KR101605242B1 - Skirt apparatus for auto ascent and descent - Google Patents

Abstract

And a skirt device provided on both sides of the lower part of the chute and capable of moving up and down by a raw material and its own weight conveyed through a belt conveyer to minimize collision and wear between the raw material and the skirt and effectively prevent the belt from being worn will be.
The skirt device having the ascending and descending functions of the present invention is provided on the lower end of a chute, which is located on a belt conveyor and in which a supply passage penetrating the upper and lower surfaces is formed. The skirt device includes a plurality of first A pair of guide plates respectively provided on the pair of support plates for guiding the material loaded on the belts, and a pair of guide plates And a first guider which is brought into contact with a raw material conveyed along the belt and rotates and elevates the pair of support plates in a moving direction of the belt.

Description

SKIRT APPARATUS FOR AUTO ASCENT AND DESCENT [0002]

The present invention relates to a skirt device having an ascending / descending function, and more particularly, to a skirt device having a function of moving up and down by a raw material and a self weight conveyed through belt conveyors, And a skirt device having an ascending / descending function.

Generally, in the industrial field, a belt conveyor is used to continuously convey raw materials such as ore and coal.

When a raw material is fed to the upper surface of the belt or a plurality of belt conveyors having different heights are used to transport the raw material, a chute is used to uniformly load and steer the raw material.

As shown in FIG. 1, the chute 50 is provided with a supply passage 70 penetrating the top and bottom surfaces thereof, and the raw material 60 is dropped through the supply passage 70. The supply passage 70 formed in the chute 50 is provided with a damper 30 which contacts the falling material 60 to guide the falling direction of the material 60 and serves as a buffer, A pair of skirts 40 which are in contact with both ends of the belt 20 are provided.

The skirt 40 is made of a rubber material in order to prevent the belt 20 from being torn or worn and is made of an impact caused when the raw material 60 falling through the chute 50 comes into contact with the belt 20 And prevents the raw material 60 loaded on the belt 20 from moving on the belt 20 when the belt is moved.

The plurality of chutes 50 provided on the upper surface and the end of the belt conveyor 10 have substantially the same function, except for their positions. 1, the raw material 60 and the chute 50, which are moved in a direction opposite to the moving direction of the belt 20, and the raw material 60 falling through the supply passage 70, 40 are damaged.

More specifically, the upper surface of the first chute 51 located at the end opposite to the moving direction of the belt 20 and the raw material 60 supplied through the supply passage 70 are dropped and loaded on the belt 20 And flows along the moving direction of the belt 20, and passes through the lower end of the second chute 52.

At this time, however, the raw material 60 passing through the first chute 51 collides with the skirt 40 of the second chute 52, which causes impact and abrasion of the skirt 40, It will eventually be damaged by wear.

The belt 20 is moved while the raw material 60 passing through the first chute 51 is sandwiched between the skirt 40 of the second chute 52 and the belt 20, There is also a problem of tearing.

Not only the upper surface of the chute 50 and the material 60 dropping through the supply passage 70 are continuously brought into contact with the inner surface of the skirt 40 closely attached to the belt 20 so that the skirt 40 There is also a problem that the raw material 60 which is broken and falls down is discharged to the outside of the belt 20.

If the belt 20 or the skirt 40 is damaged during the conveyance of the raw material 60 through the belt conveyor 10, the raw material 60 will flow out to contaminate the environment, There is a difficulty in reducing the productivity because the transfer operation can not be carried out for a long time.

A method for solving the similar problem is specifically known in the conventional "skirt device of a suit (Patent No. 10-1322041)".

In the conventional "chute skirt device (patent No. 10-1322041)" in the related art, a device body portion provided for elastic movement at the lower portion of a chute connected between transporting facilities and a lower portion of the device body portion, Elastic means provided on the skirt member and the hinge member to provide a tensile force to maintain the adhesion force between the skirt member and the transport belt, and a guard plate mounted on the lower portion of the skirt member to prevent the damage from being directly damaged The transfer device is presented.

However, such a 'skirt device of a suit' has a problem that the belt wears rapidly because the guide plate of the steel material is always in contact with the belt, and when the raw material is sandwiched between the belt and the guide plate, So that the belt is still worn out.

