KR200184033Y1 - An apparatus for correcting the declining of the material - Google Patents

Abstract

The present invention is a knitting correction device for preventing the belt conveyor for rotating the belt by using a roller and transporting the transport material using the belt in one side, it is installed on both sides of the belt and the upper part of the belt Side rollers which are moved outwardly by the belt when the raw material is in one side, and a pair of opposing one gears which rotate as the side rollers are moved to one side, and meshes with the first gear A pair of opposing two-stage gears that rotate in a direction opposite to the rotational direction of the first-stage gears, and self-aligning rollers that are vertically fixed to the lower portion of the rollers supporting the lower portion of the belt and rotated by the rotation of the second-stage gears. And a lower portion of the self-aligning roller shaft to rotate together with the self-aligning roller shaft. And a chain gear connected between a pair of turn self-aligning gears, the pair of two-stage gears facing each other, and the self-aligning roller shaft to transfer the power of the second gear to the self-aligning roller shaft. When moving the automatic watch roller is rotated by the side rollers when moving the gist correcting device that can prevent the phenomenon that the belt is leaned to one side.

Description

An apparatus for correcting the declining of the material}

The present invention relates to a knitting correction device, and in particular, when a transport carried by a belt conveyor is moved to another belt conveyor, the belt is automatically adjusted so that the transport is loaded at the center of the belt so that the transport can be moved to any part of the belt. The present invention relates to a knitting correction device using a reduction device designed to prevent the belt from meandering even if it is carried.

1 is a view showing the principle of the belt conveyor for transporting the shipment, Figure 2 is a view showing the cross section of the belt conveyor, Figure 3 is a view showing the cause of the meandering of the belt due to the loading of the shipment, Figure 4 is a conventional This is a drawing showing the roller device and the operating principle for adjusting the meandering of the belt. In the case of continuously transporting lead, raw materials and large quantities of transported goods in facilities such as steel mills, a belt conveyor is used to carry out the transport work before the dropping process. It carries out the transport by connecting several belt conveyors to the required place.

When a shipment is moved from the chute connecting the belt conveyor to another belt conveyor, when the shipment is loaded to one side as shown in Figures 3-1 and 3-4, the belt As the transport moves to the center, the belt meanders left and right.

Due to this, there were problems such as belt side damage, belt stoppage, falling light, and the like. In order to solve these problems, a 4-4 self-aligning carrier roller and a 4-3 self-aligning return roller were installed. When self-aligning carrier roller meanders to the belt as shown in Fig. 4-1, the side roller moves to the diagonal direction about the center of the roller in the direction of belt movement by the frictional force between the side roller and the belt so that the meandering is adjusted. Due to the weight of the fuel and raw materials on the side and the force that meanders only on one side, it is virtually impossible to adjust the meandering automatically. It has been used to adjust the meandering, and only the upper carrier belt meandering is adjusted irrespective of the lower belt. Figure 4-3 Self-aligning return roller also moves the diagonally around the center of the roller so that the return belt can be adjusted.

However, only the return belt meander is adjusted irrespective of the upper belt on which the cargo is loaded. Therefore, according to the meandering state of the belt, a person pulls or pushes the self-aligning return roller by hand and fixes the meander by fixing it with a chain. There was this.

The present invention is to achieve the above object, the upper carrier belt by the reduction gear gear connected to the axis of the side roller is rotated and the upper belt side roller when the raw material is transferred to another belt conveyor Automatically meandering the lower and lower return belts at the same time and eliminating the causes of meandering, belt stoppage, belt side damage, and falling lights caused by cargo stacking to extend the service life of the equipment and lower the production cost. An object of the present invention is to provide a correction device that can prevent the occurrence of trouble.

The above-described object is a knitting correction device for preventing the belt conveyor for rotating the belt using a roller and transporting the transport material using the belt is prevented from being stacked to one side, it is provided on both sides of the belt and Side rollers which are moved outwardly by the belt when the raw material in the upper portion is pulled to one side, and a pair of opposing one gears which rotate as the side rollers are moved to one side, and the first gear Self-aligning a pair of two-stage gears facing each other to rotate in a direction opposite to the rotational direction of the first-stage gears, and vertically fixed to a lower portion of the roller supporting the lower portion of the belt to rotate by rotation of the second-stage gears. A roller shaft and a lower portion of the self-aligning roller shaft to rotate together with the self-aligning roller shaft Is a return self-aligning gear, and a pair of gears connected between the two pairs of gears facing each other and the self-aligning roller shaft to transfer the power of the second gear to the self-aligning roller shaft, wherein the belt is one side In the case of moving to, the automatic adjustment roller is rotated by the side roller is achieved by a knitting correction device that can prevent the phenomenon that the belt is inclined to one side.

