KR102548915B1 - Apron Feeder - Google Patents

Abstract

The present invention relates to an apron feeder, comprising: a pair of feeder frames provided parallel to each other; roller units having groove-shaped guide grooves formed around the outer peripheral surface and provided at predetermined intervals in the longitudinal direction between the feeder frames; a chute in which several chute plates, each of which has a reinforcing plate seated in the guide groove, overlap each other and can be transferred in the longitudinal direction of the feeder frame; and a chute support unit that supports the reinforcing plate during sliding of the chute between the roller units. Thus, the present invention can provide the apron feeder that prevents deformation of the chute plate during transferring of the chute, minimizes damage to rollers, and can be economically constructed.

Description

Apron Feeder {Apron Feeder}

The present invention relates to an apron feeder that transfers or supplies an article (ore stone) used as a raw material in a certain place to a jaw crusher.

In general, an apron feeder is mainly used to transfer and supply raw stones to a jaw crusher.

Referring to 'Korean Registered Patent No. 10-0847857' for this apron feeder, several chute plates are combined so that the driving force of the drive motor installed on one side of the frame drives a chain connected to the drive sprocket wheel on the output side of the reducer through a reducer, As the driven sprocket wheel is rotated by the drive of the chain, the roller link coupled to the driven sprocket is transported at a constant speed.

In addition, according to the movement of the roller link, the chute coupled to the roller link is interlocked to move the ore falling from the top to the bottom, not shown, at a constant speed.

In addition, as a means to prevent the suit from being damaged by the weight of the gemstone, a roller (hereinafter referred to as 'roller') is coupled to the lower part of the suit by a roller frame (hereinafter referred to as 'roller frame') to distribute the weight of the gemstone It can be easily transported in the middle of the day.

At this time, the roller supporting the lower part of the chute is configured so that a separate louver is formed to have a predetermined thickness on the surface of the normal roller.

In the process of supplying raw stones to the jaw crusher by the apron feeder having such a structure, the weight of the raw stones intensively acts on the louvers and rollers supporting them through the chute, resulting in cracks in the rollers and louvers during long-term use. At the same time, due to this, there was a problem that deformation occurs in the suit itself.

In addition, there was a problem that the deformation of the chute plate occurs, such as the chute plate sagging into the space between the rollers (rollers) during the transfer of the chute. In order to compensate for this, more rollers can be used to support the chute plate, but in this case, there is a problem that management difficulties and costs such as damage to the rollers are high.

Republic of Korea Patent No. 10-0847857

An object of the present invention is to provide an apron feeder that can prevent deformation of a chute plate during transport of a chute, minimize damage to rollers, and can economically configure the device.

The present invention relates to an apron feeder, and relates to a pair of feeder frames provided in parallel with each other; and a roller unit provided with a concave guide groove formed around an outer circumferential surface and spaced apart from each other by a predetermined interval in the longitudinal direction between the feeder frames. And, a chute provided to be transportable in the longitudinal direction of the feeder frame by being provided so that a part of the chute plate having a reinforcing plate seated in the guide groove overlaps each other; and a chute support for supporting the reinforcing plate during sliding of the chute between the roller unit and the other roller unit.

As an example, a chute support rail portion provided in parallel with the feeder frame between the roller portions provided side by side in the longitudinal direction of the feeder frame to support the reinforcing plate; characterized in that it comprises a.

As an example, the chute support unit includes a plurality of fixing brackets fixed to the feeder frame and spaced apart from each other, and the fixing brackets are provided in parallel with the outer circumferential surface of the guide groove, and are in contact with the reinforcing plate when the chute slides. and a reinforcing plate support member for supporting and guiding the reinforcing plate to the guide groove.

As an example, the end of the reinforcing plate support member and the end of the reinforcing plate facing this end form a curved surface facing each other.

As an example, a filling space is formed inside between the reinforcing plate support members, and a spacer member having a plurality of through holes formed on the lower surface is configured, and the filling space is characterized in that a sound absorbing agent is filled.