Korean Patent No. 10-1322041 (Oct. 10, 2013)

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to minimize the collision and abrasion between a raw material and a skirt by being raised and lowered by a raw material and a self weight conveyed through belt conveyors, And a skirt device having a lifting / lowering function.

In order to accomplish the above object, according to the present invention, there is provided a skirt device having a lifting / lowering function, the skirt device being disposed on a belt conveyor and provided at a lower end of a chute having a supply passage formed therein passing through upper and lower surfaces thereof, A pair of guide plates provided on both sides of the lower end of the pair of support plates so as to be pivotable via a plurality of first link plates, And a first guider which is provided at the ends of the pair of support plates and contacts the raw material conveyed along the belt to rotate and elevate the pair of support plates in the moving direction of the belt.

A pair of buffer plates are provided between the pair of guide plates facing each other, and the pair of buffer plates are positioned between the guide plate and the supply passage.

The belt is bent in a U-shape, and the pair of buffer plates is at least equal to or larger than the width and length of the guide plate.

The guide plate is made of a polymer material, the buffer plate is made of a metal material, and the lower end of the buffer plate is not in contact with the belt.

The first guider is provided along the width direction of the belt, and the length of the first guider is at least equal to the interval between the pair of guide plates facing each other.

[2] The apparatus according to claim 1, wherein one end of the first link plate is provided on a side surface of the chute via a first rotation shaft, and the other end is provided on the support plate via a second rotation shaft, And is spaced apart from the lower end of the chute.

Wherein a pair of second link plates are respectively provided at the rear end of the pair of support plates with respect to a moving direction of the belt, and both ends of the first guider are rotatably supported by the pair of second link plates Respectively.

A pair of third link plates respectively provided at the ends of the pair of support plates with respect to a moving direction of the belt, and a pair of third link plates rotatably connected at both ends to the pair of third link plates, And a second guider for guiding one raw material.

And the pair of third link plates are rotatably provided at the ends of the pair of support plates.

And the outer circumferential surfaces of the first guider and the second guider are concave toward the central portion so as to correspond to the curved shape of the belt.

The second link plate is inclined at a predetermined angle with the belt.

The present invention has the following various effects.

First, the present invention can prevent the raw material from being caught between the belt and the skirt, thereby preventing the belt and the skirt from being worn and damaged.

Second, since the present invention is driven by a force in contact with a raw material without a separate power supply, maintenance and management are easy.

Third, the present invention is applicable not only to a flat belt but also to a U-shaped belt.

Fourth, the present invention can prevent a fire accident and environmental pollution by preventing the raw material from being shaded to the outside of the belt.

1 is a view showing an operation state of a conventional chute and a belt conveyor,
2 is a side view of a skirt device according to the present invention,
3 is a view showing an operating state of the skirt device according to the present invention,
4 is a rear view of a skirt device and a belt conveyor according to the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings, and the same reference numerals are given to the background art and the constituent elements of the constitution which have already been described.

The description of the skirt device having the ascending / descending function of the present invention described below is a preferred embodiment of the present invention and is not limited to the embodiment, but can be implemented in various forms.

4, a skirt device having an ascending / descending function according to an exemplary embodiment of the present invention includes a belt conveyor 10, a belt conveyor 10 and a chute 12. The belt conveyor 10 includes a supply passage 70 passing through upper and lower surfaces thereof, A pair of guide plates 100, and a first guider 300. The pair of guide plates 100,

The pair of support plates 500 are rotatably provided on both sides of the lower end of the chute 50 via a plurality of first link plates 200 along the longitudinal direction of the belt 20, And a function of moving the first guider 300, which will be described later, from the belt 20, by rotating and transmitting a force applied to the guider 300.

The first link plate 200 is provided on the side of the chute 50 via the first rotation shaft 210 so that the support plate 500 can be rotated separately from the chute 50, And the other end is provided on the support plate 500 via the second rotation shaft 220. [

The chute 50 and the support plate 500 are connected to each other by the first link plate 200 and the first and second rotation shafts 210 and 220 so that the support plate 500 contacts the tip end of the chute 50, It is possible to pivot toward the rear end side.

The chute 50 and the support plate 500 are prevented from coming into contact with each other when the pair of support plates 500 are rotated from the lower end of the chute 50 toward the front end and the rear end of the chute 50, It is preferable that the pair of support plates 500 are spaced apart from the lower end of the chute 50 toward the belt 20 by a predetermined distance.

