WO2016005335A1 - Heavy duty vehicle with a lifting apparatus for lifting and lowering a container - Google Patents

Abstract

The invention relates to a heavy duty vehicle with a lifting apparatus for lifting and lowering a container, in particular an ISO container (2), which lifting apparatus comprises a load pickup means with a spreader frame (9) for picking up the container, and a lifting drive, via which the load pickup means can be lifted and lowered, wherein the heavy duty vehicle is movable freely via wheels (3) with rubber tyres and in particular is not rail-bound. In order to provide an improved heavy duty vehicle with a lifting apparatus for lifting and lowering a container, it is proposed that the lifting drive is in the form of a belt drive (10).

Description

 Heavy duty vehicle with a lifting device for lifting and lowering a

Containers

The invention relates to a heavy load vehicle with a lifting device for lifting and lowering a container, in particular an ISO container, a

 Load-receiving means comprising a spreader frame for receiving the container and a lifting drive, via which the load-receiving means can be raised and lowered, wherein the heavy-duty vehicle on rubber-tired wheels is free and in particular non-rail moved.

Typical applications of such heavy-duty vehicles are the handling and transport of containers, in particular standardized ISO containers, within container terminals at sea or inland ports or in container terminals for combined traffic between road and rail.

In particular, heavy-duty vehicles are used, over whose

Lifting device as a Spreader or Spreaderrahmen designated

Lifting and lowering of lifting equipment is to pick up containers, lift and park after a transport at a destination again.

A special type of such heavy duty vehicles provide so-called

Portal lifting devices, which are also used as straddle carriers, gantry trucks,

Portal Stacker, Straddle Carrier, Forklift Truck, Reach Stacker, Van Carrier, Shuttle Carrier or Runner are known. In these gantry lifting devices, the lifting device is designed as a gantry lifting device with a spider-leg-like structure, which is why they run over a resting on the ground or on another container container and this also depending on the design and a raised

Can transport containers. Depending on the height, the gantry lifting devices are referred to, for example, as 1 over 3 devices, 1 over 2 devices, and so on. A 1-over-3 device can run over three stacked containers with a container in it.

In this context, ISO containers are understood as standardized large-capacity or sea freight containers that are used in the international market

Goods traffic are used. Most widely used are ISO containers with a width of 8 feet and a length of 20, 40 or 45 feet.

Such heavy duty vehicles are rubber-tired and hall-bound via a corresponding tire, but not rail-bound and thus freely movable. Accordingly, the heavy vehicles of the present invention are of

 Rail vehicles to distinguish. The heavy-duty vehicles can also be controlled manually by a driver driving in a driver's cab, semi-automatically or with so-called Automated Guided Vehicles (AGV).

"Driverless" here refers only to the actual intervention of a driver in the control process

Heavy truck also be given when a driver mitfährt, but this does not actively interfere with the control. The drive of these heavy-duty vehicles is usually diesel-electric, diesel-hydraulic or fully electric.

Heavy duty vehicles with lifting devices of the type described above

For example, from the German patent application DE 10 201 1 001 847 A1 and from the German utility model DE 20 2004 018 066 U1 known. The lifting drives the lifting devices of this heavy-duty vehicles are designed as rope drives or lifting mechanism. Also the use of chain drives as

Lifting drive for corresponding lifting devices is known.

From the European patent EP 1 094 982 B1, a rail vehicle is known, which has a structure in the manner of a straddle carrier. The

Rail vehicle is movable along rails that form rows of a warehouse of disk stacks. In order to be able to store or displace the stack of plates arranged on a pallet and lift and lower them for this purpose, the rail vehicle comprises a lifting device with a load-receiving means. The

Load-receiving means has substantially two spaced apart

Side members on which the pallet is supported with two opposite longitudinal sides during lifting and lowering. About trained as a belt drive

Lifting drive can be lifted and lowered accordingly between the longitudinal sides of a pallet cross-member longitudinal support between vertical supports of the rail vehicle. The use of a belt drive as a lifting drive is known from DE 699 33 597 T2 in relation to a hoist, from DE 10 2005 016 137 A1 with respect to a

Mast and from WO 2014/085943 A2 in relation to a lift known. On this basis, it is the object of the present invention to provide an improved heavy-duty vehicle with a lifting device for lifting and lowering a

To provide containers.

