The present invention relates to equipment for determining the load in a lift cage of a lift, wherein at least one load sensor is provided in at least one support of parts that are acted on by vibration and that are supported on at least one damping body, which is carried by a bearer for vibration damping of the parts, acted upon by vibration relative to the bearer.
Equipment for measuring the load in a lift cage of a lift has become known from U.S. Pat. No. 6,305,503 B1, which depicts a variety of measurement methods. A drive unit driving the lift cage is supported on resilient bearings. In an illustrative embodiment, a potentiometer producing a measurable voltage in dependence on the deformation of the bearing is arranged at one of the bearings. The force acting on the bearings is made up of the cage weight, the cage load, the weight of the counterweight, the weight of the support means and the weight of the drive unit. A load change is measurable at the resilient bearings as a change in voltage.
An object of the present invention is to provide an efficient system for determination of the load in a lift cage of a lift, which can be retrofit into existing lift equipment.
An advantage achieved by the invention is that, in comparison with conventional load measuring equipment, an economic solution for determination of the load in a lift cage can be realized. Moreover, by use of a small-area load sensor as employed, the sensor can be placed in a simple manner in the support for parts that are acted on by vibration, for example, between a support bracket and insulating bodies for vibration damping of a drive engine, a lift cage, a support means fixing point or deflecting rollers. It is additionally advantageous that, in the case of a subsequent installation of the load measuring equipment according to the invention, neither changes or reconstruction of the damping devices are needed, nor are their damping characteristics changed. In the case of retrofitting the damping device only has to be raised slightly from a support bracket and the load sensor, placed in the gap which forms.
In accordance with the foregoing, at least one load sensor is provided in at least one support for parts that are acted on by vibration and which are supported by at least one damping body—which is carried by a bearer—for vibration damping of the parts which are acted on by vibration relative to a bearer, wherein the load sensor can be mounted between the bearer and the damping body without constructional changes to the bearer or of the damping body.
The invention is explained in more detail in the following detailed disclosure of a preferred but nonetheless illustrative embodiment of the invention, taken in association with the accompanying figures, in which:
A second damping body 13 is provided below the bracket 6 and together with the first damping body 12 is pressed against the bracket 6 by means of a screw 14 with a hexagonal head 14.1 and a washer 15, which is threaded into the engine foot 5. A spacer sleeve 16 bearing against the engine foot 5 limits the pressing of the first damping body 12 and the second damping body 13. The drive engine 1 is fixed on the bracket 6 by the pressing of the damping bodies 12, 13, but the drive engine 1 remains insulated in terms of vibration relative to the bracket 6. The first damping body 12 can alternatively also consist of several parts.
The above calculation is based on a load sensor 11 with a diameter of 9.5 mm and a thickness of approximately 0.2 mm in the measuring region illustrated as a circle. With a thickness of merely 0.2 mm the load sensor 11 can be retrofitted in a simple manner in existing lift installations. For this purpose the screw 14 is loosened and the drive engine 1 slightly raised until a small gap forms between the bracket 6 and the first damping body 12. Thereafter the load sensor 11 can be pushed into the gap without constructional change of the bracket 6 or of the damping body 12, the drive engine 1 lowered and the screw 14 retightened.
Provided at the upper end of each tie rod 20 is a threaded portion 23 by means of which, together with an installed nut 24, the exact position of the respective support means is settable. The nut is secured by means of a locknut 25. Each nut 24 is carried by the cover plate 26, which in turn rests on the first damping body 12. The tie rods 20 penetrate the first damping body 12 and the cover plate 26.
The small-area load sensor 11 can also be placed in the region of other parts that are acted on by vibration of the lift equipment, for example, between a support bracket and insulating bodies for vibration damping of the lift cage or deflecting roller. Alternatively, more than one load sensor 11 can also be used in a support 10 or at least one load sensor 11 can be provided in more than one support 10.
Damping bodies 12 of greater resistance are usually used for supports 10 of the lift cage than for supports 10 of the drive engine 1. In that case the load sensor 11 can also have a thickness of approximately 1 mm or less. The area ratio of the area of the load sensor 11 in the measuring region to the effective area of the damping body 12 can also be approximately 1:10, or less.
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