KR102249944B1 - Device for loading conveying material of conveyor belt - Google Patents

Abstract

A conveyor belt conveying object loading device is disclosed. Conveyor belt transport material loading apparatus according to an embodiment of the present invention is disposed on the upper side of the transfer belt portion of the conveyor belt, the discharge chute for guiding the discharge of the transport material from the top to the bottom; A variable width member installed on the inner surface of the discharge chute and advancing and retreating in the width direction to change the inner width of the discharge chute; A variable width driving unit for advancing and retreating the variable width member; A driven roller rotating in contact with the return belt portion of the conveyor belt; And a power transmission device that transmits the rotation of the driven roller to a power source of the variable width driving unit.

Description

Conveyor belt loading device {DEVICE FOR LOADING CONVEYING MATERIAL OF CONVEYOR BELT}

The present invention relates to a conveyor belt transport object loading device capable of minimizing eccentric loading of transported objects and preventing falling or scattering of transported objects.

In industrial sites such as steel mills, belt-type conveyor devices are used as a means of transporting transported goods such as iron ore and coke. A typical belt-type conveyor device includes a caterpillar conveyor belt, a driving roller and a driven roller, and a plurality of support rollers.

The conveyor belt can be divided into an upper conveying belt part for conveying the conveyed material and a lower return belt part conveying after conveying the conveyed material. The conveyed material is supplied in a manner that is dropped on the upper part of the conveying belt moving from the supply chute. Since the falling conveyed material may contain lumps, the conveyed material may sometimes be eccentrically loaded or dropped to one side.

Eccentric loading of the conveyed material may cause failure of the support roller because the load is concentrated on a specific support roller that supports the conveyor belt, and may cause the conveyor belt to meander, resulting in equipment damage.

An aspect of the present invention is to provide a conveyor belt transport object loading device capable of minimizing eccentric loading of transported objects and preventing falling or scattering of transported objects.

Another aspect of the present invention is to provide a conveyor belt conveying material loading device capable of implementing even loading of conveyed material by crushing a lump during the dropping process of the conveyed material.

According to an aspect of the present invention, the discharge chute is disposed on the upper side of the conveying belt part of the conveyor belt, and guides the discharge of the conveyed material from the top to the bottom; A variable width member installed on the inner surface of the discharge chute and advancing and retreating in the width direction to change the inner width of the discharge chute; A variable width driving unit for advancing and retreating the variable width member; A driven roller rotating in contact with the return belt portion of the conveyor belt; And a power transmission device for transmitting the rotation of the driven roller to a power source of the variable width driving unit.

The conveyor belt transport object loading device includes: a collection case that covers the outside of the discharge chute to prevent scattering of dust or falling of the transport object; A guide chute installed above the discharge chute inside the collection case and guiding the conveyed material supplied from the outside to an upper entrance of the discharge chute; And a discharge duct connected to the collection case.

The variable width driving unit at least one advancing and retreating rod extending from the variable width member to the outside through the discharge chute; A pressing plate coupled to the advancing and retreating rod extending outside the discharge chute; An eccentric cam for advancing and retreating the pressing plate by eccentric rotation; An elastic member for moving the pressure plate in the eccentric cam direction; And a rotation device that receives rotation from the power transmission device and rotates the eccentric cam.

The rotating device includes a fixed gearbox; A drive shaft installed on the gearbox and connected to the power transmission device; A drive bevel gear installed on the drive shaft inside the gearbox; A driven bevel gear engaged with the driving bevel gear in the gearbox; And a driven shaft connected to the driven bevel gear and extending outside the gearbox and connected to the eccentric cam.

The power transmission device includes a drive sprocket installed on the shaft of the driven roller; A driven sprocket installed on the shaft of the rotating device; And a chain caught on the driving sprocket and the driven sprocket.

The variable width member may include a first variable width member and a second variable width member respectively installed on the inner surfaces of opposite sides of the discharge chute, and the variable width driving part comprises the first and second variable width members, respectively. It may include a first variable width driving unit and a second variable width driving unit to advance and retreat.

The conveyor belt conveying object loading device according to an embodiment of the present invention can realize smooth and uniform discharge of the conveyed material passing through the discharge chute because the width variable member inside the discharge chute changes the inner width of the discharge chute as it advances and retreats, Through this, it is possible to minimize eccentricity and uneven loading of the conveyed material.

