NL2035195B1 - TRANSPORTER AND WORKING METHOD - Google Patents

Abstract

The present invention relates to a conveyor for transporting material, the conveyor comprising: - a frame; - a transport device connected to the frame and provided with a drive, the transport device extending from a supply end to an output end and the transport device being adapted to transport material in a transport direction from the supply end to the output end; and - a connecting element arranged on a first side of the frame and adapted to connect the conveyor to an excavator, - an input element arranged on a second side of the frame, the second side being positioned opposite to the first side, the input element being adapted to guide material onto the transport device in a direction substantially perpendicular to the transport device.

Description

TRANSPORTER AND WORKING METHOD

The present invention relates to a conveyor for transporting material, in particular a conveyor that can be connected to an excavator. The invention further relates to a method for moving material with the conveyor.

JPH11247223A relates to a device for transporting material. The device can be attached to an excavator. The attachment of the Device to the excavator 1s provided at the bottom of the excavator. For the attachment of the device to the excavator, the excavator comprises a number of hooks at the bottom, whereby the conveyor belt of the device can be attached hanging from the hooks. The conveyor belt has a transport direction that is parallel to the longitudinal direction of the excavator, or in other words, parallel to the normal direction of movement of the crawler tracks of the excavator.

A disadvantage of the known device is that the attachment to the excavator is not stable. A further disadvantage is that the device takes up unnecessary space and moving it is inconvenient.

The present invention aims to overcome or at least reduce the above-mentioned problems. In particular, it may be an aim of the invention to provide a conveyor that is simpler to use.

This object is achieved by a conveyor for transporting material, the conveyor comprising: - a frame; - a transport device connected to the frame and provided with a drive, the transport device extending from a supply end to an output end and the transport device being adapted to transport material in a transport direction from the supply end to the output end; and - a connecting element arranged on a first side of the frame and adapted to connect the conveyor to an excavator, - an input element arranged on a second side of the frame, the second side being positioned opposite to the first side, the input element being adapted to guide material onto the transport device in a direction substantially perpendicular to the transport device.

An advantage of the invention is that the transport device means that the boom of the excavator does not have to move meters upwards every time the bucket of the boom is loaded with material to load material into a tipper. This has the advantage, among other things, that the loading time of the truck and/or articulated dumper is halved. A further advantage is that the truck and/or articulated dumper can work 10% more efficiently, because it does not stand still for as long to be loaded. Alternatively or additionally, the fuel consumption of the excavator decreases by approximately 50%. This increases the sustainability of the use of the excavator.

Alternatively or additionally, the transporter offers the possibility to use electric excavators, because the reduction in energy consumption requires a smaller battery. A further advantage is that the transporter can be easily connected to the front of an excavator by means of the connecting element, so that no structural adjustments to the excavator are necessary for using the transporter. One of the possibilities is to weld a number of eyes to the undercarriage of the crane.

When the conveyor is connected to the excavator, the conveyor device extends substantially perpendicular to the normal direction of movement of the excavator.

The normal direction of movement of the excavator is defined as the direction in which the excavator moves when the wheels are straight, or the direction in which the tracks extend. The connecting element is preferably designed to be connected to the front of the excavator.

A further advantage of the invention is that because the transport direction is perpendicular to the normal direction of movement of the excavator, the truck can easily be positioned next to the excavator. Alternatively or additionally, the excavator and/or the truck can easily change position if the material on the ground runs out or if the truck is full.

A further advantage of the invention is that safety is increased because the up and down movement of the excavator with its mast, and in particular the turning of the excavator, is almost completely prevented. Alternatively or additionally, the work for the excavator operator becomes lighter and easier. This increases the productivity of the excavator, which increases the labour productivity of the operator. A further advantage is that the productivity of the employees can increase by up to 100%. Due to the faster loading time that can be achieved with the present invention, the truck drivers can also work more efficiently.

In an embodiment of the invention, the input element comprises an inclined plane that is designed to guide material to the feed end of the conveyor device.

The ramp is preferably designed to guide material in a first direction. The first direction preferably extends substantially perpendicular to the direction of transport.

