SE506592C2 - Power simulator for testing overload devices of lifting devices - Google Patents

Abstract

For testing of load-limiting means in lifting devices (2), use is made of a load simulator, which has a loading device (1, 5) and a load-sensing device (4) for indicating the applied force. According to the invention, the loading device (1, 5) comprises a force-absorbing spacing device (1) and a pulling device (5). The spacing device serves as abutment between the pulling device and the girder arrangement (6) of the lifting device (2) and therefore is at one end connectible to the girder arrangement and at the other end connected to one end of the pulling device (5). The other end of the pulling device (5) is in turn designed to be connected to the lifting means (3) of the lifting device (2).

Description

z 5 Û 6 5 9 2 The standard test shown thus requires weights which must be handled and stored. In the device and method according to the mentioned Swedish patent, a disassembly of the overload device and testing of it at a separate test site is required.

An object of the present invention is to eliminate or at least considerably reduce these problems. An object of the invention is to provide a test device which can be used for your different types of lifting devices and is not connected to a lifting device with a given load capacity.

Disclosure of the Invention These and other objects of the invention are solved by means of a force simulator, which is designed as stated in claim 1.

The subclaims state particularly preferred embodiments of the invention.

In summary, for testing overloaders of lifting devices, a force simulator having a load device and a force meter for indicating applied force must be used. According to the invention, the loading device comprises partly a force-absorbing spacer device and partly a traction device.

The spacer device serves as an abutment between the towing device and the beam arrangement of the lifting device and is therefore at one end connectable to the beam arrangement and at the other end and at the other end connected to one end of the towing device. The other end of the towing device is in turn designed for connection to the lifting device of the lifting device.

A great advantage of the invention is that the force simulator can be used for testing many different lifting devices of different lifting capacity. Another advantage is that you no longer need to use separate weights and weights, which need to be handled in connection with the test process and then stored during the time between the following annual inspection sessions. A further advantage is that the device constitutes a complete test device, which contains towing devices, abutments and force meters for connection to the beam arrangement or ordinary lifting device of the lifting device subjected to testing. No actual intervention in the lifting device is required, and in addition the use of the test device or power simulator will result in a test not only of the overloader but also its connection and normal function in the lifting device. A further advantage of the invention is that the ordinary sensor of the overloader can also be controlled in a simple manner by a comparison between the measured value from the sensor of the power simulator and the measured value from the ordinary sensor of the overloader. It is therefore also easy to check the linearity of the overloader.

Because the force simulator according to the invention is a complete unit, which with simple measures is connected to the beam arrangement of the lifting device and its ordinary lifting device, no disengagement of the overloading device is required. For the same reason, the lifting device can be tested without any intervention.

An advantage of the invention is thus that the force simulator can be applied to the lifting device in a simple manner. The invention makes it possible to test overloaders in a simple and rational way, regardless of the type and function of the overloader. The test becomes significantly easier than known test methods, when the overloader is dismantled or when weights or fixed points in the floor are used to achieve the load.

Brief Description of the Drawings Fig. 1 shows a side view of an example of a force simulator, which is designed according to the present invention and is connected to a beam arrangement and ordinary lifting means of a lifting device.

Fig. 2 shows the force simulator and the lifting device in side view from the left with respect to fi g 1.

Fig. 3 shows the power simulator itself in perspective.

Description of Preferred Embodiments Figures 1-3 show a preferred embodiment of the force simulator in two side views and a perspective view. In this preferred embodiment, a spacer (1) or abutment is designed as a truncated pyramid, the corners of which are constituted by compressive-absorbing oblique struts (7).

These are inclined outwards from an end plate (8) and extend to an annular mounting end (9). This mounting is also intended to be connected in a suitable manner to the beam arrangement (6) of the lifting device (2) to be tested. The mounting flange (9) also constitutes a tensile absorbing element, which holds together the ends of the oblique struts (7) and prevents them from moving away from each other when using the force simulator. The end plate (8) at the narrow end of the spacer device forms a bracket for a towing device (5), which in this case consists of a pneumatic or hydraulic piston and cylinder assembly, the other end of which is intended to be connected to the lifting device (1/5 0 6 5 9 2). 2) ordinary lifting gear (3). The piston and cylinder unit are connected in the usual way to a compressed air or hydraulic pump via lines not shown in more detail. To check the pressure in the piston and cylinder assembly, there is a manometer, which in this case serves as a force gauge (4) for checking the applied load.

Within the scope of the invention, the spacer device (1) can also be designed in other ways. One possibility is to design it as a cone, a cylinder or a beam, taking into account that the function of the spacer device (1) is to absorb compressive forces which arise during the tensile load of the lifting device (5) by the traction device (5). In the example shown, the traction device (5) has been designed as a piston and cylinder assembly, but other traction devices can also be used, for example a rope winch or other traction device to provide traction in the lifting arrangement (10) of the lifting device (2) and thus testing the lifting device ( 2) overloaders. Within the scope of the invention, other force meters (4) can also be used instead of a manometer. Thus, one can use a load cell between the line arrangement (10) of the lifting device (2) and the traction device (5) or use a load cell between the spacer device (1) and the traction device (5). The above-mentioned annular mounting shaft (9) can also be replaced, for example with straps or struts which are attached a bit down to the struts (7) of the spacer device (1) and thus interconnect them to achieve the same function as mentioned above.

Claims (8)

S ~ 5 Ü 6 5 § 2 PATENTKRAV Force simulator for use in testing overloaders of lifting devices (2), comprising a load device (1, 5) and a force meter (4) for indicating applied force, characterized in that the load device (1, 5) comprises partly a force-receiving spacer device (1), and a traction device (5), that the spacer device (1) is designed at one end for power transmission to be connected to beam arrangements (6) included in the lifting device (2) and at the other end to be connected to one of the traction device (5) end, that the other end of the traction device (5) is designed for connection to the lifting device (3) of the lifting device (2). Power simulator according to claim 1, characterized in that the force-receiving spacer device (1) has pressure-absorbing support legs (7) which are inclined outwards in the direction from the end of the spacer device (1) which is connected to the traction device (5). Power simulator according to Claim 1 or 2, characterized in that the traction device (5) comprises one or more hydraulic or pneumatic piston and cylinder assemblies. Power simulator according to claim 1 or 2, characterized in that the traction device (5) comprises a rope winch with traction device for connection to the lifting device (3) of the lifting device (2). Power simulator according to one of Claims 1 to 4, characterized in that the force meter (4) comprises a load cell between the traction device (5) and the spacer device (1). 6. Power simulator according to claim 3, characterized in that the force meter (4) comprises a manometer in the pressure line of the piston and cylinder unit. Power simulator according to Claim 4, characterized in that the force meter (4) comprises a sensor inserted between the traction device (5) and the lifting device (3) of the lifting device (2). Power simulator according to one of Claims 1 to 4, characterized in that the force meter (4) comprises a load cell (6) inserted between the lifting device (2) and the spacer device (1).