KR101424446B1 - Chute for belt conveyor - Google Patents

Abstract

The present invention relates to a chute for a belt conveyor, wherein a chute for conveying a belt includes a duct unit disposed at an end of a supply conveyor for guiding a product to be dropped through a supply conveyor, the duct unit having a through portion opened to discharge accumulated products therein; A sensing unit for sensing a conveyed object discharged from the penetrating portion; And a control unit for receiving the sensing signal generated by the sensing unit and controlling operation of the supply conveyor; And a control unit.

Description

Suit for Belt Conveyor {CHUTE FOR BELT CONVEYOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a belt conveyor chute, and more particularly, to a belt conveyor chute capable of preventing the operation rate of the equipment from being lowered by sensing the accumulation of the conveyed material in the duct unit, .

Generally, feeds such as fuel or raw materials used in steel mills are transported to a desired location by a plurality of belt conveyors.

Since the length of the belt conveyor can not be made infinite, a chute is provided between the belt conveyor and the belt conveyor.

The chute serves to connect the belt conveyor by forming a duct shape to guide the conveyed matter, which is conveyed from one of the belt conveyors, to fall onto the other one of the belt conveyors.

A related prior art is Korean Patent Registration No. 0870904 (Registered on Nov. 21, 2008, entitled "Chute of belt conveyor equipped with damper device").

SUMMARY OF THE INVENTION An object of the present invention is to provide a chute for a belt conveyor capable of preventing the operation rate of the equipment from being lowered by detecting the accumulation of the conveyed material in the duct unit and stopping the supply conveyor.

In order to accomplish the above object, according to the present invention, there is provided a belt conveyor chute, which is disposed at an end of a supply conveyor, guides a conveyed object dropped through the feed conveyor, unit; A sensing unit for sensing the transported material discharged from the penetration unit; And a control unit for receiving the sensing signal generated by the sensing unit and controlling operation of the supply conveyor. And a control unit.

Here, the duct unit may include an overflow unit for guiding the discharged material discharged from the penetrating unit to the sensing unit.

Here, the sensing unit may include: a receiving member for accumulating the conveyed material discharged through the penetrating portion; And a sensing member for generating a sensing signal by a load of the receiving member due to accumulation of the conveyed object; And a control unit.

Here, the sensing member may include a sensing unit provided in one of the duct unit and the accommodation member to generate a sensing signal; And a signal unit which is provided on the other of the duct unit and the housing member and transmits the movement amount of the housing member to the sensing unit; And a control unit.

Here, the sensing unit may include: a support member coupled to the duct unit such that the receiving member is coupled and seesaw around a pivot axis; And further comprising:

Here, the sensing unit may include: an elastic member coupled to the duct unit to elastically support the housing member; And further comprising:

Here, the sensing unit may include a connecting member for allowing the receiving member to be detached and attached at one end of the supporting member; And further comprising:

As described above, the belt conveyor chute according to the present invention can prevent the operation rate of the equipment from being lowered by stopping the supply conveyor by detecting accumulation of the conveyed material in the duct unit.

In addition, the present invention can detect the overflow of the conveyed material in the duct unit by detecting accumulation of the conveyed material in the duct unit, and prevent the facility from being damaged due to the overflow phenomenon have.

In addition, the present invention can reduce the maintenance cost of facilities damaged by the conveyance.

In addition, the present invention can prevent scattering of the discharged discharged material when discharging accumulated matter inside the duct unit, and reduce measurement error of the discharged discharged material.

In addition, the present invention can absorb an impact caused by a discharged article to be conveyed, suppress or prevent a false detection signal from being generated, and prevent the control unit from malfunctioning.

Further, the present invention can detachably attach the receiving member and simplify the processing of the conveyed matter accumulated in the receiving member.

1 is a perspective view showing a chute for a belt conveyor according to an embodiment of the present invention,
2 is an exploded perspective view illustrating a sensing unit in a belt conveyor chute according to an embodiment of the present invention,
3 is a view illustrating a state of engagement of a chute for a belt conveyor according to an embodiment of the present invention,
4 is a view showing an operation state of a belt conveyor chute according to an embodiment of the present invention.

Hereinafter, an embodiment of a belt conveyor chute according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a perspective view showing a chute for a belt conveyor according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view illustrating a sensing unit in a chute for a belt conveyor according to an embodiment of the present invention.

1 and 2, a belt conveyor chute according to an embodiment of the present invention guides a conveyance M conveyed through a conveying conveyor V1 to a conveying conveyor V2.