The ramp element is preferably arranged on a first side of the frame, with the connecting element being arranged on an opposite second side of the frame. The transport device preferably extends in a transport direction that is substantially parallel to the first and second sides.

The ramp element preferably extends at an angle of inclination from the top surface of the frame to the ground.

The inclined plane simplifies the placement of material on the conveyor.

In an embodiment according to the invention, the connecting element comprises a hook-shaped element.

The hook-shaped element allows the conveyor to be connected to the excavator in a simple and effective manner. In that case, the excavator is preferably provided with an eye in which the hook can be placed. The hook-shaped element comprises a first end with a hook and a second end that is connected to the frame.

In an embodiment according to the invention, a distance from the hook-shaped element to the frame is adjustable in a direction perpendicular to the transport direction.

Preferably, the adjustable connection comprises an extendable connection between the hook-shaped element and the frame. The extendable connection may comprise a telescopic connection. Preferably, the telescopic connection is a hollow housing that is fixedly connected to the frame, in which an extending part is arranged in the hollow housing. The extending part can be driven by means of a cylinder. The hook is provided on the extending part. The hollow housing and the extending part can comprise any geometric shape, such as beam-shaped and/or cylindrical.

Alternatively, the distance of the hook-shaped element to the frame in a direction substantially perpendicular to the transport device can be adjusted by means of a rotational movement of the hook-shaped element. The rotational axis of the hook-shaped element is preferably perpendicular to the upper surface of the frame and/or the ground, and directed in the transport direction. In this embodiment, the hook-shaped element comprises a hook at a first end and a rotatable connection at a second end. This rotatable connection is with the frame, preferably with a wall thereof. The rotatable connection allows the hook to be rotated upwards and downwards, so that the hook can easily be attached to an eye or connecting rod of an excavator.

By being adjustable perpendicular to the transport device, a simple and reliable connection between the excavator and the conveyor is realized. A further advantage is that the conveyor can be connected to any size of excavator.

In an embodiment according to the invention, the first and second sides are both provided with a connecting element and an input element.

By providing a connecting element and a feed element on both sides, the excavator can be attached to both the first and second side. This greatly simplifies the changing of sides, and thus also the changing of the transport direction.

This allows the transport device to be adjusted to both the left and right of the excavator, resulting in a more versatile transporter.

In an embodiment according to the invention, the input elements are a plate rotatably connected to the first and second sides, the input element having an inclined position and a loading position, the input element being adapted to guide material onto the transport device in the inclined position and the input element being positioned substantially vertically upwards in the loading position and being adapted to retain material.

The input element in this embodiment can also be called a rotatable wall element. The rotatable connection makes the input element multifunctional. In the slope position, the input element is extended from the ground to the feed end of the transport device. This allows the excavator to easily bring the material lying on the ground to the transport device.

In the loading position, the infeed element extends from the frame substantially straight up, preferably perpendicular to the upper surface of the frame and/or the plane of the conveyor. This effectively retains the material at the side to which the excavator 1s is attached, preventing the material from ending up on the excavator or between the excavator and the frame.

Preferably, the input element is located in the loading position on the side where the excavator is connected to the frame, and the input element is located in the slope position on the opposite side, where the excavator is not connected to the frame.

In an embodiment according to the invention, an obstruction wall is provided on the first side which is designed to retain material, the connecting element being provided on the obstruction wall.

Preferably, the obstruction wall extends substantially straight upwards from the frame, preferably perpendicular to the top surface of the frame and/or the plane of the conveyor.

An advantage of the obstruction wall is that the material is effectively held back at the side to which the excavator is attached. This prevents the material from ending up on the excavator or between the excavator and the frame. Because the connecting element is attached to the obstruction wall, the conveyor can be effectively connected to the excavator.

In an embodiment according to the invention, the obstruction wall and the input element are interchangeable.

Interchangeable means that the obstruction wall can be placed on the second side and the input element on the first side. An advantage of this is that changing sides, and thus also changing the transport direction, is greatly simplified. This allows the transport device in particular to be set to both the left and the right of the excavator.

