LOAD CELL

Abstract

The invention relates to a load cell for measuring the tension in a supporting cable of a lifting apparatus, the load cell comprising a first body which is in mechanical contact with a supporting structure of the lifting apparatus, a second body which is in mechanical contact with supporting means of the lifting apparatus, and connection means such as a ball-and-socket joint which mechanically couples one end of the first body to the corresponding end of the second body. Deformation measuring means are used to measure the deformation caused by the exertion of force by the second body of the cell on the first body when the load cell is subjected to compression forces.

Claims

1. A load cell for measuring the tension in a supporting cable of a lifting device, characterised in that the load cell (11) comprises a first body (12) in mechanical contact with a support structure of the lifting device; the first body (12) includes means for measuring the deformation exerted by a second body (13) of the cell (11), wherein one end of the first body (12) and the corresponding end of the second body (13) are mechanically joined by means of a male-female ball-and-socket type joint.

2. Cell, according to claim 1, wherein one end of the first body (12) comprises a concave seat (14) that serves as a housing for a convex protuberance (I 5) located at the corresponding end of the second body (13).

3. Cell, according to claim 1, wherein one end of the first body (12) comprises a convex seat (14) that serves as a housing for a concave protuberance (15) located at the corresponding end of the second body (13).

4. Cell, according to claim 1, wherein the male-female ball-and-socket joint is of the radial ball-and-socket joint type, the angular-contact ball-and-socket joint type, the axial ball-and-socket joint type, or similar.

5. The cell, according to claim 1, wherein the load cell (11) is configured to be installed between a spring whereon the supporting cable rests and a support structure of the lifting device.

6. The cell, according to claim 2, wherein the load cell (11) is configured to be installed between a spring whereon the supporting cable rests and a support structure of the lifting device.

7. The cell, according to claim 3, wherein the load cell (11) is configured to be installed between a spring whereon the supporting cable rests and a support structure of the lifting device.

8. The cell, according to claim 4, wherein the load cell (11) is configured to be installed between a spring whereon the supporting cable rests and a support structure of the lifting device.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0015] A more detailed explanation of the device according to embodiments of the invention is given in the following description based on the attached figures, wherein:

[0016] FIG. 1 shows a perspective view of a first body and a second body of a load cell for measuring the tension in a supporting cable of a lifting device;

[0017] FIG. 2 shows an elevational view of a cross-section of the load cell; and

[0018] FIG. 3 shows an elevational view of a section of different types of male-female ball-and-socket joints for the load cells.

DESCRIPTION

[0019] In relation to FIGS. 1 and 2, which show a load cell 11 for measuring the tension in each supporting cable of a lifting device.

[0020] The supporting cable is mechanically coupled to a traction unit, such that the load cell is subjected to compression, thereby bearing the stress of the supporting cable in order to provide a direct measurement of the tension in the cable.

[0021] Male-female ball-and-socket joint. This system for joining sections by means of an articulated ball makes it possible to absorb misalignments between two adjacent surfaces, thereby preventing significant torque loads.

[0022] The load cell 11 comprises a first body 12, which includes means for measuring the deformation of said cell when that load cell 11 is subjected to compressive stresses; and a second body 13 in mechanical contact with a support structure, which co-operate mechanically with a terminal end of the supporting cable of the lifting device, such that the supporting cable extends along a passthrough cylindrical cavity 21 defined along the axis of revolution of the load cell 11, wherein the supporting cable penetrates the cell 11 in its entirety, as shown in FIG. 2. Consequently, the supporting cable penetrates both the first body 12 and the second body 13 of the load cell 11; thus, both the first and the second body 12, 13 are mechanically coupled upon being a male-female ball-and-socket type joint that is subjected to compression; i.e. one end of the first body 12 comprises a concave seat 14 that serves as a housing for a convex protuberance 15 located at the corresponding end of the second body, or, vice versa, the end of the first body 12 is convex and the end of the second body has the corresponding concave shape.

[0023] The terminal end of the supporting cable projects from the flat upper side of the second body 13. The flat lower side of the first body 12 is in physical contact with a flat fixed surface of the support structure, such that, under compressive stress, the second body 13 of the load cell 11 tends to move towards the flat fixed surface of the support structure. The male-female ball-and-socket joint between the first body 12 and the second body 13 uniformly distributes the load and the compressive stress on the load cell, the first body 12 being compressed between the second body 13 and the flat fixed surface of the support structure. Deformation means, included in the load cell (11), measure the compression to which the first body 12 of the cell 11 is subjected.

[0024] The convex protuberance 15 emerges from the end of the second body 13 to mechanically couple to the concave seat 14 of the corresponding end of the first body 12, in order to provide certain lateral mobility to the load cell 11 and, consequently, prevent alignment errors or misalignment or lurching in the load cell 11, thereby preventing the transmission of wedging stresses.

[0025] In relation to FIG. 3, the male-female ball-and-socket joint may be of the radial ball-and-socket type; of the angular contact ball-and-socket joint type, wherein the sliding surfaces are inclined at an angle with respect to the axis of the ball-and-socket joint; of the axial ball-and-socket joint type, having a spherical surface in the protuberance 15 and a hollow and equally spherical surface on the seat 14; or similar.

[0026] The load cell 11 as a whole has a parallelepiped or elongated cylinder shape, and is made of a material with high mechanical resistance.

[0027] The load cell 11 is capable of detecting the deformation caused by a compression force exerted thereon and generating, in accordance with said force, a signal that may be transmitted to a data control and processing centre, which includes a data processing unit, to provide a value equivalent to the force detected.

[0028] Therefore, the load cell 11 constantly measures the force of the tension in the cable in a direct manner, making it possible to precisely regulate and control said tension, while also indicating the behaviour of the supporting cable tie when the load cell 11 is located on the cable tie itself.

[0029] In the case of ties that include a damper spring, as is usually the case of supporting cable ties of lifting devices, the load cell 11 can be placed between the spring whereon the supporting cable is supported and the support structure, such that the tensile strength of the cable is applied to the spring and the spring transmits it to the load cell 11.

[0030] The configuration of the load cell 11 enables much higher resistance than other types of cells at considerable loads. This is due to the geometry itself and to the fact that the load cell 11 has certain lateral mobility to prevent the wedging stresses, misalignments or lurches that may cause overloads and material fatigue. This fatigue can cause the cell 11 to break, which is particularly dangerous.

[0031] An overload may give rise to deformations in the load cell 11 and, consequently, erroneous load measurements. The selection of materials with high resistance and the aforementioned geometry for manufacturing the load cell minimises this risk.