In the conveyor belt transport object loading apparatus according to an embodiment of the present invention, since the first and second variable width members crush the transport object in the form of a lump in the process of dropping the transport object onto the conveyor belt, even loading of the transport object can be realized. .

In the conveyor belt loading device according to an embodiment of the present invention, since the first and second variable width driving units are operated by driven rollers that rotate by the transfer of the conveyor belt, the first and second widths are variable without a separate power source. You can implement the advance and retreat of the absence.

In the conveyor belt loading device according to an embodiment of the present invention, since the collection case covers the outside of the guide chute and the discharge chute, it is possible to prevent dust from scattering or falling of the conveyed material around during the loading process of the conveyed material.

1 is a perspective view of a belt-type conveyor to which a conveyor belt transport object loading device according to an embodiment of the present invention is applied.
2 is a cross-sectional view of a conveyor belt transport object loading device according to an embodiment of the present invention.
3 is a detailed view of a main part of a conveyor belt transport object loading device according to an embodiment of the present invention.
4 is a cross-sectional view taken along line IV-IV' of FIG. 3.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following examples are presented in order to sufficiently convey the spirit of the present invention to those of ordinary skill in the art to which the present invention pertains, and may be embodied in other forms without being limited thereto. In the drawings, in order to clarify the present invention, the illustration of parts not related to the description may be omitted, and the size of the components may be slightly exaggerated to help understanding.

1 is a perspective view showing a conveyor belt transport object loading device according to an embodiment of the present invention, and Figure 2 is a cross-sectional view of the conveyor belt transport object loading device of FIG.

Referring to Figures 1 and 1, the conveyor belt 10 can be divided into an upper transfer belt section 11 for transporting transported items such as iron ore and coke, and a lower return belt section 12 that is returned after transporting the transported material. have. The transfer belt part 11 is supported by a plurality of upper support rollers 13 so that sagging does not occur in a state in which the conveyed material is loaded, and the return belt part 12 is also supported by a plurality of lower support rollers ( 14) can be supported by Each upper support roller 13 may include three rollers arranged in the width direction so as to support the lower surface of the transfer belt 11 in a curved shape, as shown in FIG. 2.

Referring to FIG. 2, the transport material loading device 100 includes a discharge chute 110, a guide chute 120, a collection case 130, first and second variable width members 141 and 142, and the first and second widths. Variable driving units 150 and 160, driven rollers 170, and first and second power transmission devices 180 and 190 may be included.

The discharge chute 110 is installed in a fixed state in the upper center of the transfer belt portion 11 of the conveyor belt 10, as shown in FIGS. 2 to 4, and guides the discharge of the conveyed material from the top to the bottom. The discharge chute 110 may be provided in the form of a square barrel with the upper inlet 111 and the lower outlet 112 open, and transfer the powder or granules falling through the inner conveyed material discharge passage 113. It can be guided to the center of the upper surface of the transfer belt portion 11 of the conveyor belt (10).

The guide chute 120 is installed on the top of the discharge chute 110 and is provided in the form of a funnel with a wide upper width and a narrow lower width, so that the conveyed material supplied from the outside is smoothly passed to the upper inlet 111 of the discharge chute 110. You can guide them to be supplied.

The collection case 130 may cover the outside of the discharge chute 110 and the guide chute 120 to prevent scattering of dust or falling of the conveyed material during the loading process of the conveyed material. The collection case 130 may accommodate the rest of the discharge chute 110 except for the lower outlet 112 in a sealed state.

A discharge duct 132 for discharging dust scattered in the collecting case 130 is connected to the upper part of the collecting case 130. The discharge duct 132 may have an outlet connected to a dust collector (not shown).

Vibration supply devices 103 and 104 may be installed on both sides of the upper side of the collection case 130 to supply the transported material inputted to the external supply hoppers 101 and 102 to the upper part of the guide chute 120 inside the collection case 130, respectively. The conveyed material inputted to the external supply hoppers 101 and 102 may be supplied to the top of the guide chute 120 by the vibration supplying devices 103 and 104, and pass through the guide chute 120 and the discharge chute 110 to pass through the conveyor belt 10 ) Of the transfer belt portion 11 can be dropped to the center of the upper surface.