This results in a more versatile conveyor.

In an embodiment according to the invention, a guide housing is provided on the transport device for guiding the material on the transport device.

The guide housing preferably comprises part of the conveying device, for example 1/8 part of the entire length of the conveying device. The length should be seen in the direction of the conveying direction. The guide housing is preferably tapered. seen in the conveying direction.

The guide housing prevents excessively large lumps of material from being moved onto the conveyor at the same time. This reduces the loss of material falling off the conveyor, which further increases the efficiency of the conveyor.

In an embodiment according to the invention, the transport device comprises a lifting hook, preferably positioned near the centre of gravity of the conveyor.

The lifting hook is preferably rotatable. The lifting hook is preferably 360 degrees rotatable.

The lifting hook is preferably tiltable. The lifting hook is preferably mounted on the guide housing.

The lifting hook allows the bucket of the excavator to engage, allowing the conveyor as a whole to be lifted free of the ground by the lifting hook. This allows the conveyor, when connected to the excavator, to be easily positioned at another location. This is particularly advantageous in combination with the connecting element.

The rotatable lifting hook makes it easier to put the transporter away.

Because the hook is positioned at the center of gravity, the bucket of the excavator can engage the hook and lift it up. By rotating the hook, the conveyor can be placed at any desired location.

In an embodiment according to the invention, the transport device comprises a conveyor belt.

The conveyor belt can effectively transport the material from the inlet end to the outlet end of the conveyor.

In an embodiment according to the invention, the transport device is provided at a transport angle relative to an upper surface of the frame.

The upper surface of the frame is preferably in use substantially parallel to the ground.

The transport angle allows the material to be brought to a position higher than the excavator bucket, without the excavator boom and bucket having to bridge the height difference. This increases the efficiency of the excavator.

In an embodiment according to the invention, the transport angle is in the range of 10-80 degrees, preferably in the range of 30-60 degrees, and most preferably in the range of 40-50 degrees.

The above-mentioned angles efficiently bring the material to a height.

In an embodiment according to the invention, the transport device comprises two parts, a first part extending towards the supply end extending substantially parallel to the upper surface of the frame and a second part extending towards the discharge end extending at the transport angle.

The first section allows the material to be positioned by the excavator's bucket. By extending parallel to the upper surface of the frame, the bucket does not have to tilt, which simplifies the work. The second section effectively brings the material to a height higher than the bucket without the bucket itself having to bridge this height.

In an embodiment according to the invention, the conveyor further comprises adjustment means connected to the transport device which are designed to adjust the transport angle by tilting the transport device relative to the frame.

The adjustment means make it easy to adjust the transport angle, so that the height of the discharge end can be adjusted to different trucks and/or articulated dumpers. The adjustment means preferably comprise at least one cylinder that is operatively connected between the frame and the second part of the transport device.

In an embodiment according to the invention, the frame further comprises a battery which is operatively connected to the drive of the transport device.

Preferably, the battery is actively connected to adjustment means for adjusting the transport angle.

The battery allows the transporter to operate completely autonomously and 1s not dependent on a power source of the excavator. This allows the transporter to be powered entirely by sustainable energy. This increases the sustainability of the invention.

In an embodiment according to the invention, the connecting element is a tiltable connecting element, the tiltable connecting element being tiltable about an axis that extends substantially parallel to the normal direction of movement of the excavator.

The tiltable connection creates a play in the connection between the conveyor and the excavator. This play prevents unwanted forces on the connection in the event of uneven ground. This increases the lifespan of the connection.

Alternatively or additionally, the chance of breakage or wear of the connection is smaller.

In an embodiment according to the invention, the connecting element comprises an operating position and a locking position, wherein in the operating position the connecting element is tiltable and in the locking position the connecting element is locked against tilting, wherein the connecting element can be placed in the locking position by lifting a side of the frame positioned away from the connecting element.

Locking the tilt while lifting simplifies transport.

In an embodiment according to the invention, the conveyor further comprises a remote control, the connection being decouplable by means of the remote control.