The pair of guide plates 100 are respectively provided on a pair of support plates 500 along the longitudinal direction of the belt 20 to guide the raw materials 60 loaded on the belt 20, The end of the guide plate 100 located on the opposite side of the belt 20 contacts the belt 20.

The guide plate 100 is normally in contact with the belt 20 by its own weight and when the raw material 60 loaded on the belt 20 contacts the first guider 300 to be described later, The belt 20 is lifted and lowered from the belt 20 to maintain the noncontact state with the belt 20. [

The first guider 300 rotates and elevates the pair of support plates 500 toward the moving direction of the belt 20 in contact with the raw material 60 conveyed along the belt 20, And is provided at an end of the support plate 500.

When the raw material 60 transported along the belt 20 and the first guider 300 are brought into contact with each other, an external force acting on the moving direction of the belt 20 is applied to the first guider 300, The support plate 500 of the first rotating shaft 210 rotates around the first rotating shaft 210 and the second rotating shaft 220. At this time, the guide plate 100 provided on the support plate 500 is also moved together with the support plate 500, so that the guide plate 100 is separated from the belt 20, that is, it is in an elevated state.

The first guider 300 is wound on the upper surface of the belt 20 along the width direction of the belt 20 so as to be in contact with the material 60 to be conveyed, It is preferable that the distance between the guide plates 100 is larger than the distance between the guide plates 100.

The first guider 300 may be provided at one or both ends of the pair of support plates 500. In an embodiment of the present invention, the first guider 300 may include a first guider 400 300 are provided on the rear end side of the support plate 500 with reference to the moving direction of the belt 20. [

It is preferable that the present invention further includes a pair of buffer plates 600, a pair of second link plates 700, a pair of third link plates 800, and a second guider 400.

The pair of buffer plates 600 is provided to prevent the pair of guide plates 100 from colliding with the material 60 falling through the supply passage 70 and being damaged. The guide plate 100 is provided between the guide plate 100 and the supply passage 70 so as to prevent the raw material 60 dropped from the supply passage 70 from colliding with the guide plate 100, .

It is also preferable that the pair of buffer plates 600 have the same width and length as the guide plate 100 to effectively protect the guide plate 100 from the raw material 60. [

However, when the shape of the belt 20 is formed in a U shape rather than a straight shape, the width and length of the pair of buffer plates 600 are equal to the width and length of the guide plate 100 It is preferable to have a larger size.

That is, since the pair of buffer plates 600 are positioned between the pair of guide plates 100, if the belt 20 is U-shaped, It is possible to effectively protect the guide plate 100 from the raw material 60 while preventing the end located on the belt 20 side from being in contact with the belt 20 and being bent even if the width and length of the guide plate 100 are equal to or larger than the width and length.

The guide plate 100 is preferably made of a polymer material since it is in direct contact with the belt 20 in order to prevent the material 60 falling from the supply path 70 from being shaded out of the belt 20, It is preferable that the plate 600 is formed of a metal material to effectively protect the guide plate 100 from the falling material 60 and to prevent the guide plate 100 from being damaged.

However, when the buffer plate 600 made of a metal is in contact with the belt 20, the belt 20 may be worn or torn, so that the lower end of the buffer plate 600 is not brought into contact with the belt 20 .

The pair of second link plates 700 connects the first guider 300 and the pair of support plates 500 to each other and supports the pair of support plates 500 And both ends of the first guider 300 are rotatably connected to the pair of second link plates 700, respectively.

The first guider 300 transmits the force applied when the first guider 300 is in contact with the raw material 60 to the support plate 500 so that the support plate 500 rotates about the first rotation axis 210 and the second rotation axis 220, Since the first guider 300 rides up the raw material 60 loaded on the belt 20, the first guider 300 presses the raw material 60 on the belt 20, Pressure may be applied to cause wear and breakage.

Accordingly, when the first guider 300 and the raw material 60 are brought into contact with each other, the first guider 300 can be rotated in the moving direction of the belt 20, thereby facilitating the movement of the raw material 60 The pressure applied to the belt 20 can be effectively removed.