This object is achieved by a heavy vehicle with the features of claim 1. In claims 2 to 10 advantageous embodiments of the heavy truck according to the invention are given.

A heavy-duty vehicle with a lifting device for lifting and lowering a container, in particular an ISO container comprising a load-carrying means with a spreader frame for receiving the container and a lifting drive, via which the load receiving means can be raised and lowered, said

Heavy-duty vehicle on rubber-tired wheels is free to move and especially non-rail, is improved by the lifting drive is designed as a belt drive. Compared with the known from the prior art linear actuators, especially against rope and chain drives, a belt drive is much easier to maintain in outdoor use and thus more cost-effective.

Belt drives are not subject to corrosion and lubrication is not required. The above points lead to an overall increase

Lifetime of the lifting drive. In addition, smaller components can be used, as the usable belt is generally advantageous

have geometric dimensions compared to appropriately usable ropes or chains. The required dimensions of these ropes or chains, in particular the rope diameters, in contrast, are relatively large, which requires the use of correspondingly large components in rope and chain drives.

It is advantageously provided that the belt drive is designed as a flat belt drive. As a result, the life is further increased. Flat belts have a particularly long service life, as during operation of the belt drive at

Flat belt compared to other belt forms almost exclusively the neutral fiber is loaded. Accordingly suitable are flat belts with in Essentially rectangular cross-sections. If, due to the application, not a so-called multi-layer winding is required, other belt cross-sections are also conceivable, for example toothed belts. In addition, the use of smaller compared to rope and chain drives components is possible.

A structurally particularly simple use of a belt drive

trained lifting drive is possible when the lifting device as

Portal lifting device is formed. In a structurally simple manner is also provided that the belt drive comprises at least one belt, a winding device for winding or unwinding of the belt and a Umlenkrollensystem through which the belt is guided flaschenzugartig and to which the load-receiving means can be fastened.

Advantageously, it is also provided that the belt drive comprises four belts and four Umlenkrollensysteme, is guided by a flaschenzugartig each of Umlenkrollensysteme one of the belt and the load-carrying means on the four Umlenkrollensystemen fastened. As a result, a rotationally free lifting or lowering of the load-receiving means is possible without elaborate guides must be provided for the load-carrying means.

In a structurally simple manner is also provided that the belt drive for each belt comprises a winding device for winding or unwinding of the respective belt. As a result, smaller and cheaper winding devices and drives for the winding devices can be used.

Advantageously, it is provided that the belt drive a first

Belt drive unit and a second belt drive unit and each of the two belt drive units comprises a winding device for simultaneously winding or unwinding a first belt and a second belt on a common coil of the winding device. The use of these so-called multi-layer windings is easy to implement and leads due to the reduced number of required winding devices advantageously to further cost optimization. In a structurally simple way is also provided that each

Umlenkrollensystem comprises a top bottle and a bottom block, each with at least one guide roller and the bottom block on her at least one

Deflection pulley is suspended on supporting strands of the guided by the Umlenkrollensystem belt.

Furthermore, it is advantageously provided that each deflection roller system comprises two deflection rollers and the lower block is suspended via its two deflection rollers on four supporting strands of the belt guided by the deflection roller system. Due to the four-stranded design of Umlenkrollensystems smaller sized and thus cheaper drives for the

Winding devices are used. In a structurally simple manner, it is provided that each Umlenkrollensystem, in particular the upper bottle, is suspended from the heavy load vehicle.

An embodiment of the invention will be explained in more detail with reference to the following description. Show it:

1 shows a view of a portal lifting device whose lifting drive is designed as a belt drive

 2 shows a side view of the lifting drive of the portal lifting device from FIG. 1 and FIG. 3 shows a section of the lifting drive according to FIG. 2.