The first and second variable width members 141 and 142 are installed on both inner surfaces of the discharge chute 110 facing each other, as shown in FIGS. 3 and 4, and advance and retreat in the width direction to the inside of the discharge chute 110. The width of the conveyed material discharge passage 113 can be varied. The first and second variable width members 141 and 142 may be provided in a substantially flat plate shape, and may have a width and a height corresponding to the inner surfaces of both sides of the discharge chute 110.

The first variable width driver 150 and the second variable width driver 160 advance and retreat the first and second variable width members 141 and 142 respectively installed on both sides of the discharge chute 110 in the width direction. The transport object loading device 100 of the present embodiment includes a first variable width driving unit 150 and a second variable width driving unit 160 to drive the first variable width member 141 and the second variable width member 142, respectively. However, if one variable width member is installed in the discharge chute 110, there may be one variable width driving unit that drives it.

As shown in FIGS. 2 to 4, the first variable width driving unit 150 passes through the discharge chute 110 and the collection case 130 from the first variable width member 141, and extends to the outside. The advance and retreat rods (151, 152) of the collection case 130, the pressing plate 153 coupled to the advance and retreat rods (151, 152) extending outward, the eccentric cam 154 for advancing and retreating the pressing plate 153 by eccentric rotation It may include an elastic member 155 for moving in the direction of the eccentric cam 154, a rotation device 158 for rotating the eccentric cam 154 by receiving rotation from the first power transmission device 180.

On the inclined outer surface of the collection case 130, a support plate 156 for installation of the first variable width driving unit 150 is installed, and the advance and retreat rods 151 and 152 at the upper and lower portions are the discharge chute 110 and the collection case 130. ), through the support plate 156 and supported to be slidable. In the present exemplary embodiment, the first variable width member 141 and the pressing plate 153 are connected by two advance and retreat rods 151 and 152 provided parallel to each other at the upper and lower portions, but there may be one or more advance and retreat rods.

The elastic member 155 may be a compression coil spring installed between the pressure plate 153 and the support plate 156 to move the pressure plate 153 in the eccentric cam 154 direction, and the elastic member 155 in the pressure plate 153 A support shaft 157 that is installed in parallel with the advancing and retreating rods 151 and 152 to support and slidably supported on the support plate 156 may be provided.

The rotating device 158 is installed in the gearbox 158a and the gearbox 158a fixed to the fixing member 159 extending from the collection case 130, as shown in FIG. A drive shaft 158b connected to 180, a drive bevel gear 158c installed on the drive shaft 158b inside the gearbox 158a, and a driven bevel gear engaged with the drive bevel gear 158c in the gearbox 158a ( 158d), the shaft line may include a driven shaft 158e installed on the gearbox 158a in a direction crossing the drive shaft 158b and connecting the driven bevel gear 158d and the eccentric cam 154.

As shown in FIG. 2, the driven roller 170 is installed to come into contact with the return belt portion 12 of the conveyor belt 10 and rotates by the transfer of the return belt portion 12. The first and second power transmission devices 180 and 190 are installed on opposite sides to transmit the rotation of the driven roller 170 to the first variable width driving unit 150 and the second variable width driving unit 160. The first and second power transmission devices 180 and 190 transmit the rotation of the driven roller 170 to be used as a power source for the first and second variable width driving units 150 and 160.

The first power transmission device 180 includes a driving sprocket 181 installed on one axis of the driven roller 170, and a driven sprocket 182 installed on the driving shaft 158b of the rotating device 158 of the first variable width driving unit 150. ), including a caterpillar chain 183 caught on the driving sprocket 181 and the driven sprocket 182.

When the driven roller 170 rotates by the movement of the conveyor belt 10, the first variable width driving unit 150 operates the rotation device 158 by the first power transmission device 180, and the eccentric cam 154 The first width variable member 141 in the discharge chute 110 is moved forward and backward by rotating the eccentric cam 154 and advancing and retreating the pressure plate 153 while the eccentric cam 154 rotates.

The second variable width drive unit 160 has the same configuration and operation principle as the first variable width drive unit 150 only in a different installation position, and the second power transmission device 190 is also the same as the first power transmission device 180 Do. Therefore, the first variable width member 141 and the second variable width member 142 on both sides of the discharge chute 110 may advance and retreat at the same time.