The chute for a belt conveyor according to an embodiment of the present invention includes a duct unit 10, a sensing unit 30, and a control unit 90.

The duct unit 10 can be disposed at the end of the supply conveyor V1. The duct unit 10 guides the conveyance M falling through the feed conveyor V1.

Then, the material M is fed into the duct unit 10 through the inlet 11, discharged through the outlet 13, and transferred to the conveying conveyor V2.

Here, the duct unit 10 may be provided with a damper 20 for adjusting the amount of the conveyed material M to be fed. The damper 20 is rotatably coupled through the rotary shaft 21 and the amount of rotation of the damper 20 can be adjusted through the adjustment part 23 provided at one side.

The damper 20 can prevent the generation of the attached charcoal generated when the conveyed object M falls, and can prevent the clogging of the chute.

The duct unit (10) has an opening (15). The penetrating portion 15 allows the discharged material M accumulated in the duct unit 10 to be discharged by a hole opened at one side of the duct unit 10.

The penetration portion 15 allows a part of the transferred matter M to be accumulated to be discharged when the transferred matter M accumulates in the duct unit 10. Here, the size and opening position of the penetrating portion 15 are not limited.

Here, the overflow portion 17 is provided in the penetrating portion 15.

The overflow portion 17 forms a path of movement of the conveyed material M discharged from the through portion 15. [ The overflow portion 17 may be provided so as to be inclined downward from the penetrating portion 15. [

The overflow portion 17 can deliver the discharged material M discharged through the penetrating portion 15 to the housing member 40 without loss.

The transported matter M discharged from the penetration portion 15 is moved along the overflow portion 17 and accumulated in the sensing unit 30. [

The sensing unit (30) senses the conveyance (M) discharged from the penetration part (15).

The sensing unit (30) includes a receiving member (40) and a sensing member (50).

The receiving member (40) accumulates the articles (M) discharged through the penetrating portion (15). The receiving groove 40 may be recessed in the receiving member 40 so that the discharged article M can be stably accumulated without loss.

The housing member 40 may be provided with a connection portion 42 for connection with the support member 60.

Here, the connection portion 42 may be formed to protrude from the housing member 40. Then, the connection portion 42 is inserted into the first connection portion 81 formed in the connection member 80 to be described later.

On the other hand, although the connection portion 42 is not shown, it may be recessed in the housing member 40. Then, the first coupling portion 81 protruding from the coupling member 80, which will be described later, is inserted into the coupling portion 42.

The sensing member 50 generates a sensing signal by the load of the receiving member 40 in accordance with the accumulation of the articles M to be conveyed.

The sensing member 50 includes a sensing unit 52 and a signal unit 51. The sensing unit 52 is provided in the duct unit 10 to generate a sensing signal. The signal unit 51 may be provided on a support member 60 to be described later and may transmit the movement amount of the housing member 40 to the sensing unit 52. [

The signal unit 51 is moved in accordance with the load of the conveyed object accumulated in the receiving member 40 and the moved signal unit 51 contacts the sensing unit 52 so that the sensing unit 52 generates a sensing signal .

Here, when the sensing unit 30 does not include the supporting member 60, the signal portion 51 may be provided in the receiving member 40.

Although not shown, the sensing unit 52 may be provided in a support member 60, which will be described later, so that the signal unit 51 may be provided in the duct unit 10. [

Also, although not shown, the sensing unit 52 may be provided in the housing member 40, so that the signal unit 51 may be provided in the duct unit 10.

The sensing unit 30 may further include a support member 60.

The support member 60 is coupled to the duct unit 10 such that the housing member 40 is engaged and seesaw around the pivot shaft 62. [

More specifically, the supporting member 60 has the receiving member 40 at one end and the signal unit 51 at the other end. The supporting member 60 is coupled to the duct unit 10 by pivoting the pivot shaft 62 so that the pivot shaft 62 is seesawed to the supporting portion 61 provided in the duct unit 10. [

When the connecting portion 42 of the housing member 40 has a groove shape, one end of the supporting member 60 can be fitted into the groove-like connecting portion 42. [

The sensing unit 30 may further include an elastic member 70.

The elastic member (70) is coupled to the duct unit (10) so that the housing member (40) is resiliently supported.

First, the elastic member 70 elastically supports the support member 60 as shown in the figure, so that the accommodation member 40 can be resiliently supported.

The elastic member 70 includes a fixing portion 71 coupled to the duct unit 10 and an elastic portion 72 coupled to the fixing portion 71 to elastically support the supporting member 60.