1 shows the principle of a belt conveyor for transporting a shipment.

2 shows a cross section of a belt conveyor;

3 shows the cause of the meandering of the belt due to the loading of the transport.

4 is a view showing a conventional Laura device and the principle of operation for adjusting the belt meandering.

Figure 5 is a front view of the vehicle offset automatic offset device of the belt conveyor using a reduction device according to the present invention.

Fig. 6 is a perspective view of a belt conveyor automatic offsetting device of a belt conveyor using a speed reduction device mounted on a belt conveyor according to the present invention.

7 is a perspective view of a belt conveyor automatic offset device of the belt conveyor using the reduction device according to the present invention.

Figure 8 is a view showing the principle of the automatic offset device for the shipment of the belt conveyor using the reduction device according to the present invention.

9 is a view showing a state in which the belt conveyor transport object automatic offset device using the reduction device according to the present invention disassembled.

<Description of Symbols for Main Parts of Drawing>

1. Belt 2. Self-aligning carrier Laura

3. Self-aligning carrier stand 6. Side roller

7. Power transmission gear 10,12. 1 gear

14,16. 2 Gears 18. Chain Gears

21. Three-speed Gear

22,23. Back stop power transmission gear 24. Carrier shaft

28,31,32 Return self-aligning gear 37. Return self-aligning Laura Caba

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 5 is a front view of a vehicle loading automatic offset device of a belt conveyor using a reduction gear according to the present invention, and FIG. 6 has a vehicle offset automatic offset device of a belt conveyor using a reduction device installed on a belt conveyor according to the present disclosure. 7 is a perspective view of a belt conveyor using a deceleration device according to the present invention is a perspective view having an automatic offset device, Figure 8 is a principle of the belt conveyor using a deceleration device according to the present invention 9 is a diagram illustrating a state in which the belt conveyor transport object automatic offsetting device using the speed reduction device according to the present invention is disassembled.

The present invention is divided into three according to the width of the belt (1) to the carrier roller (2) supporting the upper belt (1) and the carrier carrier stand (3) to support the three carrier roller (2) Mount the rollers (2) and fix the fixing plate (4) to the center of the self-aligning carrier stand (3) with a bolt (39) and then fixed by welding the self-aligning roller shaft (24) to the fixing plate (4).

Insert the back stop power transmission gears 22, 23 upwards around the center of the fixed self-aligning roller shaft 24, and then insert the bushing 26 and the bearing 25 in the center hole of the reducer fixing plate 27. Insert the self-aligning roller shaft (24) to the bottom of the reducer fixing plate.

Insert the power transmission gear 28 in the lower part of the self-aligning roller shaft 24, and then insert the bearing 29 and the bushing 30, and return to both of the power transmission gear 28. And fit the fixed shaft (33, 34).

Insert the lower return self-aligning roller cover (37) into the lower return self-aligning roller cover (37) and tighten it with the nuts (39, 40) to fix it. The meander stopper (35, 36) meanders up the lower return self-aligning roller cover (37). The adjusting gear shafts 33 and 34 and the self-aligning roller shaft 24 are welded and fixed.

The side roller fixing plate 9 in which the bearings are fitted to the reducer fixing plate 27 is fixed with a bolt 39, and the side roller shaft 8 is fixed thereon. Insert the power transmission gear (7) and the side roller (6) to the fixed side roller shaft, engage the power transmission gear (7) and the reduction gear 1 gear (10), and then fit the upper gear shaft (11). After fixing the first gear 12 of the same size to the lower portion of the center of the first gear shaft 11 and fixed to the reducer fixing plate 27 fixed to the fixed plate 13, the bearing is coupled.

The second gear 14 is engaged with the reduction gear 1, the shaft 15 of the second gear is fitted, and the second gear 16 of the same size is fitted under the shaft. The shaft 15 into which the two-stage gears 14 and 16 are fitted is coupled to the two-stage gear fixing plate 17 to which the bearing is coupled, and then fixed to the reducer fixing plate 27 with a bolt 41.