The remote control eliminates the need for the worker sitting on the excavator to leave the excavator cabin to disconnect the conveyor. This increases the safety and efficiency of the invention.

In an embodiment according to the invention, the conveyor further comprises a sliding element arranged under the frame.

The sliding element makes it easier to move when the frame is placed on the ground.

The invention further relates to an excavator provided with a conveyor according to the invention.

The excavator has similar advantages and effects as described for the transporter according to the invention.

In an embodiment of the invention, the excavator further comprises an eye or connecting rod mounted on the excavator, the eye or connecting rod being adapted to be connected to the connecting element of the conveyor.

By connecting the eye and the hook a robust connection is realized between the excavator and the conveyor. The eye is preferably mounted at the front of the excavator.

The invention further relates to a method for moving material, the method comprising the steps of: - providing an excavator according to the invention; - placing material on the transport device with the excavator; and - transporting material to a desired location with the transport device.

The method has similar advantages and effects as described for the transporter and the excavator according to the invention.

In an embodiment according to the invention, the method further comprises: - connecting the conveyor to the excavator.

Further features, advantages and details of the invention are described by means of embodiments thereof, reference being made to the appended drawings, in which: - figure 1, a side view of an excavator provided with a conveyor according to the invention; - figure 2, a perspective view of a conveyor according to the invention; - figure 3, a perspective view of a connecting element; - figure 4A-B, a side view of a connecting element; - figure 5, perspective view of a conveyor according to the invention.

Conveyor 2 (Figure 1) is connected to excavator 60 by connecting element 10.

Excavator 60 is equipped with boom 62 with bucket 64 at the end thereof. Bucket 64 can transport material 66 via inlet element 12 to conveyor belt 20. Via conveyor belt 20, material 66 is transported upwards to discharge end 24. From discharge end 24, material 66 can be dumped into an articulated dumper (not shown).

Conveyor 2 (figure 2) comprises a frame 4 and a transport device 6. Frame 4 comprises first side 7 and second opposite side 8. Connecting element 10 is arranged on first side 7. Inlet element 12 is arranged on second side 8. Conveyor device 6 comprises first part 14 which runs parallel to the upper surface of frame 4, and second part 16 which extends from frame 4 at a transport angle o. Conveyor device 6 is provided with rollers 18 over which conveyor belt 20 runs. Conveyor belt 20 is driven by drive 22, which is arranged at the discharge end 24 of second part 16. Drive 22 rotates drive roller 21, with which drive roller 21 sets conveyor belt 20 in motion over rollers 18. Drive 22 is supplied with power by battery 26 which is arranged on frame 4. Conveyor 6 is designed to transport material from inlet end 23 to outlet end 24.

Input element 12 is rotatably connected to frame 4 on second side 8. Input element 12 is hingedly connected about rotation axis A. On first side 7, wall section 28 is rotatably connected to frame 4. Input element 12 is arranged at an angle [B] with respect to the top surface of frame 4. Wall section 28 is arranged substantially perpendicular to the top surface of frame 4, with wall section 28 being directed substantially upwards. If the excavator is connected to conveyor 2 on second side 8, input element 12 can be rotated upwards to serve as wall section 28. At the same time, wall section 28 is rotated downwards and provided at an angle [B] with respect to the top surface of frame 4, so that wall section 28 can function as input element 12.

Guide housing 30 is mounted on second part 16. Guide housing 30 is provided with inlet opening 32 and outlet opening 34. Inlet opening 32 has a larger surface area than outlet opening 34. As a result, guide housing 30 tapers from inlet opening 32 to outlet opening 34. Lifting hook 38 is attached to top wall 36 of guide housing 30.

Lifting hook 38 is 360° rotatable about rotation axis C. Lifting hook 38 is positioned mainly at centre of gravity 40 of conveyor two. This makes it easy for conveyor 2 to be lifted by the excavator by engaging the bucket of the excavator on lifting hook 38.

Connecting element 10 (Figures 3 and 4A) is shown in the extended position 56.

