NL1036291C2 - PNEUMATICALLY CONTROLLED LIFTING EQUIPMENT FOR LIFTING, AND ONE FOR ONE PLACE OF CONCRETE ARMMATS. - Google Patents

Description

Pneumatically operated hoisting tools for hoisting, and placing concrete reinforcement mats one by one.

5 Description lifting equipment:

The concrete reinforcement mats are removed from the stack one by one, either by hand or with a hoisting device and a four-drop chain, and placed in place.

This special hoisting tool has been developed to pick up a stack of concrete reinforcement mats 10 in one go and to place these mats from below, one by one. The operation is done by one person on the hoisting tool and one person in a hoisting tool.

An employee uses the handlebar to steer the hoisting tool directly above the stack. By means of a hoisting device, this hoisting tool can be lowered onto a stack of concrete reinforcement mats stacked on top of each other. When sagging, the six unloading units slide over the 15 bars of the concrete reinforcement mats.

When lifting, the six tempering units grab the bars of the concrete reinforcement mats. Now the hoisting tool with the concrete reinforcement mats can be lifted to the place where they can be placed one by one. The advantage of this hoisting tool is that with much less labor, and hoisting movements, it is possible to place the concrete reinforcement mats faster and ergonomically.

1036291 2

Pneumatically operated hoisting tools for hoisting, and placing concrete reinforcement mats one by one.

5 Description and operation of the main frame: Fig.1

The hoisting tool consists of a main frame made of tubular profile. Fig.1 pos.1.

On the main frame there are six, horizontally movable, discharge units, Fig. 1 pos.4, 7, 10, 11, 15 and 20. The discharge units, Fig. 1, pos. 4, 7, 10, 11, 15 and 20 can be continuously can be pushed onto every stitch size and fixed by means of a lever, Fig.3 pos.30.

The dimensions of the main frame have been chosen such that several types of concrete reinforcement sizes can be loaded. The operation of the six discharge units, Fig. 1 pos. 4, 7, 10, 11, 15 and 20, is effected centrally by means of a pneumatic hand valve. Fig.1 pos.6. Extendable tubes are fitted at four points in the frame. Fig. 1, 2, 3, 9 and 12. These sleeves are provided with locking pins. The hoisting tool 15 stands on these extendable tubes when it is not being used. The lifting frame has four lifting eyes. Fig. 1 pos.8, 13, 18 and 19. The hoisting tool can be stably suspended in the hoisting device by means of a four-way jump. Mounted on one long side of the main frame in a handlebar bracket, Fig.1 pos.5. The height of the handlebar is chosen such that the worker can stand upright, while the mats fall out of the hoisting tool at knee height. The depth of the handlebar is also shown, FIG. 1 20 pos.5, chosen so that the side stitches of the concrete reinforcement mats cannot fall to the worker when falling. The handlebar bracket, Fig.1 pos.5, can be easily folded up so that the hoisting tool falls within the dimensions of the truck.

There is a removable pneumatic compressor on the main frame, Fig.1 pos. 16 confirmed. Opposite this pneumatic compressor, Fig.1 pos.16, is a demountable electric power unit, Fig.1 pos.14. This electrical unit, Fig.1 pos.14, provides the electrical current for the pneumatic compressor, Fig.1 pos.16. The pneumatic compressor, Fig.1 pos.16, supplies the six discharge units, Fig.1 pos.4,7,10,11,15 and 20, with compressed air. The electrical unit, Fig.1 pos.14, and the pneumatic compressor, Fig.1 pos.16, are protected by a steel case for theft prevention.

3

Description of the discharge unit: Fig.2

A discharge unit is mounted horizontally slidably with in the main frame, Fig. 1 pos. 1, by means of the discharge unit subframe, Fig. 2 pos. 12. By means of the locking lever.

Fig. 3 pos.30 is to fix the discharge unit subframe to the main frame. Fig.1 pos.1.

Clamping cams, Fig. 3 pos.31 and 32 ensure that the discharge unit cannot be lifted from the main frame.

On the unloading unit subframe, Fig. 2 pos. 12, are two U-profils. Herein the annealing unit can, by means of the slider block, Fig. 2 pos. 10, and upper sliding block, Fig. 2 pos. 15, vertically 10. This is to compensate for the difference in height of a stack of concrete reinforcement mats. Between the sliding block, Fig. 2 pos. 10, and the top sliding block, Fig. 2 pos. 15, two tension springs, Fig. 2 pos. 27 and 28, are placed. These two tension springs together ensure that the outer jaws, Fig. 2 pos. 1,2,3 and 26, in the uncontrolled state, are pulled apart at the bottom.

