DE403800C - Lifting gear for construction work like - Google Patents

Description

The increased requirements that the metallurgical plant and mining industry place on dimensions and The load-bearing capacity of the iron high-rise structures made it necessary to create special equipment, in order to be able to carry out the construction of these large structures quickly and safely. The mostly used wooden masts are no longer sufficient for larger dimensions and are replaced in these cases by a wide variety of iron construction masts.

The main condition that such a hoist must meet is stability. In view of the frequent lack of space and perfect maneuverability, an umbrella-like stranding of the upper part of the crane is used against the ground while maintaining the smallest possible contact area. The stability however, in most cases it is highly dependent on the load, the interception ropes get a lot of tension, have to be well anchored and maneuverable of the device can be arranged very numerous. In addition, not inconsiderable, horizontal forces occur at the foot of the crane, which must be absorbed by the respective securing in the ground. These anchorages in the subsoil are difficult to carry out at high loads, time-consuming and remain always more or less insecure, as one often remains dependent on the worker's sense of proportion.

This deficiency overcomes the present invention, because by discouraging everyone from the Load-resulting horizontal reaction at the head and foot of the standing tree, on the one hand no additional tensions get into the interception ropes and on the other hand a special observation of the stand foot is omitted. The interception ropes only have a vertical position of the device and to absorb the wind and vibration forces on a case-by-case basis. The number of these ropes remains independent of the load.

The subject matter of the invention is illustrated in the accompanying drawing.

Fig. Ι shows the overall arrangement.

Fig. 2 shows schematically the representation with the largest unloading width,

Fig. 3 the middle position,

Fig. 4 the position of the smallest projection.

Fig. 5 shows the system with the structure raised.

The hoist consists of the vertical column 5, at the head of which the load-bearing system, consisting of the cross beam Q, the feeder A and the cables a, v, r, I, g, is suspended freely.

The transverse tree Q is the one in Fig. 1

illustrated embodiment of a triangular isosceles frame is 5-3-3, hinged at its narrower side of the triangle 3-3 of likewise designed as a triangular frame jib A. With the two side parts 2-3 of the frame of the boom A is still a rectangular frame 3-3-8-8 perpendicular to the plane thereof in connection. This rectangular frame is suspended from the rope ν by means of two rods at 4. A counterweight G is suspended from the free end 5 of the transverse tree Q by means of the cable g and the load L is attached to the free end 2 of the boom A by means of the cable L - By attaching the counterweight G, the load L to be lifted is kept in balance. The largest unloading width e depends on the ratio of the load to the counterweight, but can be reduced as required by operating the cables accordingly.

The load rope I is used for the immediate lifting and lowering of the load.

The jib rope α enables the exact setting of the projection width e within certain limits.

The front rope ν and the return rope r are used for the rough setting of the desired radius e, as well as for changing the height of the load-bearing system.

The counterweight G is brought to the desired height by means of the counterweight rope g. The routing of the ropes can be seen from the drawing; the power ropes are dash-dotted, the interception ropes are shown in dashed lines. The former is operated from point 9.

The counterweight G remains during one

Working period is the same and is determined as a function of the respective largest product of the load L times the required unloading width e .

Points 1 to 6 generally describe curved paths that consist of more than ♦ 5 combine multiple circular and linear movements.

Between hooking on the load and lifting it off the ground, the constant takes place Transition of the equilibrium position of the unloaded crane to that of the loaded one; the analog Change takes place between placing the load and releasing the hook. The load can only be released after reaching the equilibrium position for relief possible.

The pivotability of the boom A is limited by its vertical position and the extended position with respect to the transverse boom. To prevent the slackening of the boom in a rope of the vertical position, the cable is eccentrically mounted on the boom ν A at step 3.

The vertical position of the boom A limits its movement. In this position, however, the entire (also vertical) load is transferred to A as a longitudinal force, so that the rope α would have to be tension-free if the pivot point of A and Q would coincide with the starting point of the rope ν. In order to keep the rope α constantly under tension, so that the boom A can also be tilted forward from its vertical position, the rope ν is eccentric by means of the frame 3-3-8-8, which is connected to the boom A so that it cannot rotate and is perpendicular to its plane, connected. This creates a torque in the steep positions of the boom that enables A to tilt forward.

Claims (3)

Patent Claims: 1. Lifting equipment for construction work and similar purposes, characterized in that that a carrier system that is in equilibrium in all lifting and rotating positions, which carries the load (Z.), floating freely at the head of a standing column (S) is suspended so that only perpendicular forces are transmitted to them. 2. Lifting device according to claim 1, characterized in that the support system suspended at the head of the vertical column consists of a transverse tree (Q) for receiving the counterweight and a boom (A) hinged to it for receiving the load and that the transverse tree and boom are articulated with one another communicating, during the suspension of the carrier system is carried out by means of three cables, of which the boom cable (a) allows for the accurate adjustment of the Ausladeweite (e), however, the force acting on the free end of the cross-tree (Q) return rope (/ ') and at the The connection point of the transverse boom and the front rope (v) engaging the boom are used for the rough setting of the desired unloading width and for changing the height of the carrier system. 3. Lifting device according to claim 1 and 2, characterized in that the front rope (v) engages the boom eccentrically. 1 sheet of drawings.