore cleaning can be timely carried out, the situation that the iron impurities are returned to the materials after being impacted by the materials is avoided, and the problem that the adsorption state of the magnetic rod in the hopper 1 is not easy to be perceived and easily causes the iron impurities adsorbed in the previous step to be returned to the materials in the prior art is solved.

Preferably, as shown in fig. 1 and 2, the second mounting plate 5 in this embodiment provides a mounting base for the first magnetic rod 6, and a certain distance is reserved between the first magnetic rod 6 and the guide chute 2, so that materials can fall down through the gap, and also fall down after passing through the gap and the first magnetic rod 6, iron impurities are adsorbed by the first magnetic rod 6 in the process, so as to achieve the iron removal purpose, further, two opposite sides of the second mounting plate 5 in this embodiment are respectively provided with a transversely arranged adjusting groove 9, and two ends of the first magnetic rod 6 are respectively in sliding contact with the two adjusting grooves 9, so that the transverse position of the first magnetic rod 6 can be adjusted, and therefore the relative position between the first magnetic rod 6 and the guide chute 2 can be adjusted to adapt to more material discharging conditions, and further, the first magnetic rod 6 can be detached from one end of the adjusting groove 9, which is away from the guide chute 2, so that cleaning of the first magnetic rod 6 is convenient.

As shown in fig. 2, a first clamping groove 10 is further formed in one surface of the two opposite second mounting plates 5, the first clamping groove 10 has an upward opening, a second magnetic rod 11 is further clamped between the two corresponding first clamping grooves 10 on the two second mounting plates 5, and the additionally arranged second magnetic rod 11 is matched with the first magnetic rod 6, so that the iron removal efficiency is further improved, and meanwhile, the second magnetic rod 11 can be conveniently detached, so that the subsequent cleaning and maintenance are facilitated; further, the second magnetic rod 11 is higher than the first magnetic rod 6, so that a V-shaped surrounding structure can be formed among the second magnetic rod 11, the first magnetic rod 6 and the bottom plate 3, and materials can better contact with the first magnetic rod 6 and the second magnetic rod 11 after leaving the guide chute 2 through the structure, so that iron removal efficiency is better.

Preferably, as shown in fig. 1, two pairs of second clamping grooves 12 are respectively formed in opposite sides of the first mounting plate 4, and a third magnetic rod 13 is clamped between each pair of second clamping grooves 12 (the second clamping grooves 12 are provided with upward openings to facilitate clamping of the third magnetic rod 13), all the third magnetic rods 13 are separated from the bottom plate 3, a space is reserved between the third magnetic rods 13 and the bottom plate 3 for allowing materials to pass through, normal movement of the materials is not blocked, the materials are removed from the upper side by the third magnetic rods 13, iron removal efficiency is further improved, and meanwhile, the third magnetic rods 13 can be conveniently detached for cleaning maintenance.

Finally, it is noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present utility model, which is intended to be covered by the scope of the claims of the present utility model.

Claims (6)

1. The hopper iron removal assembly is characterized by comprising a guide chute fixedly connected with a hopper, wherein the guide chute comprises a bottom plate fixedly connected with the hopper and a pair of first mounting plates fixedly connected with two sides of the bottom plate, the two first mounting plates are fixedly connected with the hopper, the hopper is provided with a discharge hole, and materials are led out from the discharge hole and then enter the guide chute; the magnetic rod discharging device is characterized by further comprising a pair of second mounting plates fixedly connected with one end of the bottom plate, which is away from the hopper, and a first magnetic rod which is away from one end face of the discharging hole and is away from the bottom plate is further arranged between the two second mounting plates.

2. The hopper iron removal assembly of claim 1, wherein two opposite sides of the second mounting plates are respectively provided with a transversely arranged adjusting groove, and two ends of the first magnetic rod are respectively in sliding contact with the two adjusting grooves.

3. The hopper iron removal assembly of claim 1, wherein a first slot is further formed in an opposite side of the two second mounting plates, the first slot has an upward opening, and a second magnetic rod is further clamped between the corresponding two first slots on the two second mounting plates.

4. The hopper iron removal assembly of claim 3, wherein the second magnetic bar set height is greater than the first magnetic bar set height.

5. The hopper iron removal assembly as set forth in any one of claims 1-4, wherein a plurality of pairs of second slots are respectively provided on opposite sides of the two first mounting plates, and a third magnetic rod is further clamped between each pair of second slots, and all of the third magnetic rods are separated from the bottom plate.

6. The hopper iron removal assembly of claim 5, wherein said hopper is further fixedly connected with an adjustment plate positioned above said guide chute, said adjustment plate further being slidably connected with a plugboard that moves up and down to open and close said discharge port.