15 There are four outer jaws per discharge unit, Fig.2 pos. 1,2,3 and 26, and two inner jaws, Fig.2 pos.4 and 29. The inner jaws, Fig.2 pos.4 and 29, are rotatably attached to the central pin. Fig.2 pos.5. The upper side of the inner jaws are rotatably attached to the lower levers Fig. 2, pos. 7,8 and 11, by means of a pin. Fig.2 pos.6 and 13. The lower levers are rotatably attached to the lower sliding block via a pin, fig.2 pos.9, Fig.2 pos. 10. On top of the slide-under block, Fig. 2 pos. 10, the bellows cylinder, Fig. 2 is pos. 14 confirms.

The outer basin, Fig. 2 pos. 1,2,3 and 26 are rotatably attached to the central pin in the middle. Fig.2 pos.5. The top of the outer basin, Fig. 2 pos. 1,2,3 and 26, are rotatably attached to the upper levers Fig. 2 pos. 17 to 20, by means of a pin. Fig.2 pos.21 and 24. The upper levers, Fig.2 pos. 17 to 20 are central, via a pin fig. 2 pos. 16, rotatably attached to the upper sliding block, Fig. 2 pos. 15. At the bottom of this upper sliding block

Fig.2 pos. 15, is the bellows cylinder. Fig.2 pos. 14, confirms.

At the top of the outer jaws there are two stroke limiting profiles, Fig.2 pos.22 and 23, slidable over pin, Fig.2 pos.24 and rotatable around pin, Fig.2 pos.21.

In these stroke limiting profiles, Fig.2 pos.22 and 23, there is a latch pin, Fig.2 pos.25, which is the outward stroke of the outer jaws, Fig.2 pos. 1,2,3 and 26. It is possible to place the locking pin, Fig.2 pos.25, in two different places in the holes of the stroke limiting profiles. The stroke limit can be set in this way.

(To make all parts visible, outside jaw, Fig.2 pos.2, has been omitted.) 4

How the unloading unit works: 1. Loading the concrete reinforcement mats. Fig.3 5 If the bellows cylinder, Fig.3 pos.14, is not operated, the outer jaws, Fig.2 pos. 1,2,3 and 26, by the tension springs, Fig. 2 pos. 27 and 28, pulled towards each other at the top. This creates sufficient space at the bottom of the outer basin, Fig.3 pos. 1,2,3 and 26, to be able to freely lower over the threaded rods of the concrete reinforcement mats.

10 When the hoisting tool is lowered, the inner jaws, Fig. 3 pos. 4 and 29, are placed on the threaded rod of the upper concrete reinforcement mat, Fig. 3, item 32. Due to the weight of the discharge unit, the inner jaws Fig. 3 pos.4 and 29, pressed onto the threaded rod of the concrete reinforcement mat. Due to the sloping edges on the underside of the inner jaws, Fig. 3 pos. 4 and 29, the inner jaws are pushed out by the threaded rod. When the threaded rod has passed the triangular protrusion of the inner jaws, the inner jaws, Fig. 3 pos. 4 and 29, fall against each other again due to their own weight. This process is repeated every time a threaded rod passes. Until the desired number of concrete reinforcement mats is loaded.

20 2. Lifting a number of concrete reinforcement mats. FIG

Once the correct depth has been reached, lifting armor mats can be started. When the main frame, Fig.1 pos.1 is lifted, the slider block slides, Fig.2 pos. 10 up to the bottom stop in the discharge unit subframe, Fig. 3 pos. 12. The annealing unit is then also hoisted up. The concrete reinforcement mats, Fig. 4 pos.32, hang on top of the triangular protrusions of the inner jaws, Fig. 4 pos. 4 and 29. Due to the shape of the inner jaws, Fig. 4, items 4 and 29, they clamp underneath the lower threaded rod, of the lower concrete reinforcement mat, Fig. 4 pos.32, of the number of concrete reinforcement mats to be hoisted. The heavier the stack, the greater this clamping force. The rest of the concrete reinforcement mats, Fig. 4 pos.32, lie on top of the clamped concrete reinforcement mat and are thus hoisted up.

5

The operation of the discharge unit: 3. Separation of the lower concrete reinforcement mat. Figures 4 and 5.