In order to allow the support plate 500 to be easily rotated in the moving direction of the belt 20 when the first guider 300 is contacted with the material 60 conveyed on the upper surface of the belt 20, It is preferable that the belt 700 is inclined at a predetermined angle with respect to the belt 20. 2, one end of the second link plate 700 is fixed to the rear end of the support plate 500, and the other end of the second link plate 700 is inclined downward at a predetermined angle in a direction opposite to the support plate 500 .

The pair of third link plates 800 connects the second guider 400 to be described later and the pair of support plates 500. The pair of support plates 500 And both ends of the second guider 400 are rotatably connected to the pair of third link plates 800, respectively.

The second guider 400 guides the proceeding direction of the raw material 60 passing through the chute 50 so that the traveling direction of the raw material 60 is not changed due to the vibration of the belt 20. The first guider 300, The belt 20 can be prevented from being damaged.

If the raw material 60 is fed through the upper surface of the chute 50 and the feed passage 70 but not through the first guider 300 and the raw material 60 loaded on the belt 20 is fed through the first guider If the guide plate 100 is rotated in the moving direction of the belt 20 by the second guider 400 at this time, A phenomenon that the raw material 60 falling from the belt 20 through the supply passage 70 is lifted out of the belt 20 will be generated.

Accordingly, the third link plate 800 is rotatably provided at the tip end portions of the pair of support plates 500, so that when the second guider 400 rides up the raw material 60, the third link plate 800 rotates The support plate 500 can be held in place without pivoting.

However, according to the present invention, it is possible to prevent the third link plate 800 from rotating. Even in such a case, the phenomenon that the raw material 60 is shaded by the pair of buffer plates 600 is prevented It will be possible.

If the shape of the belt 20 of the belt conveyor 10 is curved in a U-shape, the raw material 60 loaded on the belt 20 is mostly concentrated in the center of the belt 20, When the raw material 60 densely disposed in the center of the belt 20 contacts the first and second guiders 300 and 400 and the raw material 60 is conveyed to the belt 20, (20) while being dispersed in the width direction of the belt (20).

The first guider 300 and the second guider 400 may be concavely formed toward the center of the first guider 300 and the second guider 400 so as to correspond to the curved shape of the belt 20 It is possible to prevent the raw material 60 concentrated in the center portion of the belt 20 from being widely dispersed along the width direction of the belt 20. [

The pair of guide plates 100 are lifted from the belt 20 by the rotation of the support plate 500 when the first guider 300 and the raw material 60 are in contact with each other, Both ends of the first guider 300 in which the outer circumferential surface is recessed are gripped such that the raw material 60 is not shaded to the outside of the belt 20, Thereby guiding the conveying direction of the sheet 60.

The first guider 300 and the second guider 400 may maintain the belt 20 in contact with the belt 20 so that the belt 20 may be worn out. And may be spaced apart from the upper surface by a predetermined distance.

Hereinafter, the operation of the present invention will be described with reference to FIGS. 2 and 3. FIG.

2, when the raw material 60 is not loaded on the upper surface of the belt 20, the weight of the pair of the support plates 500 and the guide plate 100 causes the belt 20 to rotate, The first guider 300 and the guide plate 100 are kept in contact with each other and as shown in FIG. 3, when the material 60 is loaded on the upper surface of the belt 20, The support plate 500 rotates about the first rotation axis 210 and the second rotation axis 220 as the raw material 60 is contacted.

A process of rotating and elevating the pair of guide plates 100 will be described in detail.

An external force is applied to the first guider 300 toward the moving direction of the belt 20 when the raw material 60 moving from the rear side of the first guider 300 contacts the first guider 300, The belt 20 rotates in the same direction as the moving direction of the belt 20.

The first guider 300 is rotated by the raw material 60 moving in the moving direction of the belt 20 toward the moving direction of the belt 20 and rises on the surface of the raw material 60 at the same time as being pushed, The pair of support plates 500 are rotated about the first rotation axis 210 and the second rotation axis 220 along the moving direction of the belt 20. [

A pair of guide plates 100 are provided on the pair of support plates 500. When the guide plate 100 contacts the belt 20 as the support plate 500 rotates, Contact state with the belt 20 while being lifted and lowered.

That is, since the guide plate 100 is spaced from the belt 20, the guide plate 100 is prevented from colliding with the material 60 conveyed on the upper surface of the belt 20.