Connecting element 10 comprises hook 44 which is hingedly connected to piston 46 by means of hinge connection 50. Hook 44 can be hinged about hinge connection 50 by means of hook cylinder 48. Hook cylinder 48 is pulled so that hook 44 points upwards. Piston 46 is arranged telescopically in housing 52. In the embodiment shown, housing 52 is beam-shaped. It is clear to the skilled person that other shapes, such as a cylindrical housing 52, are also possible. Piston 46 is movable in housing 52 by means of piston cylinder 54. By extending or retracting piston cylinder 34, the protruding length of hook 44 relative to housing 52 can be adjusted. In the extended position 56, the extended length is Lj.

Connecting element 10 (Fig. 4B) is shown in retracted position 42. In retracted position 42, piston cylinder 54 is retracted, causing hook 44 to be partially positioned within housing 52. In retracted position 42, the extended length Ls.

Connecting element 10 (figure 5) is shown on first side 7 in extended position 56. Housing 52 is attached to frame 4. Hook cylinder 48 is retracted so that hook 44 points upwards. This makes it easy to attach hook 44 to an eye or connecting rod of an excavator. On second side 8 a similar connecting element 10 is provided so that conveyor 2 can be connected to excavator 60 on both sides 7,8.

Obstruction wall 170 (Figure 6) is attached to frame 104 on first side 107.

Obstruction wall 170 extends substantially perpendicular to conveyor belt 120.

Because conveyor belt 120 runs on frame 104 parallel to the top surface of frame 104, obstruction wall 170 also extends substantially perpendicular to the top surface of frame 104. Connecting element 110 is connected to obstruction wall 170. Connecting element 110 is designed as a hook 144. Connecting element 110 is connected to obstruction wall 170 by hinge connection 174. Furthermore, hook cylinder 176 is provided on obstruction wall 170. Hook cylinder 176 is connected to obstruction wall 170 above hinge connection 174 and extends to cylinder hinge connection 178. This allows connecting element 110 to pivot about hinge connection 174 by adjusting the extended length of hook cylinder 176. This allows connecting element 110 to be automatically coupled to or disconnected from connecting rod 172 mounted on excavator 160. Input element 112 is provided on second side 108.

Obstruction wall 170 is further provided with two guard wheels 180. Guard wheels 180 face excavator 160. Guard wheels 170 are positioned such that the outer circumference of guard wheels 180 are in line with crawler tracks 182 of excavator 160.

During use, it is possible for conveyor 2 to swerve around the connection between connecting element 10 and the excavator. Protective wheels 180 prevent tracks 182 from hitting frame 104 during swerve or during other unwanted movement where frame 104 moves towards tracks 182. This reduces the chance of damage to the conveyor.

In one embodiment, input element 112 and obstruction wall 170 may be interchanged, i.e., input element 112 may be attached to first side 107 and obstruction wall 170 may be attached to second side 108 of frame 104. The hydraulic connections for hook cylinder 176 may be manually disconnected on first side 107 and connected on second side 108.

In one embodiment, conveyor 2 is provided. Second part 16 is set at a transport angle a. An articulated dumper is positioned under discharge end 24 of conveyor device 6. Piston 46 is positioned out of housing 52 of connecting element 10 by piston cylinder 54. Hook cylinder 48 is shortened so that hook 44 pivots about hinge connection 50. Hook 40 is then attached to an eye or connecting rod of an excavator on side 7 of frame 4. On side 7, wall part 28 is directed substantially upwards to retain material that the excavator places on feed end 23.

Input element 12 is arranged at an angle [3 relative to the top surface of frame 4 on second side 8. The excavator feeds material via input element 12 to feed end 23 of conveyor device 6. There the material is placed on conveyor belt 20. Drive 22 drives drive roller 21, causing conveyor belt 20 to feed material in transport direction T.

Transport direction T is perpendicular to the normal travel direction R of excavator 60. The material is lifted by second part 16 of transport device 6 so that it can be fed into the articulated dumper. The material is evenly distributed over conveyor belt 20 by guide housing 38, which reduces the loss of material to the side of conveyor belt 20. If the material has already been fed into the articulated dumper in the vicinity of conveyor 2, the bucket of the excavator can engage with lifting hook 38 and thereby lift conveyor 2. The excavator can then position itself to a next location so that new material can be fed to feed end 23.