As an example, the chute plate includes a seating portion provided with the reinforcing plate on a first surface on which an article is seated and a second surface facing the roller unit, and the first surface at the front and rear ends of the seating portion in the sliding direction, respectively. Characterized in that it includes a connector provided in a hemispherical shape protruding to have a predetermined curvature toward the.

As an example, the connectors of one chute plate overlap each other in the form of being stacked with the connectors of the other chute plate, and the end of the connector located on the upper part is characterized in that an elastic material is formed with an anti-catch edge.

As an example, the distance between the central axis of the guide groove and the end of the reinforcing plate support member is adjusted so that a part of the reinforcing plate is supported by the reinforcing plate support member when the reinforcing plate passes through the guide groove while the chute plate is moving. to be characterized

As an example, a chain connected to a sprocket shaft is configured at both ends of the chute, and the chain is connected by a connecting rod between rollers to be combined in an endless orbit, and the rollers of the chain are supported at both ends of the feeder frame It is characterized in that the support rail is configured.

As an example, a departure prevention rim protrudes from the outer surface of the support rail, and a transverse roller in contact with the departure prevention rim is further configured on the connecting rod.

As for the apron feed of the present invention, the following effects can be exhibited.

First, according to the apron feed of the present invention, in the process of supplying the gemstone to the jaw crusher, the weight of the gemstone is distributed in the roller and chute plate support supporting the chute, which can improve the rigidity and stability of the apron feed It works.

Second, according to the apron feed of the present invention, it is possible to prevent deformation of the chute, such as the chute plate sagging into the space between the rollers during transport of the chute, thereby reducing the impact applied to the roller, It has the effect of preventing damage and reducing maintenance costs.

Thirdly, according to the apron feed of the present invention, it is possible to control damage caused by foreign substances being caught between the chute plates during the transport of the chute, to control the noise generated during the transport of the chute, and to control the departure of the chute. There is an effect.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view showing an embodiment of the apron feeder of the present invention.
FIG. 2 is a plan view showing the projected apron feeder of FIG. 1 .
Figure 3 is a cross-sectional view showing a vertical section in the traveling direction of the chute of Figure 2;
FIG. 4 is a perspective view showing a partially exploded view of FIG. 1 .
FIG. 5 is a cross-sectional view taken along line A-A' of FIG. 1 .
6 is a partial view showing one embodiment of a suit with one configuration of the present invention.
7 is a partial view showing another embodiment of a suit with one configuration of the present invention.
8 is a cross-sectional view showing an embodiment of a chute support part in one configuration of the present invention.
9 is a front view showing another embodiment of a suit with one configuration of the present invention.

In describing the present invention, the terms or words used in this specification and claims are based on the principle that the inventor can appropriately define the concept of the term in order to best describe his or her invention. should be interpreted as a meaning and concept that corresponds to the technical idea of

Hereinafter, an embodiment of the apron feeder of the present invention will be described with reference to the accompanying drawings.

1 to 9, the apron feeder 1 includes a feeder frame 10, a roller unit 20, a chute 30, a chute support unit 40, and a chute support rail unit 50. include

The feeder frame 10, although not shown in the drawings, may be provided in a grid shape in the longitudinal and transverse directions. The feeder frame 10 is provided in a lattice shape such as an H beam, and corresponds to a configuration in which the roller unit 20 and the chute support unit 40 are fixed. Since various known technologies exist for the feeder frame 10, a detailed description thereof will be omitted.

In addition, the feeder frame 10 may be provided with a chute 30, and a drive motor M for rotationally interlocking the chute 30 in the feeder frame 10 may be provided.

The feeder frame 10 may be provided with a plurality of roller units 20 installed to support the transfer of the chute 30 . Hereinafter, the forward direction of the chute 30 in the feeder frame 10 is referred to as the forward direction, and the opposite direction to the forward direction is referred to as the rear end direction.

