A CRANE

Abstract

A crane including a main boom having a first end portion and a second end portion, and being supported by a support structure via a hinged connection whereby the main boom is pivotable in a vertical plane. A pivoting assembly is arranged below the main boom, wherein the pivoting assembly includes an electric motor-and-winch assembly, a sheave assembly, and one or more drive wires extending between the motor-and-winch assembly and the sheave assembly.

Claims

1. A crane comprising: a main boom having a first end portion and a second end portion, and being supported by a support structure via a hinged connection whereby the main boom is pivotable in a vertical plane; and a pivoting assembly arranged below the main boom, wherein the pivoting assembly comprises an electric motor-and-winch assembly, a sheave assembly, and one or more drive wires extending between the motor-and-winch assembly and the sheave assembly.

2. The crane of claim 1, wherein the electric motor-and-winch assembly is arranged on an end portion of the main boom, and the sheave assembly is arranged on the support structure, or vice versa.

3. The crane of claim 1, further comprising a secondary boom which is slidably connected to the main boom and arranged for translatory motion with respect to the main boom, wherein: one or more power-and-transmission units connected to the main boom, wherein a power-and-transmission unit comprises a drive unit operatively connected to a first gear; at least a portion of the secondary boom comprising a second gear; and the first and second gears are dimensioned and configured for gripping engagement, whereby operation of the drive unit causes the secondary boom to move with respect to the main boom.

4. The crane of claim 3, wherein the drive unit is an electric motor.

5. The crane of claim 3, wherein the first gear is a circular gear and the second gear is a linear gear.

6. The crane of claim 3, wherein the secondary boom is slidably arranged inside at least a portion of the main boom.

7. The crane of claim 3, further comprising a pedestal having a slewing mechanism to which the support structure is rotatably connected.

8. The crane of claim 3, further comprising a main winch arranged on the secondary boom.

9. The crane of claim 8, wherein the main winch comprises an electric motor.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0014] These and other characteristics of the invention will become clear from the following description of an embodiment of the invention, given as a non-restrictive example, with reference to the attached schematic drawings, wherein:

[0015] FIG. 1 is a side view of an embodiment of the crane according to the invention, where the main boom is drawn partly transparent in order to illustrate a secondary boom inside the main boom;

[0016] FIG. 2 is an enlarged drawing of the area A in FIG. 1;

[0017] FIG. 3 is a sketch illustrating the principle of how the secondary boom may be moved with respect to the main boom; and

[0018] FIG. 4 is a side view of the crane illustrated in FIG. 1, in three different positions: fully raised and secondary boom retracted, intermediate and secondary boom extended, and fully lowered and secondary boom retracted.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

[0019] The following description may use terms such as horizontal, vertical, lateral, back and forth, up and down, upper, lower, inner, outer, forward, rear, etc. These terms generally refer to the views and orientations as shown in the drawings and that are associated with a normal use of the invention. The terms are used for the reader's convenience only and shall not be limiting.

[0020] Referring initially to FIG. 1 and FIG. 2, the crane 1 according to the invention comprises a superstructure 3 rotatably arranged on a pedestal 2. Rotating the superstructure around the pedestal vertical axis y is accomplished by the slewing mechanism 4, which is well known in the art. This slewing motion S is indicated by a left-hand arrow in FIG. 1, but it should be understood that the superstructure may be rotated also in the opposite direction. The pedestal comprises a boom rest 5 which is used for supporting a portion of the boom when the crane is not in operation. The pedestal is firmly connected to the deck (not shown) of a ship or other vessel, or to any other suitable foundation. Although the invented crane is particularly useful on a ship, it is equally applicable for use on a fixed foundation, onshore or at sea.

[0021] The superstructure 3 comprises a support structure 18, for example a column, to which the slewing mechanism is connected. In the upper end of the support structure, a hinged connection 8 is arranged, to provide a fulcrum and connecting the erect support structure to a main crane boom 6for example by means of a bolt or pin, or any other device which is known in the art. A service platform 15 is arranged on the support column 18.

[0022] The main boom 6 comprises a first (forward) end portion 6a and a second (rear) end portion 6b. The hinged connection 8 is arranged closer to the second end portion than to the first end portion. In FIG. 1, reference number 6c designates the main boom portion between the hinged connection 8 and the second (rear) end portion 6b, and is referred to a the pivot interface portion 6c.