The elastic member 70 absorbs the impact applied to the receiving member 40 in accordance with the drop of the conveyed product M when the conveyed product M is accumulated in the receiving member 40, It is possible to prevent an erroneous detection signal from being generated.

Alternatively, although not shown, the elastic member 70 can elastically support the receiving member 40 directly. Then, the fixing portion 71 is coupled to the duct unit 10, and the elastic portion 72 elastically supports the housing member 40 directly.

The sensing unit 30 may further include a connecting member 80.

The connecting member 80 allows the receiving member 40 to be detached and attached at one end of the supporting member 60. [

The connection member 80 is provided with a first engagement portion 81 to which the housing member 40 is coupled and a second engagement portion 82 to which one end of the support member 60 is coupled, It is possible to fix the one end of the supporting member 60 and the receiving member 40 coupled to the connecting member 80 through the through hole.

More specifically, the coupling portion 42 of the receiving member 40, which is a projection, is fitted to the first coupling portion 81, and the one end of the supporting member 60 is fitted to the second coupling portion 82.

The fixing pin portion 83 may fix the connecting portion 42 of the receiving member 40 and the one end portion of the supporting member 60 to the connecting member 80.

Here, the connecting member 80 may be integrally coupled to one end of the supporting member 60. [

Further, the connecting member 80 can be integrally coupled to the receiving member 40. Here, the connecting member 80 may be composed of the connecting portion 42 of the receiving member 40.

The control unit 90 receives the sensing signal generated in the sensing unit 30 and controls the operation of the supply conveyor V1.

When the sensing unit 30 generates a sensing signal according to the contact between the signal unit 51 and the sensing unit 52, the control unit 90 determines that the conveyance M is accumulated in the duct unit 10 do.

Then, the control unit 90 receives the detection signal and controls the operation of the supply conveyor V1 so that the supply conveyor V1 can be stopped.

Hereinafter, an operation method of the belt conveyor chute will be described.

FIG. 3 is a view showing a combined state of the chute for a belt conveyor according to an embodiment of the present invention, and FIG. 4 is a view showing an operation state of the chute for a belt conveyor according to an embodiment of the present invention.

Referring to FIGS. 3 and 4, the duct unit 10 is provided with an overflow portion 17 so as to communicate with the penetrating portion 15 and the penetrating portion 15 is opened.

The receiving member 40 is positioned below the overflow portion 17 so that the conveyed matter M discharged through the penetrating portion 15 can be accumulated. The housing member 40 is detachably coupled to one end of the support member 60 coupled to the duct unit 10 so as to be able to seethe movement.

A signal part 51 is provided at the other end of the supporting member 60 and a sensing part 52 is coupled to the duct unit 10 at a position above the signal part 51 by a signal part 51.

Here, the conveyed material M conveyed through the feed conveyor V1 is conveyed to the conveying conveyor V2 via the duct unit 10 and conveyed to the next place.

The transferred material M is dropped from the duct unit 10 through the inlet port 11 and discharged to the discharge port 13.

When the discharge port 13 is clogged, the conveyed matter M accumulates in the duct unit 10. The accumulated matter M accumulated in this manner is discharged through the penetrating portion 15. [ So that a part of the discharged material M accumulated in the duct unit 10 is discharged through the penetrating portion 15. [

The articles M discharged from the penetrating portion 15 are accumulated in the receiving member 40 via the overflow portion 17. [

The signal portion 51 can be moved by the load of the housing member 40 and contact the sensing portion 52. [

Specifically, the receiving member 40 is lowered by the conveyance M accumulated in the receiving member 40. Then, as the support member 60 is seesawed about the pivot shaft 62, the signal portion 51 is raised.

The raised signal portion 51 contacts the sensing portion 52 and generates a sensing signal in the sensing portion 52 due to the contact between the signal portion 51 and the sensing portion 52.

Since the load of the receiving member 40 increases with an increase in the amount of the conveyed object M, the contact state between the signal unit 51 and the sensing unit 52 can be maintained.

Then, the control unit 90 receives the detection signal and stops the supply conveyor V1.

When the signal unit 51 and the sensing unit 52 maintain the contact state in consideration of the contact time due to the contact between the signal unit 51 and the sensing unit 52, the control unit 90 controls the supply conveyor V1 It can be stopped.

Here, the contact time can be set according to the type of the material M to be conveyed or the installation place.

For example, when the conveyed product M passes through the penetrating portion 15 and accumulates in the receiving member 40, the impact due to the drop of the conveyed product M can be transmitted to the receiving member 40. [

Due to such an impact, the signal portion 51 may be suddenly raised and brought into contact with the sensing portion 52. However, since the elastic member 70 elastically supports the support member 60 to absorb the shock, the signal portion 51 is prevented from suddenly rising, and when the signal portion 51 is raised, Can be suppressed or prevented.