The driving motor (M) may be provided in the feeder frame 10 so that driving force is transmitted to the chute 30 by receiving power from the outside. Operating the chute by a drive motor and a drive motor provided in the feeder frame is a known technique and a detailed description thereof will be omitted.

However, as described below, the chain 36 configured in the chute 30 and interlocked integrally interlocks with the sprocket receiving the driving force of the driving motor M, thereby driving the chute ( 30) can be rotationally interlocked.

The roller unit 20 is provided with a guide groove 201 and is rotatably coupled to the roller support member 22 to fix the roller support member 22 to the feeder frame 10 .

The roller unit 20 may have a concave guide groove 201 formed around an outer circumferential surface thereof and spaced apart from the feeder frame 10 at a predetermined interval in the longitudinal direction.

The chute 30 is provided so that a part of the chute plate 32 having the reinforcing plate 34 seated in the guide groove 201 overlaps each other so that rotational interlocking is possible in the longitudinal direction of the feeder frame 10. may be provided.

The chute 30 is stably supported by a plurality of roller parts 20 coupled to the roller support member 22, and rotational interlocking is performed at a constant speed by a sprocket operated by a driving motor M. It can be.

Although reference numbers are not shown in the chute plate 32, the article seated on the seating portion 321 described below is moved to both ends of the chute plate 32 so that separation from the chute plate 32 is controlled. To do so, a shoot plate tip extending orthogonally from the seating portion 321 may be included.

This chute plate tip is formed so that the width of one side (front end direction) is wider than the width of the other side (rear end direction) based on the chute plate tip, so that a part of the chute plate tip is maintained in a state inserted in advance into another part of the chute plate tip, so that the chute ( 30) may be provided to prevent objects placed inside, that is, gemstones and parts of gemstones from escaping to the outside.

The seating portion 321 includes a first surface on which an article is seated and a second surface facing the roller unit 20, and a reinforcing plate 34 is provided on the second surface. The seating portion 321 is provided with connectors 322 in a hemispherical shape protruding toward the first surface to have a predetermined curvature on one side and the other side of the sliding direction of the seating portion 321, respectively, so that the other chute plate 32 It is overlapped with to prevent items from falling between the chute plates, and the strength of the chute plates 32 is reinforced by these connectors 322.

The connector 322 is provided with a larger radius than the connector 3221 at one end of the seating portion 321, so that when the chute plates 32 are connected, the connector 3221 of one chute plate 32 It is stacked in a shape covering the connector 3222 of the other chute plate 32.

As shown in the drawing, the connector 322 is mutually chute in a shape in which the connector 3221 provided in the front end direction of the moving direction in which the chute 30 is transported covers the connector 3222 provided in the rear end direction of the other chute plate 32 The plates 32 overlap.

The reinforcing plate 34 may be provided on the lower side of the seating portion 321 corresponding to the roller portion 20 and seated in the guide groove 201 . This reinforcing plate 34 may be provided with a combination fastened to the chute plate 32 by welding or bolting.

The reinforcing plate 34 is supported by the roller parts 20 according to the transport of the chute 30. The reinforcing plate 34 is not supported between the roller parts 20, so that the deformation of the chute 30, that is, the chute plate ( 32) may cause problems. In addition, in order to solve this problem, there is an uneconomical problem when more roller parts 20 are configured, and even if the roller parts 20 are densely configured, there is a gap between the roller parts 20, so the problem can be completely freed There is no

Accordingly, in the present invention, the chute support portion 40 supporting the reinforcing plate 34 can be configured economically by being configured between the roller portions 20, and minimizing the empty gap in supporting the chute 30 is to make it possible

The chute support part 40 supports the reinforcing plate 34 during sliding of the chute 30 between the roller part 20 and the other roller part, and guides the reinforcing plate 34 to be seated in the guide groove 201. can do.

The chute support part 40 is provided with a plurality of fixing brackets 42 fixed to the feeder frame 10 and forming a certain distance, and the fixing bracket 42 is provided in parallel with the outer circumferential surface of the guide groove 201. It is characterized in that it comprises a reinforcing plate support member 44 for guiding the reinforcing plate 34 to the guide groove 201 by contacting and supporting the reinforcing plate 34 when the chute 30 slides. .