FIG. 1 shows a view of a portal lifting device 1. The portal lifting device 1 is a heavy-duty vehicle with a lifting device designed as a portal lifting device for lifting and lowering a container, in particular an ISO container 2. The portal lifting device 1 is freely movable on a corridor surface 4 via a total of four rubber-tired wheels 3. The wheels 3 are arranged in the usual way in the corners of an imaginary rectangle. In principle, it is also possible to provide more than four rubber-tired wheels 3, if this is technically necessary. The wheels 3 of the portal lifting device 1 are fastened to two chassis carriers 5 which are each aligned with their longitudinal extent in the direction of travel F of the portal lifting device 1. The two chassis carriers 5 each comprise two of the wheels 3 which are in Direction of travel F seen are arranged at a distance one behind the other. The

Chassis supports 5 also have electric traction drives and electric

Steering motors for the wheels 3, which are fed by arranged within the upper frame 8 batteries 5a. Alternatively, the various drives of the portal lifting device 1 can also be designed as diesel-electric or diesel-hydraulic. Due to the existing single-wheel steering, various steering programs, such as an optimized one, can be controlled via an appropriate control system

Standard curve, circle, a turn around its own vertical axis or a crab can be realized. The portal lifting device 1 shown by way of example can be operated fully automatically as an AGV, however, as described above, it can also be designed to be manually or semi-automatically operable.

The two chassis supports 5 arranged parallel to one another and at a distance from each other are connected to one another via a front first portal frame 6a and via a rear second portal frame 6b. Accordingly, the two U-shaped portal frame 6a, 6b seen in the direction of travel F are arranged spaced from each other. Each of the two portal frames 6a, 6b comprises an upper horizontal and transverse to the direction of travel F aligned portal carrier 6c, at the lateral ends of which in each case a vertical gantry support 6d connects. About the portal supports 6d, the two portal frame 6a, 6b are based on the

 Chassis supports 5 from, resulting in a spider-leg like structure. The two gantry supports 6d of each gantry frame 6a, 6b and, accordingly, the two girder girders 5 are at least the width of an ISO container 2 spaced from each other. In addition, the two portal frame 6a, 6b are connected to each other via two spaced apart and aligned in the direction of travel F side member 7. The two gantry beams 6c and the side members 7 form one

Upper frame 8. On the upper frame 8, in particular on the gantry beams 6c, the lifting device is attached, via which the ISO container 2 can be picked up from the floor surface 4 and placed on the floor surface 4.

The lifting device essentially comprises an electric motor-operated

Lifting drive, via which a load-receiving means for receiving and handling the ISO container 2 in a substantially vertical stroke direction H can be raised and lowered. The lifting drive is a belt drive 10 in the form of a flat belt drive

trained and will be described in more detail below with reference to FIG 2. The load handling device essentially comprises a so-called

Spreader frame 9, in particular as a so-called single-lift or twin-lift

Spreader can be trained. In the twin-lift variant, two 20-foot ISO containers 2 arranged directly one behind the other in the direction of travel F of the portal lifting device 1 can be accommodated. For receiving an ISO container 2, so-called twistlocks of the spreader frame 9 engage in corresponding upper corner fittings of the ISO container 2, by the subsequent locking of which the ISO container 2 is fastened to the spreader frame 9. In the usual way, the load-carrying means below the upper frame 8 and between the portal supports 6d of the front first portal frame 6a and the portal supports 6d of the rear second portal frame 6b in the lifting direction H up and down movable.

Overall, the portal lifting device 1 exemplified in FIG. 1 is as

So-called 1 formed over 0 device, via which a recorded from the floor surface 4 ISO container 2 can be discontinued only on the floor surface 4 again. A stacking of ISO containers 2 is not possible in the illustrated 1 via O- Portalhubgerät due to its limited maximum lifting height h of the lifting device.

Of course, even with portal lifting devices with greater maximum lifting height h, for example 1 over 3 devices, or other heavy-duty vehicles with a lifting device, in particular a portal lifting device, and a corresponding lifting device for lifting and lowering a container or ISO container 2 of the linear actuator 10 as a belt drive, in particular flat belt drive, be formed.