[0023] The crane comprises a pivoting assembly 19, whereby the main boom 6 may be rotated (pivoted) about the hinged connection 8, in a vertical plane, as indicated by the double arrow P in FIG. 1. The pivoting assembly 19 is arranged below the pivot interface portion 6c. In the illustrated embodiment, the pivoting assembly 19 comprises a motor-and-winch assembly 12 arranged on the support structure 18, a rotary attachment device (for example a sheave) 14 arranged at or near the main boom second end portion 6b), and one or more drive wires 13 extending between the motor-and-winch assembly 12. This pivoting assembly 19 enables pivoting motion P about the hinged connection 8. The drive wires 13 may be single or multi fall, depending on the application and operational requirements. A reversed arrangement is conceivable, i.e. where the motor-and-winch assembly is arranged on the boom and the sheave is arranged on the support structure. The motor in the motor-and-winch assembly 12 is preferably an electric motor.

[0024] In the illustrated embodiment, a secondary boom 7 is slidably connected to the main boom 6 and arranged for translatory motion T with respect to the main boom, along a main boom longitudinal axis x. In the illustrated embodiment, the main boom 6 is a box boom and the secondary boom 7 is slidably arranged inside at least a portion of the main boom 6. The secondary boom 7 is thus a telescopic boom, that may be retracted into and extended out from the main boom first end portion 6a. The main boom 6 may comprise one or more support structures 10 for the secondary boom, alternatively comprising friction-mitigating pads 10.

[0025] Arranged at the free end of the secondary boom is a main winch, which is configured and dimensioned for hoisting and lowering a payload via a lifting wire (not shown). The main winch 9 may be powered by an electric motor.

[0026] The translatory motion T (here: telescopic) of the secondary boom is achieved by one or more power-and-transmission units 11 connected to the main boom. FIGS. 1, 2, and 4 show three such units, but the invention shall not be limited to this number. The power-and-transmission unit comprises a drive unit 11 operatively connected to a first gear 16, and at least a portion of the secondary boom comprises a second gear 17. The first and second gears are dimensioned and configured for gripping engagement, whereby operation of the drive unit 11 causes the secondary boom to move (translate T) with respect to the main boom.

[0027] Although, in the illustrated embodiment, the secondary boom 7 is shown as being arranged for telescopic movement inside a box boom 6, it should be understood that the main boom and secondary boom may be slidably interconnected in other configurations.

[0028] Referring to FIG. 3, the first gear 16 is a circular gear and the second gear 17 is a linear gear, in combination a rack-and-pinion drive. The drive unit 11 is an electric motor, rotatably connected to the first gear.

[0029] Required power cables and other equipment for operating the electric motors described above are not described, as such are well known in the art.

[0030] Although not illustrated, it should be understood that a third boom may be arranged in relation to the secondary boom in a manner similar to how the secondary boom is arranged in relation to the main boom (and so on for a boom four, five, etc.).

[0031] In FIG. 4, the invented crane 1 is illustrated in three different angular positions: Ia fully raised positon, IIan intermediate positon, and IIIa fully lowered position. In the positions I and III, the secondary boom 7 is fully retracted, while it is fully extended in position II. It should be understood that the secondary boom may be extended (completely or partly) at any angular position of the main boom. In its fully extended position, the secondary boom 7 may be extended completely beyond the hinged connection 8, i.e. on the side of the first (forward) end portion 6a. The main and secondary booms are balanced by the pivoting assembly (motor-and-winch assembly 12 and drive wires 13).

[0032] Position III may be used as a parking position when the crane is not in use, a portion of the main boom being supported by the boom rest 5.

[0033] FIG. 4 illustrates the versatility and improved operational range of the invented crane, compared to cranes of the prior art. One significant aspect of the invented crane, is that the pivoting assembly 19 is arranged below the main boom 6, and there is no tower or other element extending above the main boom. This allows for the extended operation envelope illustrated in FIG. 4. The electric motors and the associated gears and assemblies make hydraulic cylinders and a tower (normally extending above the main boom in cranes types of the prior art) superfluous. The electric motor in the pivoting assembly 19 also provides for instantaneous and stepless response when necessary. In a dynamic situation, for example when the crane is used for shifting cargo between vessels or between a vessel and a platform, the main boom is moving in the vertical plane. These movements may cause alternating tension and relaxation in the pivoting wires 13. The electric motor in the pivoting assembly 19 will be able to react instantaneously in order to compensate for the boom movements and maintain appropriate tension in the wires at all times, and thus preventing slack in the wires.

[0034] The main boom may be lowered much farther downwards and much closer to the pedestal 2 (position III) than cranes of the prior art, which means that an operator may move the boom close to a payload without having to pay out much of the lifting wire. The invented crane is also more compact when not in use, and occupies less deck space than a conventional tower crane.

[0035] As described above, the invented crane is all electrically powered, with no need for hydraulic actuators and associated equipment. The electric motors (and associated control system, not shown) allow for an improved three-dimensional control of the crane, with more accurate response times than traditional hydraulic cylinders. This is particularly relevant when the crane is installed on a ship or other vessel, where the ability to quickly control pivot P, slewing S, and telescoping T, is important to compensate for the ship's movement.