Preferably, as shown in the drawing, the reinforcing plate support member 44 in the fixing bracket 42 protrudes both ends to minimize the gap with the roller unit 20 to support the chute 30 mentioned above. It is reasonable to minimize the empty gap.

More preferably, as shown in FIG. 3, the distance d1 between the central axis of the guide groove 201 and the end of the reinforcing plate support member 44 is the distance d1 between the chute plate 32 and the reinforcing plate 34 while moving. When passing through the guide groove 201, it is reasonable that a part of the reinforcing plate 34 is adjusted to be supported by the reinforcing plate support member 44.

That is, when the distance (d) between the central axis of the guide groove 201 and the end of the reinforcing plate support member 44 is too large, although not shown in the drawing, the reinforcing plate 34 is the guide groove 201 When passing through, a state in which a part of the reinforcing plate 34 is not supported by the reinforcing plate support member 44 may occur.

In this case, the corresponding chute plate 32 is finely seesaw interlocked with the guide groove 201 as an axis, so that the reinforcing plate 34 may be caught by the reinforcing plate support member 44 in the front direction during the flow process. there is.

Accordingly, in the present invention, in order to control this problem, when the reinforcing plate 34 passes through the guide groove 201, a part of the reinforcing plate 34 is supported by the reinforcing plate support member 44. 201) to make the distance (d) between the central axis and the end of the reinforcing plate support member 44 as small as possible.

To this end, the distance between the chute support part 40 and the roller part 20 is reduced, or the reinforcing plate support member 44 protrudes from the fixing bracket 42 by lengthening the protruding length of the reinforcing plate support member 44 and the guide The gap between the grooves 201 can be reduced.

In addition, as shown in FIG. 4, the end of the reinforcing plate support member 44 and the end of the reinforcing plate 34 facing it form curved surfaces 441 and 341 facing each other.

As shown in the drawing, the reinforcing plate 34 has a curved surface 341 formed at the lower end in the front end direction, and the reinforcing plate support member 44 has a curved surface 441 formed at the upper end in the rear end direction, so that the chute 30 This is to ensure that the reinforcing plate 34 integrally interlocking with the guide groove 201 as well as the reinforcing plate support member 44 and the operation without jamming.

That is, in the flow process of the chute 30, the reinforcing plate 34 composed of each chute plate 32 may form a step with the guide groove 201, in particular, the reinforcing plate support member 44, which faces in the flow process. In spite of the formation of these steps, the problem of the flow of the chute 30 is controlled by forming the opposite curved surfaces 341 and 441, respectively.

Meanwhile, between the roller parts 20, the reinforcing plate 34 of the chute 30 is supported by the reinforcing plate support member 44 so that the reinforcing plate 34 slides in the reinforcing plate support member 44. As a result, there is a problem that noise is generated.

Accordingly, in the present invention, as shown in FIG. 6, a filling space 461 is formed inside between the reinforcing plate support members 44, and a spacer 46 having a plurality of through holes 462 formed on the lower surface is configured. , The filling space 461 is presented as an example so that the sound absorbing agent 48 is filled.

The spacer member 46 is to be attached between the reinforcing plate support members 44 by using a material having rigidity such as iron to control the deformation of the spaced difference between the chute support parts 40 due to the load. That is, to improve the support rigidity of the chute support portion (40).

In addition to this, the spacer 46 is configured in a container shape with an open upper surface so that the sound absorbing agent 48 is filled as the filling space 461 is formed therein, and a plurality of through holes 462 are formed on the lower surface. However, the noise generated from the reinforcing plate support member 44 on both sides is transmitted to the sound absorbent 48 along the sidewall of the spacer 46 or directly transmitted from the reinforcing plate 34 to the sound absorbent 48 so that it is canceled will be.