FIG. 2 shows a side view of the lifting drive of the portal lifting device 1. The lifting drive designed as a belt drive 10 is fastened to the upper frame 8, in particular to the portal carriers 6c. The belt drive 10 essentially comprises a first belt drive unit 10a arranged on the front first portal frame 6a and a second belt arranged on the rear second portal frame 6b

Belt drive unit 10b (not shown in Figure 2). Each of the two

Belt drive units 10a and 10b has a drivable winding device 10c to simultaneously drive a first belt 10d and a second belt 10e on one side coil coiling the winding device 10c or to be able to unwind. The belts 10d, 10e are preferably as a composite belt with a plastic sheath and at least one of them enclosed

Pull cord, such as a plastic or steel tendon formed. In the manner of a block and tackle, the first belt 10d is guided through a first deflection roller system 11a and the second belt 10e through a second deflection roller system 11b. In this way, a total of four pulley-like partial belt drives of the belt drive are formed. At the lower ends of the four partial belt drives respectively

 Umlenkrollensysteme 1 1 a, 1 1 b in each case an attachment point BP is formed. At the four attachment points BP of the spreader frame 9 is suspended with two extending in the direction of travel F carriers 9a. The two

Belt drive units 10a and 10b or their Umlenkrollensysteme 1 1 a, 1 1 b are arranged between the portal supports 6d of the first portal frame 6a and the second portal frame 6b, that the

Fixing points BP are arranged below the upper frame 8 in the corners of an imaginary rectangle and in a horizontal plane. In FIGS. 1 and 2, only the two non-hidden attachment points BP are marked in the region of the front first portal frame 6a. The front attachment points BP in the region of the first portal frame 6a are in each case via one of the carriers 9a with the corresponding rear attachment point BP in the region of the second

Portal frame 6b connected. In addition, the spreader frame 9 comprises two transverse beams 9b, of which in each case a cross member 9b extends between the portal supports 6d of the first and second portal frame 6a, 6b. About the cross member 9b, the carrier 9a are connected to each other in the region of the attachment points BP. The cross member 9b serve as a guide of the spreader frame 9 between the

Portal supports 6d. As a result of the fact that the first and the second belt drive units 10a, 10b are operated in synchronism via an unillustrated control, all four can be operated

Fixing points BP and thus also raise it on its carrier 9a Spreaderrahmen 9 synchronously in the stroke direction H and lower. By the synchronism of the two belt drive units 10a, 10b or their belt 10d, 10e and the associated synchronous lifting or Lowering the four attachment points BP, a container received by the spreader frame 9 can safely and essentially without rotation in the container

Lifting direction H can be raised and lowered. In FIG. 2, one of the

Spreaderrahmen 9 recorded ISO container 2 raised to the maximum lifting height h.

Due to the same construction of the two belt drive units 10a, 10b, only the first belt drive unit 10a shown in FIG. 2 will be described below. The winding device 10c of the first belt drive unit 10a is transverse to

 Direction of travel F seen centrally between the two Umlenkrollensystemen 1 1 a, 1 1 b on the upper frame 8, in particular on the gantry support 6c of the first

Portal frame 6a, attached. The winding device 10c of the first belt drive unit 10a is driven via an electric drive motor 10g (see also FIG. 1) and a transmission (not shown). In addition, the first belt drive unit 10a includes a brake device 10h to stop the winding device 10c. The drive motor 10g and the braking device 10h are arranged within the upper frame 8 and preferably on an inner side of the corresponding gantry carrier 6c. On an outer side of the gantry carrier 6c, the winding device 10c and in particular its coil is arranged and connected through the gantry carrier 6c through the transmission to the drive motor 10g and the braking device 10h.

The first belt drive unit 10a is essentially formed by the first belt 10d of the first pulley-like belt drive and the second belt 10e of the second pulley-like belt drive each being fastened with its upper first end to the common reel of the winding device 10c. The attachment is such that the two belts 10d, 10e of the

Winding device 10c or its coil can be coiled in the same manner in the manner of a so-called multi-layer winding or unwound to raise the Spreaderrahmen 9 or lower. For this purpose, the first ends of the belt 10d and 10e are preferably on the

Winding device 10c attached, that they relative to the circumference of the coil run opposite each other or offset by 180 degrees from the coil. To form the belt drive 10 as a flat belt drive, the belts 10d and 10e are preferably a flat belt with a substantially rectangular

Cross section formed.

All flaschenzugartigen partial belt drives of the embodiment are the same, in particular four-stranded, formed. By way of example, the structure of the first partial belt drive will be described below, which is depicted as a section of the first belt drive unit 10a in FIG.