At this time, the guide plate 100 is spaced from the belt 20, but the pair of buffer plates 600 are not rotated because they are fixed to the lower end of the chute 50 separately from the support plate 500. However, since the buffer plate 600 is configured to protect the guide plate 100, when the buffer plate 600 is formed of a metallic material, the buffer plate 600 is provided at a predetermined interval so as not to contact the belt 20, but does not rotate in any direction.

That is, when the raw material 60 is fed through the upper surface of the chute 50 and the feed passage 70 while the guide plate 100 is spaced from the belt 20, the raw material 60 collided with the belt 20 It can be shaded out of the belt 20 through a gap formed between the belt 20 and the guide plate 100. Since the pair of buffer plates 600 are positioned between the pair of guide plates 100, It is possible to prevent the raw material 60 falling through the passage 70 from being thrown out of the belt 20.

The raw material 60 passing through the lower end of the chute 50 meets the second guider 400 and the second guider 400 moves up the raw material 60 while rotating along the moving direction of the belt 20 do. The third link plate 800 is rotatably provided on the support plate 500 in a manner different from the second link plate 700 so that the second guide plate 400 is contacted with the raw material 60, 500 do not rotate.

This is because when the upper surface of the chute 50 and the raw material 60 to be introduced through the supply passage 70 are provided instead of the raw material 60 moving on the side of the first guider 300, When the guide plate 100 is lifted and lowered due to contact between the belt 20 and the guide plate 100 due to contact between the belt 20 and the guide plate 100, there is a high possibility that the raw material 60 is shaded.

The material 60 loaded on the belt 20 may be concentrated to the center of the belt 20. If the first guider 300 is concavely formed, It is possible to prevent the raw material 60 concentrated at the center portion of the belt 20 from being dispersed widely in the width direction of the belt 20 by the outer circumferential surface of the second guider 400. [

As the pair of guide plates 100 are separated from the belt 20, the guide 60 does not function to guide the proceeding direction of the raw material 60. This vacant space can be divided into the first guide 300 and the second guide 400 are replaced by both ends.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the invention.

10: belt conveyor 20: belt
50: suit 60: raw material
70: feed passage 100: guide plate
200: first link plate 300: first guider
400: second guider 500: support plate
600: buffer plate 700: second link plate
800: third link plate

Claims (11)

A skirt device disposed on a belt conveyor and provided at a lower end of a chute in which a supply passage penetrating an upper surface and a lower surface is formed,
A pair of support plates rotatably mounted on both sides of the lower end of the chute via a plurality of first link plates;
A pair of guide plates provided respectively on the pair of support plates for guiding the raw materials loaded on the belt; And
And a first guider rotatably connected to the ends of the pair of support plates to rotate the pair of support plates in a moving direction of the belt in contact with a raw material conveyed along the belt, ,
Wherein the first guider is provided along a width direction of the belt, the length of which is at least equal to a distance between the pair of guide plates facing each other,
Wherein one end of the first link plate is provided on a side surface of the chute via a first rotation axis and the other end is provided on the support plate via a second rotation shaft.
The method according to claim 1,
Characterized in that a pair of buffer plates are provided between the pair of guide plates facing each other, and the pair of buffer plates are respectively located between the guide plate and the supply passage. Device.
The method of claim 2,
Wherein the pair of buffer plates are provided at least equal to or larger than the width and length of the guide plate.
The method of claim 3,
Wherein the guide plate is made of a polymer material, the buffer plate is made of a metal material, and the lower end of the buffer plate is not in contact with the belt.
delete delete The method according to claim 1,
A pair of second link plates are provided at the rear ends of the pair of support plates with respect to a moving direction of the belt,
And both ends of the first guider are rotatably connected to the pair of second link plates.
The method of claim 7,
A pair of third link plates respectively provided at the ends of the pair of support plates with respect to a moving direction of the belt, and a pair of third link plates rotatably connected at both ends to the pair of third link plates, And a second guider for guiding a raw material.
The method of claim 8,
And the pair of third link plates are rotatably provided at the tip ends of the pair of support plates.
The method of claim 8,
Wherein the outer peripheral surface of the first guider and the second guider are concave toward the central portion so as to correspond to the curved " U " shape of the belt.
The method of claim 7,
Wherein the second link plate is inclined at a predetermined angle with respect to the belt.

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