Here, the reason why the through hole 462 is formed is that when the mineral contains moisture, it can fall and be absorbed by the sound absorbent 48. Since the sound absorption efficiency is lowered, moisture escapes from the sound absorbent 48 by gravity through the through hole 462.

The type of the sound absorbing agent 48 is not limited, and foamable urethane may be applied as an example.

On the other hand, as mentioned above, the chute 30 is overlapped with each other in a form in which the connector 322 of one chute plate 32 is stacked with the connector 322 of the other chute plate 32, the foreign matter contained in the mineral When pinched between the connectors 322, a failure may occur due to the formation of a step between the chute plates 32. In the present invention, as shown in FIG. (3221-1) is configured to control foreign matter from being caught between the connectors 322.

As shown in the drawing, the anti-hicking frame 3221-1 has one end attached to the end of the connector 3221 located at the top, and the other end connected to the connector 3222 located at the bottom Seating portion 321 It is composed of a shape covering the chute 30 to set minerals, etc. on the upper part to block foreign matter from entering between the connectors 322 during flow.

On the other hand, in the above-mentioned embodiments, the chute plate 32 constituting the chute 30 controls the formation of upper and lower steps to provide an example in which the chute 30 operates smoothly. In 7, an embodiment for controlling the separation of the chute 30 or the chute plate 32 in the transverse direction while doubling the supporting force by supporting both ends of the chute 30 is presented.

In this embodiment, a chain 36 connected to the sprocket shaft is configured at both ends of the chute 30, and the chain 36 is connected by a simple connecting rod 362 to the roller 361 and coupled in the form of an endless track. However, at both ends of the feeder frame 10, support rails 11 for supporting the rollers 361 of the chain 36 are configured, and in addition, the outer surface of the support rail 11 has a breakaway prevention border. 112 protrudes, and an example in which a transverse roller 363 in contact with the separation prevention rim 112 is further configured in the connecting rod 362 is presented.

Although the chain 36 is not shown in the drawings, rotational interlocking is performed by interlocking with the sprocket shaft interlocking with the driving motor, so that the chute 30 integrally interlocking therewith also rotates interlocking.

As shown in the drawing, the chain 36 is coupled to a plurality of rollers 361 by simple connecting rods 362 and coupled in the form of an endless track, and one connecting rod 362 is connected to the chute 30. A connecting means 364 is configured, and the other connecting rod 362 is composed of a pair of shafts 363-1 and a pair of wheels 363-2 that rotate in conjunction with the pair of shafts 363-1. Make sure roller 363 is included.

The support rail 11 is composed of a support body 111 interlocking with the roller 361 and a separation prevention edge 112 protruding from the outside of the support body 111 and interlocking with the transverse roller 363.

In this way, the support body 111 supports the roller 361 so that the end of the chute 30 is supported, and at the same time, the separation prevention rim 112 supports the transverse roller 363 from the outside, so that the chute ( 30) or the chute plate 32 can be controlled to be detached in the transverse direction.

As shown in FIG. 2 or 3, the chute support rail part 50 is provided in parallel with the feeder frame 10 between the roller parts 20 provided side by side in the longitudinal direction of the feeder frame 10, The reinforcing plate 34 can be supported.

The chute support rail part 50 is provided on the rail fixing bracket 52 fixed to the feeder frame 10 and the rail fixing bracket 52 to make surface contact with the reinforcing plate 34, and the chute 30 It may include a rail 54 for guiding in the transport direction of.

The rail fixing bracket 52 has an H-beam shape in vertical cross section, one side of which the feeder frame 10 is fixed and supported, and the other side facing the chute 30 so that the rail 54 can be provided. there is.

The rail 54, one side is seated on the other surface of the rail fixing bracket 52 and fixedly supported, and the other side is provided in surface contact with the reinforcing plate 34 to support and guide the chute 30 in the transport direction. can do.