5 By operating the pneumatic valve, Fig.1 pos.6, the bellows cylinder, Fig.4 pos.14, goes out. As a result, the upper levers press, Fig. 4 pos. 17 to 20, the outer basin,

Fig. 4 pos. 1,2,3 and 26, outwards at the top. As a result, the outer jaws close, Fig. 4 pos. 1,2,3 and 26, located at the bottom. This stroke is limited by the locking pin, Fig. 4 pos.25, which protrudes into the stroke limiting profiles, Fig. 4 pos.22 and 23. As soon as the outer jaws, Fig. 4 pos. 1,2,3 and 26, touching the bottom, the clamping force passes from the inner jaws, Fig. 4 pos. 4 and 29, to the outer jaw, Fig. 4, pos. 1,2,3 and 26. This opens the inner jaws, Fig. 5 pos. 4 and 29. The entire stack of concrete reinforcement mats to be hoisted, Fig. 5 pos.32, falls out of the inner basin, Fig. 5 pos. 4 and 29, and ends up in the closed outer basin, Fig. 5 pos. 1,2,3 and 26. The fall distance can be adjusted by means of the locking pin, Fig. 5 pos. 25 in the stroke limiting profiles, Fig. 5 pos. 22 and 23.

4. Unloading the lower concrete reinforcement mat. 6 and 7.

Through the pneumatic valve, FIG. 1 pos, 6 again to operate, the bellows cylinder goes,

Fig. 6 pos.14. This causes the clamping force to return from the outer jaws, Fig. 6 pos. 1,2,3 and 26, towards the inner pelvis, Fig. 6 pos. 4 and 29. Due to the shape of the inner jaws and due to the correct position of the locking pin, Fig. 6 pos.25, into the right hole of the stroke limiting profiles, Fig. 6 pos. 22 and 23, the inner jaws come, Fig. 4 pos.4 and 29, exactly below the 25th lower threaded rod, together. Only when this clamping force has completely passed, do the outer jaws, Fig.7 pos. 1,2,3 and 26. This causes the lower concrete reinforcement mat to fall, Fig. 7 pos.32, from the discharge unit. The rest of the concrete reinforcement mats to be hoisted, Fig.7 pos.32, remain clamped by the inner jaws, Fig.7 pos.4 and 29. By again operating the pneumatic valve, Fig.1 pos.6, you separate the next 30 concrete reinforcement mat from the pile, ..... etc, etc.

In this way, the entire stack of concrete reinforcement mats, Fig. 7 pos.32, is placed one by one.

1036291

Claims (6)

The hoisting tool according to claim 1, characterized in that it is provided with six independent, longitudinally shiftable discharge units. Fig. 1 pos. 4, 7, 10, 12, 15 and 20. 3. These annealing units, Fig. 1, pos. 4, 7, 10, 12, 15 and 20, according to claim 2, characterized in that it 1 person, from one central location, by means of electricity, hydraulics or pneumatics. Fig.1 pos.6. 4. These annealing units, FIG. 1 pos. 4, 7, 10, 12, 15 and 20, according to claim 2, characterized in that each discharge unit, by means of two U-profiles in the discharge unit subframe, Fig. 2 pos. 12, is slidable independently in high. 5. These annealing units, Figs. 1, 7, 7, 12, 12, 15 and 20, according to claim 2, characterized in that each annealing unit consists of a double set, double scissor movements, i.e. the two inner jaws, Fig.2 pos. 4 and 29, and the four outer jaws, Fig. 2 pos. 1, 2, 3 and 26, which by means of two sets of levers, Fig. 2 pos. 7,8 and 11, and Fig. 2 pos. 17 to 20, via one bellows cylinder, Fig. 2 pos. 14 are linked to each other. 6. These double scissor movements according to claim 5, characterized in that they have a common pivot point in the middle. Fig.2 pos.5. 7. These four outer jaws, Fig.2 pos. 1,2,3 and 26, according to claim 5, characterized in that the stroke of these outer jaws is adjustable by means of a locking pin, Fig. 2, item 25, in the stroke limiting profiles, Fig. 2, item 22 and 23. . 8. These double scissor movements according to claim 5, characterized in that the stack of concrete reinforcement mats is always clamped together by the inner or outer jaws, and because of this construction a stack of concrete reinforcement mats cannot fall out of the discharge unit, even if the electrical, hydraulic or pneumatic energy is lost. 1036291