Here, since the sensing signal due to the contact between the signal unit 51 and the sensing unit 52 is smaller than the contact time set in the control unit 90, even if the signal unit 51 and the sensing unit 52 come into contact with each other due to the impact, (90) does not stop the supply conveyor (V1).

It can be confirmed that the conveyance M is accumulated in the duct unit 10 as the supply conveyor V1 is stopped.

Then, the discharged material M accumulated in the duct unit 10 is processed so that the inlet 11 and the outlet 13 of the duct unit 10 are communicated with each other. And, by restarting the supply conveyor V1, the duct unit 10 can guide the conveyed material M stably.

It is also possible to easily remove the accumulated matter M accumulated on the receiving member 40 by separating the receiving member 40 on which the conveyed product M is accumulated from the supporting member 60. [ The separated receiving member 40 can be coupled to the supporting member 60 again.

Then, the housing member 40 returns to the home position, and the signal unit 51 and the sensing unit 52 are separated from each other, so that the sensing unit 30 can sense over-accumulation of the duct unit 10 again.

According to the above-described belt conveyor chute, it is possible to prevent the operation rate of the equipment from being lowered by stopping the supply conveyor V1 by detecting accumulation of the conveyed material M in the duct unit 10. [

Further, the present invention can detect the overflow phenomenon of the conveyed material (M) in the duct unit (10) by detecting accumulation of the conveyed material (M) inside the duct unit (10) It is possible to prevent the equipment from being damaged due to the conveyed object M due to the conveyance.

Further, the present invention can reduce the maintenance cost of equipment damaged by the material M to be conveyed.

The present invention also prevents scattering of discharged discharged material M when the discharged material M accumulated in the duct unit 10 is discharged to the through portion 15 and discharges the discharged discharged material M ) Can be reduced.

In addition, the present invention can absorb an impact caused by the discharged conveyed object M, suppress or prevent a false detection signal from being generated, and prevent the control unit 90 from malfunctioning.

Further, the present invention can detachably attach the receiving member 40, and it is possible to simplify the processing of the conveyed product M accumulated in the receiving member 40. [

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the claims.

10: duct unit 11: inlet
13: outlet 15:
17: Overflow section 20: Damper
21: Pivot shaft 23:
30: sensing unit 40: housing member
41: receiving groove 42:
50: sensing member 51: signal part
52: sensor part 60: support member
61: support part 62: pivot shaft
70: elastic member 71:
72: elastic portion 80: connecting member
81: first insertion hole 82: second insertion hole
83: Fixing pin part 90: Control unit
V1: Feed conveyor V2: Feed conveyor
M: Feed

Claims (7)

A duct unit disposed at an end of the supply conveyor and guiding a transported product falling through the supply conveyor, wherein the duct unit is opened so as to discharge the transported product accumulated therein;
A sensing unit for sensing the transported material discharged from the penetration unit; And
A control unit for receiving the sensing signal generated by the sensing unit and controlling the operation of the supply conveyor; / RTI >
The sensing unit includes:
A receiving member for accumulating the conveyed material discharged through the penetrating portion; And
A sensing member for generating a sensing signal by a load of the accommodating member in accordance with accumulation of the conveyed object; And a belt conveyor for conveying the belt conveyor.
The method according to claim 1,
Wherein the duct unit includes an overflow portion for guiding the conveyed material discharged from the through portion to the sensing unit.
delete The method according to claim 1,
Wherein the sensing member comprises:
A sensing unit provided in any one of the duct unit and the accommodation member to generate a sensing signal; And
A signal unit provided on the other of the duct unit and the receiving member and transmitting a movement amount of the receiving member to the sensing unit; And a belt conveyor for conveying the belt conveyor.
The method according to claim 1,
The sensing unit includes:
A supporting member to which the housing member is coupled and is coupled to the duct unit so as to be seesawed about a pivot axis; Further comprising: a belt conveyor for conveying the belt conveyor.
The method according to any one of claims 1, 4, and 5,
The sensing unit includes:
An elastic member coupled to the duct unit to elastically support the housing member; Further comprising: a belt conveyor for conveying the belt conveyor.
The method according to any one of claims 1, 4, and 5,
The sensing unit includes:
A connecting member for allowing the receiving member to be detached and attached at one end of the supporting member; The belt conveyor according to claim 1, further comprising:

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