The rail 54 may have an area of one side larger than that of the other side to expand a support surface. Accordingly, the fixing force can be improved. The rail 54 has an area of the other side smaller than that of the one side, but is provided to have an area capable of supporting the reinforcing plate 34 and can slide while supporting the reinforcing plate 34 . The rail 54 may have a predetermined curvature at both ends of a surface supporting the reinforcing plate 34 .

According to this chute support rail part 50, the reinforcing plate 34 is supported by the rail 54 on both sides of the side end surface of the reinforcing plate 34, respectively, and the reinforcing plate 34 is deflected to one side. It is possible to stably support the chute 30 by not being.

Meanwhile, a support plate 35 may be provided between the chute plate 32 and the reinforcing plate 34 . One surface of the support plate 35 may be attached to the chute plate 32 and the other surface may be provided facing the roller unit 20 or the chute support rail unit 50 . The support plate 35 may be provided on the other surface of the support plate 35 at a predetermined interval to correspond to the roller unit 20 and the chute support rail unit 50 .

Although the preferred embodiments of the present invention have been described in detail above, the present invention is not limited thereto, and those skilled in the art using the basic concept (technical idea) of the present invention defined in the following claims Various modifications and improvements are possible and will be said to belong to the scope of the present invention, and the specific protection scope of the present invention will be clarified by the appended claims.

10: feeder frame
20: roller part
30: suit
40: chute support
50: Chute support rail part

Claims (10)

A pair of feeder frames provided in parallel with each other;
Roller units having groove-shaped guide grooves formed around the outer circumferential surface and spaced at predetermined intervals in the longitudinal direction between the feeder frames;
a chute in which a portion of a chute plate provided with a reinforcing plate seated in the guide groove is provided so as to overlap each other so as to be transportable in the longitudinal direction of the feeder frame; and
The apron feeder comprising a; chute support for supporting the reinforcing plate during sliding of the chute between the rollers.
According to claim 1,
The apron feeder comprising a; chute support rails provided in parallel with the feeder frame between the rollers provided side by side in the longitudinal direction of the feeder frame to support the reinforcing plate.
According to claim 1,
The chute support part,
A plurality of fixing brackets fixed to the feeder frame and spaced apart from each other, provided on the fixing brackets in parallel with the outer circumferential surface of the guide groove, and contacting and supporting the reinforcing plate when the chute slides, thereby reinforcing the reinforcement through the guide groove. An apron feeder comprising a reinforcing plate support member for guiding the plate.
According to claim 3,
The apron feeder, characterized in that the end of the reinforcing plate support member and the end of the reinforcing plate opposite to it form a curved surface facing each other.
According to claim 3,
An apron feeder, characterized in that a filling space is formed inside between the reinforcing plate support members and a spacer member having a plurality of through holes formed on the lower surface is formed, and the sound absorbing material is filled in the filling space.
According to claim 3,
The chute plate,
The first surface on which the article is seated and the second surface opposite to the roller part are provided with the reinforcing plate, and the front and rear ends of the seating part in the sliding direction have a predetermined curvature toward the first surface, respectively. An apron feeder comprising a connector provided in a protruding hemispherical shape.
According to claim 6,
The apron feeder, characterized in that the connector of one chute plate overlaps each other in the form of being stacked with the connector of the other chute plate, but the end of the connector located on the upper part is composed of an elastic material to prevent jamming.
According to claim 3,
The distance between the central axis of the guide groove and the end of the reinforcing plate support member is adjusted so that a part of the reinforcing plate is supported by the reinforcing plate support member when the reinforcing plate passes through the guide groove while the chute plate is moving Apron Feeder.
According to claim 1,
Chains connected to sprocket shafts are formed at both ends of the chute, and the chains are connected by connecting rods between rollers to form an endless track, and at both ends of the feeder frame are support rails for supporting the rollers of the chain. Apron feeder, characterized in that configured.
According to claim 9,
An apron feeder, characterized in that a separation prevention rim protrudes from an outer surface of the support rail, and a transverse roller in contact with the separation prevention rim is further configured in the connecting rod.

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