The present invention is by no means limited to the above-described embodiments thereof. The requested protection is defined by the following claims within the scope of which many modifications are conceivable.

Claims (24)

CONCLUSIONS 1. Conveyor for transporting material, comprising: - a frame; - a transport device connected to the frame and provided with a drive, the transport device extending from a supply end to an output end and the transport device being adapted to transport material in a transport direction from the supply end to the output end; and - a connecting element arranged on a first side of the frame and adapted to connect the conveyor to an excavator, - an input element arranged on a second side of the frame, the second side being positioned opposite to the first side, the input element being adapted to guide material onto the transport device in a direction substantially perpendicular to the transport device. 2. A conveyor as claimed in claim 1, wherein the infeed element comprises an inclined plane adapted to guide material towards the infeed end of the conveyor. 3. A conveyor according to claim 1 or 2, wherein the connecting element comprises a hook-shaped element. 4. Conveyor according to claim 3 or 4, wherein a distance from the hook-shaped element to the frame in a direction perpendicular to the transport direction is adjustable. 5. A conveyor according to any preceding claim, wherein the first and second sides are both provided with a connecting element and an inlet element. 6. A conveyor according to claim 5, wherein the input element is a plate rotatably connected to the first and second sides, the input element having an inclined position and a loading position, in the inclined position the input element being adapted to guide material onto the conveyor and in the loading position the input element being positioned substantially vertically upwards and being adapted to retain material. 7. Conveyor according to any one of the preceding claims, wherein an obstruction wall 1s arranged on the first side is arranged to retain material, wherein the connecting element is arranged on the obstruction wall. 8. A conveyor as claimed in claim 7, wherein the obstruction wall and the inlet element are interchangeable. 9. Conveyor according to any one of the preceding claims, wherein a guide housing is provided on the conveyor device for guiding the material on the conveyor device. 10. A conveyor according to any preceding claim, wherein the transport device comprises a lifting hook, preferably positioned near the centre of gravity of the conveyor. 11. A conveyor according to any preceding claim, wherein the conveyor device comprises a conveyor belt. 12. A conveyor according to any preceding claim, wherein the conveying device is provided at a conveying angle relative to an upper surface of the frame. 13. A conveyor according to claim 12, wherein the conveying angle is in the range of 10-80 degrees, preferably in the range of 30-60 degrees, and most preferably in the range of 40-50 degrees. 14. A conveyor according to claim 12 or 13, wherein the conveyor comprises two parts, a first part extending towards the inlet end extending substantially parallel to the upper surface of the frame and a second part extending towards the outlet end extending at the conveying angle. 15. Conveyor according to any of claims 12 to 14, further comprising adjustment means connected to the transport device and adapted to adjust the transport angle by tilting the transport device relative to the frame. 16. A conveyor as claimed in any preceding claim, wherein the frame further comprises a battery operatively connected to the drive of the conveyor. 17. A conveyor according to any preceding claim, wherein the connection is a tiltable connection, the tiltable connection being tiltable about an axis extending substantially parallel to the normal direction of movement of the excavator. 18. A conveyor according to claim 17, wherein the connection comprises an operating position and a locking position, wherein in the operating position the connection is tiltable and in the locking position the connection is locked against tilting, wherein the connection can be placed in the locking position by lifting a side of the frame positioned away from the connection. 19. A conveyor according to any preceding claim, further comprising a remote control, wherein the connection is detachable by means of the remote control. 20. Conveyor according to any of the preceding claims, further comprising a sliding element arranged under the frame. 21. Excavator provided with a conveyor according to one of the preceding claims. 22. The excavator of claim 21 further comprising an eye or connecting rod mounted on the excavator, the eye or connecting rod being adapted to be connected to the connecting element of the conveyor. 23. Method for moving material, comprising: - providing an excavator according to claim 22; - placing material on the transport device with the excavator; and - transporting material to a desired location with the transport device. 24. The method of claim 23, further comprising: - connecting the conveyor to the excavator.