Engage the 3rd gear 20 with the 2nd gear 16, and then insert the 3rd gear shaft 19 and fix it with bolts 41 to the gear reducer fixing plate 27. Insert the chain gear (18) on the upper side of the third gear shaft (19), and then connect the chain gear (18) and the back stop power transmission gear (22) by chains, which rotate in one direction and rotate in the opposite direction. Should not be rotated.

Hereinafter, with reference to the accompanying drawings will be described the operation and function of the present invention.

When the transport is loaded to the right side of the carrier part as shown in Fig. 3-1 of Fig. 3, the transport is moved to the center of the carrier part by the weight of the transport as shown in Fig. 3-3. If the belt 1 is installed as shown in FIG. 6, the belt 1 is meandered in the direction 1b at the central portion A1 of the belt 1 and the Laura when the belt 1 proceeds in the 1a direction as shown in FIG. 7-7. .

At this time, the side roller 6 and the power transmission gear 7 are rotated in the clockwise direction, and the first gear 10 and 12 meshed with the power transmission gear 7 are rotated counterclockwise. 12) when the second gear (14, 16) engaged with the second gear (14, 16) is rotated in the clockwise direction and the third gear (20) and the chain gear (18) engaged with the second gear (14, 16) rotates counterclockwise. 18 and the back stop power transmission gear 22 connected by the chain 5 also rotate counterclockwise and the self-aligning carrier shaft 24 also rotates, while the self-aligning carrier roller 2 moves in the direction 3a of FIG. 7-2. And the belt 1 meandered in the 1b direction while being automatically rotated in the 3b direction, is automatically adjusted to A1 which is the center of the belt 1 and the self-aligning carrier roller 2, and proceeds in a meandering manner as in A2.

The lower return belt 1 also travels in the direction 1a at A1 which is the center of the lower return belt 1 and the lower return self-aligning roller 36 as shown in FIG. 7-3, and the belt 1 meanders in the direction 1b. At this time, the lower return self-aligning gear 28 connected to the self-aligning carrier shaft 24 as shown in FIG. 7-1 is rotated counterclockwise as shown in FIG. 7-3, and the lower return self-aligning gear 28 and Both self-aligning gears 31 and 32 that are engaged are rotated clockwise.

At the same time, the lower return self-aligning roller 38 is rotated in the 3a and 3b directions, respectively, based on A1, the center of the lower belt 1 and the lower return self-aligning roller 36, so that the return belt 1 is also automatically As in A2, the meander adjustment was performed so that the upper carrier self-aligning roller 2 and the lower return self-aligning roller 38 were automatically adjusted at the same time.

When the transport is loaded to the left side of the carrier portion as shown in 3-4 of FIG. 3, the transport is directed to the center of the Kerry pour according to the weight of the transport as shown in FIG. 3-6. Only the direction of rotation of the gears was reversed to automatically adjust the meander.

The present invention is the state of the belt due to the formation of the transport material due to the belt side damage caused by the loading of the transport material on either side of the belt, the resulting stop of the belt, the occurrence of falling lights, etc. Carrier and return belts are automatically meandered at the same time, so that the cargo is always loaded in the center of the belt, improving the transport capacity of cargo, reducing downtime and reducing manpower. It has a good practical effect to solve.

Claims (1)

In the knitting correction device for preventing the belt conveyor to rotate the belt using the roller and to transport the transport material using the belt to the one side, Side rollers which are installed at both sides of the belt and are moved outwardly by the belt when the raw material in the upper portion of the belt is pulled to one side; A pair of opposing one-stage gears that rotate as the side rollers move to one side; A pair of opposing two-gear gear meshed with the first-gear gear and rotating in a direction opposite to the rotational direction of the first gear, A self-aligning roller shaft fixed vertically to a lower portion of the roller supporting the lower portion of the belt to rotate by rotation of the second gear; A return self-aligning gear mounted on a lower portion of the self-aligning roller shaft and rotating together with the self-aligning roller shaft; And a chain gear connected between the pair of two-speed gears facing each other and the self-aligning roller shaft to transfer the power of the second gear to the self-aligning roller shaft, wherein the side roller when the belt moves to one side. As the automatic watch roller is rotated by the knitting correction device capable of preventing the belt from being leaned to one side.