The first belt 10d is fastened with its first end to the coil of the winding device 10c and, starting therefrom, is guided through the first deflection roller system 11a. The Umlenkrollensystem has in flaschenzugtypischer manner on two upper fixed and two lower loose pulleys. In particular, the first belt 10d is guided over the fixed and loose deflection rollers of the first deflection pulley system 11a in such a way that the four load-bearing strands of the first partial belt drive are formed. For this purpose, the first belt 10d is fastened with its second end via a spring 10f to an upper fixed point FP on the first deflection roller system 11a. The two upper pulleys of the first pulley system 1 1 a are rotatably mounted in a top bottle 1 1 c. Here, the pulleys are arranged one above the other or next to each other between and along the longitudinal extent of flachstabförmigen side walls of the upper bottle 1 1 c. The upper bottle 1 1 c is suspended with its upper first end via a bearing 1 1 e on an outer side of the gantry 6c pendulum, but suspended translationally. As a result, the two pulleys of the upper bottle 1 1 c in flaschenzugtypischer manner to fixed pulleys of the pulley-like Teilriemenzugs. Accordingly, the upper bottle 1 1 c moves during winding or unwinding of the first

Belt 10d not in lifting direction H up or down.

The axes of rotation of all the pulleys of the upper bottle 1 1 c, the bearing 1 1 e and the coil of the winding device 10c are aligned parallel to each other and in the direction of travel F. A pendulum of the upper bottle 1 1 c along the first portal frame 6a and transversely to the direction of travel F is limited in the direction of the winding device 10c by a stop 1 1f. The stop 1 1 f is at the first portal frame 6a arranged that the upper bottle 1 1 c with its longitudinal extent vertically in

Lifting direction H is aligned when the upper bottle 1 1 c rests with its lower second end to the stop 1 1f. Here, the stopper 11f is disposed at the lower end of the upper bottle 11c between the side walls thereof and the first belt 10d.

The two lower pulleys of the first pulley system 1 1 a are stored in a comparable with the top plate 1 c lower block 1 1 d. About her two pulleys, the lower block 1 1 d suspended from the four load-bearing strands of the pulley-like Teilriementriebs. This will be the two

To loosen pulleys of the bottom block 1 1 d in a pulley typical way

Pulleys of the pulley-like sub-belt pulley. Accordingly, the lower block 11 d moves up or down in the lifting direction H during winding or unwinding of the first belt 10d. The lower block 1 1 d is aligned with its longitudinal extent in the stroke direction H and with the upper bottle 1 1 c aligned.

Below the lowest loose pulley forms the bottom block 1 1 d at its lower end one of the attachment points BP. At the lower end of the upper bottle 1 1 c is the upper fixed point FP for the second end of the first belt 10 d. The spring 10f is disposed at the second end between the fixed point FP and the uppermost pulley of the lower block 11d.

All pulleys of about the upper bottle 1 1 c pendulum suspended first pulley system 1 1 a are together with the upper bottle 1 1 c and the

 Bottom 1 1 d arranged in an imaginary vertical plane. The outermost deflection rollers seen in the stroke direction H have a roller diameter which is larger than the roller diameter of the inner deflection rollers arranged therebetween. Preferably, the roll diameter of the outer and inner pulleys are the same size.

In the same way as described above for the first pulley-type partial belt drive, the second belt 10e and the second pulley system 11b form the second pulley-like partial belt drive of the first belt drive unit 10a (see FIG. 2). In order to protect the belt drive 10, can be provided on the upper frame 8 and on the portal frame 6a, 6b not shown plate-shaped covers. The belt drive 10 is concentric with respect to the lifting device of

 Heavy load vehicle and the load receiving means arranged, resulting in this respect a correspondingly symmetrical arrangement in particular of the belt drive units 10a, 10b, the belt 10d, 10e, the Umlenkrollensysteme 1 1 a, 1 1 b and the attachment points BP results.

In the present embodiment, all four pulleys are four-stranded. Of course, however, the pulleys may also have a different number of fixed or loose pulleys associated therewith a different number of supporting strands. Likewise, the fixed point FP can also be provided on the bottom block 1 1 d.

Basically, it is also possible that for each of the four pulley-like part belt drives or their belts 10d, 10e a separate

Winding device 10c is provided. The winding devices 10c are then each independently driven and are operated via a corresponding control in the synchronization described above. Accordingly, four independent belt drive units are then provided, each comprising a belt, a pulley system and a winding device 10c for the belt and a drive motor 10g, a transmission and a braking device 10h for the

Have winding device 10c.