When the driven roller 170 is rotated by the operation of the conveyor belt 10, the conveying object loading device 100 has a first variable width member 141 and a second variable width member 142 inside the discharge chute 110. As) moves forward and backward at the same time, since the inner width of the discharge chute 110 is varied, smooth discharge of the conveyed material passing through the discharge chute 110 can be implemented. When the conveyed material is discharged smoothly, since the conveyed material is uniformly loaded on the conveying belt part 11 of the conveyor belt 10, eccentricity and uneven loading of the conveyed material can be minimized. This is because the amount of delivery per unit time of the transported material dropped from the discharge chute 110 onto the transport belt 11 becomes uniform.

The transported object loading device 100 is transported because the first and second variable width members 141 and 142 crush the transported object in the form of a lump in the process of dropping the transported object to the transport belt portion 11 of the conveyor belt 10. It can realize even loading of water. In addition, since the first and second variable width driving units 150 and 160 are operated by the driven roller 170 that rotates by the transfer of the conveyor belt 10, the first and second variable width members 141 and 142 without a separate power source. Can be implemented.

The transported object loading device 100 can prevent dust from scattering around or falling of the transported object during the loading process of the transported object because the collection case 130 covers the outside of the guide chute 120 and the discharge chute 110. have.

10: conveyor belt, 11: transfer belt part,
12: return belt portion, 100: loading device to be transported,
110: discharge chute, 120: guide chute,
130: collection case, 141: first width variable member,
142: second variable width member, 150: first variable width driving unit,
151,152: advance and retreat rod, 153: pressure plate,
154: eccentric cam, 155: elastic member,
158: rotating device, 160: a second variable width driving unit,
170: driven roller, 180: first power transmission device,
190: second power transmission device.

Claims (6)

A discharge chute disposed above the conveying belt part of the conveyor belt and having a conveyed material discharge passage for discharging the conveyed material to the center of the upper surface of the conveying belt part by guiding the discharging of the conveyed material from the top to the bottom;
A guide chute installed on the top of the discharge chute and guiding the transported material supplied from the outside to the upper inlet of the discharge chute;
A variable width member installed on the inner surface of the discharge chute and advancing and retreating in the width direction to change the inner width of the conveyed material discharge passage of the discharge chute;
A variable width driving unit for periodically advancing and retreating the variable width member;
A driven roller rotating in contact with the return belt portion of the conveyor belt; And
Conveyor belt transport material loading device comprising a; power transmission device for transmitting the rotation of the driven roller to the power source of the variable width driving unit. The method of claim 1,
A collection case that covers the outer side of the discharge chute and the guide chute to prevent scattering of dust or falling of the conveyed material; And
Conveyor belt transport material loading device further comprising a; discharge duct connected to the collection case. The method of claim 1,
The variable width driving part,
At least one advancing rod extending from the variable width member to the outside through the discharge chute;
A pressing plate coupled to the advancing and retreating rod extending outside the discharge chute;
An eccentric cam for advancing and retreating the pressing plate by eccentric rotation;
An elastic member for moving the pressure plate in the eccentric cam direction; And
Conveyor belt transport material loading device comprising a; rotation device for rotating the eccentric cam by receiving the rotation from the power transmission device. The method of claim 3,
The rotating device,
Fixed gearbox;
A drive shaft installed on the gearbox and connected to the power transmission device;
A drive bevel gear installed on the drive shaft inside the gearbox;
A driven bevel gear engaged with the driving bevel gear in the gearbox; And
And a driven shaft connected to the driven bevel gear and extending outside the gearbox and connected to the eccentric cam. The method of claim 3,
The power transmission device,
A driving sprocket installed on the shaft of the driven roller;
A driven sprocket installed on the shaft of the rotating device; And
Conveyor belt conveying object loading device comprising a; chain caught on the driving sprocket and the driven sprocket. The method of claim 1,
The variable width member includes a first variable width member and a second variable width member respectively installed on inner surfaces of opposite sides of the discharge chute,
The conveyor belt transport material loading device including a first variable width driving unit and a second variable width driving unit for advancing and retreating the first and second variable width members, respectively.

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