However, the belt drive 10 may also have less than four belts, for example, only a single belt or on both gantry frames 6a, 6c each have a belt. Accordingly, then only one attachment point BP

or two attachment points BP provided. A rotationally free lifting or lowering of one of the spreader frame 9

taken container in the stroke direction H is possible in this case, by the torque equalization one or more corresponding guides

or traverses for connecting the Spreaderrahmens 9 are used. LIST OF REFERENCE NUMBERS

1 portal lift

 2 ISO containers

 3 wheel

 4 corridor area

 5 chassis carrier

 5a battery

 6a first portal frame

6b second portal frame

6c portal carrier

 6d gantry support

 7 side members

 8 upper frame

 9 spreader frame

 9a carrier

 9b cross member

 10 belt drive

 10a first belt drive unit

10b second belt drive unit

10c winding device

 10d first belt

 10e second belt

 10f spring

 10g drive motor

 10h braking device

 1 1 a first pulley system

1 1 b second pulley system

1 1 c upper bottle

 1 1 d bottom bottle

 1 1 e bearings

 1 1f stop

BP attachment point

F direction of travel benchmark

Lifting height

stroke direction

Claims

claims

1 . Heavy goods vehicle with a lifting device for lifting and lowering a container, in particular an ISO container (2), which comprises a load receiving means with a spreader frame (9) for receiving the container and a lifting drive, via which the load receiving means can be raised and lowered, wherein the

Heavy-duty vehicle on rubber-tired wheels (3) free and in particular non-rail is movable, characterized in that the lifting drive is designed as a belt drive (10).

2. heavy-duty vehicle according to claim 1, characterized in that the belt drive (10) is designed as a flat belt drive.

3. Heavy-duty vehicle according to claim 1 or 2, characterized in that the lifting device is designed as a portal lifting device.

4. Heavy-duty vehicle according to one of claims 1 to 3, characterized in that the belt drive (10) at least one belt (1 Od, 10e), a

Winding device (10c) for winding or unwinding of the belt (1 Od, 10e) and a Umlenkrollensystem (1 1 a, 1 1 b), through which the belt (1 Od, 10e) is guided like a pulley and to which the load-receiving means can be fastened ,

5. Heavy-duty vehicle according to claim 4, characterized in that the belt drive (10) four belts (1 Od, 10e) and four Umlenkrollensysteme (1 1 a, 1 1 b), by each of the Umlenkrollensysteme (1 1 a, 1 1 b ) one of the belts (1 Od, 10e) is guided like a pulley and the load-carrying means on the four

Umlenkrollensystemen (1 1 a, 1 1 b) can be fastened.

6. Heavy-duty vehicle according to claim 4 or 5, characterized in that the belt drive (10) for each belt (1 Od, 10e) comprises a winding device (10c) for winding or unwinding of the respective belt (1 Od, 10e).

7. Heavy-duty vehicle according to claim 4 or 5, characterized in that the belt drive (10) has a first belt drive unit (10 a) and a second Belt drive unit (10b) and each of the two belt drive units (10a, 10b) comprises a winding device (10c) for simultaneously winding or unwinding a first belt (10d) and a second belt (10e) on a common coil of the winding device (10c).

8. Heavy-duty vehicle according to one of claims 4 to 7, characterized in that each pulley system (1 1 a, 1 1 b) a top bottle (1 1 c) and a

Includes lower block (1 1 d), each with at least one pulley and the

Lower bottle (1 1 d) on its at least one deflection roller on supporting strands of the by the Umlenkrollensystem (1 1 a, 1 1 b) guided belt (1 Od, 10e) is suspended.

9. Heavy-duty vehicle according to claim 8, characterized in that each Umlenkrollensystem (1 1 a, 1 1 b) comprises two pulleys and the lower block (1 1 d) via its two pulleys on four supporting strands of the by the

 Umlenkrollensystem (1 1 a, 1 1 b) guided belt (1 Od, 10e) is suspended.

10. Heavy-duty vehicle according to claim 8 or 9, characterized in that each Umlenkrollensystem (1 1 a, 1 1 b), in particular the upper bottle (1 1 c), is suspended from the heavy load vehicle suspended.