HU187380B - Measuring system for determining the valus of deformation - Google Patents

Abstract

Measuring device for determining deformation values with a measuring object holder and means for determining the measured value. The means for determining the measured value are arranged above the measuring object receptacle as a vertically movable unit. It consists of a quill with a vertically movable measuring pin, a transducer for detecting the measured variables by means of a measuring bolt, a loading device and suitable means for functional connection of these parts. Due to the easy-to-automate measuring process and the output of two measured values, whereby the first measured value does not have to correspond to the zero point of the measuring device, the measuring objects can be exchanged in a very short sequence, whereby high throughput rates are possible.

Description

BACKGROUND OF THE INVENTION The present invention relates to a measuring apparatus which can be used to detect deformation by detecting deformation between the preload and the after loading on a particular object to be measured, especially for eggs for hatching and consumption.

Devices for measuring deformation are known. Such a device is described, for example, in the GDR patented device (WP 93 438), in which the object to be measured is approached so much as a sensor, and the evaluation device connected to the meter detects the setting to zero. If a force is then applied to the object to be measured, the pointer moving from zero indicates the degree of deformation. The disadvantage of this equipment is that the search for the datum is very cumbersome, so that only a low level of productivity is then achieved.

Also known is a measuring device whose measuring pin is connected to a measuring sensor by means of a lever system, and this measuring pin is brought closer to the object to be measured. When a force is applied to the object to be measured, the evaluating apparatus connected to the measuring sensor is set to zero and then, under the action of a subsequent load, the deflection of the measuring device relative to the zero position indicates the deformation.

The disadvantage of this apparatus is that it is not suitable for measuring objects which are subject to greater fluctuations in size and shape, since the space to accommodate the object to be measured is limited.

It is an object of the present invention to provide a measuring apparatus for detecting deformation which is capable of providing a high level of productivity independent of greater variation in the size of the object to be measured. The apparatus according to the invention thus has the task of constructing a measuring device capable of determining deformation values which does not require a complicated search of the datum, but also automatically compensates for major fluctuations in the size of the object to be measured, without space should be limited.

According to the present invention, this object is solved by the means for determining the measurement value being arranged in a vertically movable unit above the holder of the object to be measured.

The apparatus thus consists of a peak support having a vertically movable measuring pin, a measuring pin defining the value to be measured by the measuring pin and a load-transmitting structure and means for operatively connecting these structural elements.

A braking device is integrated in the device to limit the path of the vertically movable unit and to brake this unit.

The signal is coupled to a signal transducer which converts the value obtained at the measurement and is preferably provided with a limit signal for transmitting a braking signal for stopping the unit moving in the vertical direction.

The pivot pin pin is connected directly to the pins pin or via a link rod.

According to a further embodiment, the traffic signal is mounted in the pillar instead of the pivot pin with the corresponding measuring pin.

The pivot of the tip support or the pivot of the road sign is formed with a bearing surface so that the load is resting on the object to be measured. The load can be set to a constant value or electro-motorized to change this value. Movement of the vertically movable joint assembly is provided by a gear which, according to a preferred embodiment, is a motor-driven rope pulling device.

The complete apparatus is, of course, provided with a suitable measuring stand, the base of which is provided with a holder for holding the object to be measured, and on which a height support is mounted on an adjustable support arm.

The moving object is approached to the object on the bracket by a motor drive until the measuring pin guided in the peak bracket contacts the object to be measured and the measuring pin on the road sign moves. The output voltage of the transducer is then increased, which, when a predetermined limit is reached, outputs a control signal, which is used to actuate the braking mechanism. After braking, the output voltage generated by the transducer corresponds to the first measurement value, while the object to be measured is subjected to a preload corresponding to the combined effect of the weight of the measuring pin and the measuring force transmitted by the traffic signal.

Then, through the load-transmitting structure, a force corresponding to the specific load-bearing capacity of the object is applied to the measuring pin contacting the object to be measured or to the pin of the peak support, thereby determining the deformation of the object to be measured. The distance traveled by the peak support is detected by the traffic signal and a second measurement value is generated in the transducer. The measuring apparatus is then moved to its initial position. The difference between the first and second readings corresponds to the deformation of the object to be measured, taking into account the change in load.

The advantage of the measuring device according to the invention is that on the one hand the two measurement values - where the first measurement value does not have to correspond to the zero point of the measuring device and on the other hand due to the automation of the measuring process. Items to be measured can be quickly replaced and thus achieve high productivity with the equipment.

The coarse adjustment allows you to select the objects you want to measure in a quantity that corresponds to a specific measurable mean value, while allowing the object to be weighed within a series to be measured, even with a centimeter travel, even within centimeters. .

Measurement value after analog to digital conversion

187,380 may be stored in a suitable storage for further processing.

The route indicator output signals of the evaluation of, load conditions - when the load is an intermediary device in the lower position, and the load is increasing MER- bowling ⁵ - tests for breaking strength of the measured objects may be performed.

This work can also be carried out when the load on intermediary device is operated electronically, such as by moving a weight to the system ¹⁰ emeltyűs instrument. The invention will be described in more detail by way of an exemplary embodiment, with reference to the accompanying drawings.

In the drawings it is

Figure 1 is a side view of the measuring apparatus mutat- ¹⁵ ja, the

Fig. 2 is a front view of the top of the measuring apparatus, a

Figure 3 illustrates the clamping assembly of the peak support. ²⁰

The measuring apparatus (Fig. 1) is mounted on a weighing stand consisting of a pedestal 1, a column 2 mounted on the pedestal and a support arm 7 with a handwheel 3 mounted on the column 2. On the pedestal 1 there is provided a pond 12 for securing and positioning the anvil 14 and the object 11 to be measured. The holder 12 rests on a spring 13. The support arm 7 is provided with a clamping sleeve 8, into which a peak support 9 with a measuring pin 10 fits. Attached to the support arm 7 is a housing 4, ^{30 of} which extends 5 levers. The lever 5 is assembled with a clamping screw 6.

In the housing 4, the elements of the measuring apparatus shown in Figures 2 and 3 are arranged. On the support arm 7 (Fig. 2) is placed a base plate 15 whose support frame 16 serves to hold various structural elements.

A table 17 is connected to the peak support 9, which is connected to a roller 20 driven by a band 19 through a guide roller 18.

On the table 17, a tensioning device 21 is provided which receives a sign 23 and a lever 25 of the load transfer device. The 25 raised. 26 weights are movably disposed.

The table 17 also has 27 eccentrics.

Figure 3 shows a detail of a clamping device for the peak support 9 (not shown). The lever screw 5 is connected to the clamping screw 6, which is actuated by a magnet 28.

The equipment works as follows:

During the vertical downward movement of the table 17 connected to the peak support 9, the belt 19 is rolled out of the motor-driven roller 20.

The band 19 is guided by the guide rollers 18. A prerequisite for the displacement of the peak support is that the magnet 28, previously known, releases the clamping device known per se.

The tip support 9 moves downward until the pin 10 touches the object 11 to be measured. This contact is transmitted by the measuring pin 10 to the sign 23 via a specially designed upper part 24 via a measuring pin 22. When the plunger 22 is lowered into the signal 23, the magnet 29 is actuated, the tip support 9 is immediately stopped, and by turning off the drive mechanism of the roller 20, the belt 19 is no longer rolled over. When the tip support 9 is stopped, the measurement value generated in the sign 23 is stored as the first measurement value. With the help of the electromotor-driven eccentric 27, the weight 26 is then placed by the lever 25 on the support wedge of the upper part 24. Thereby, a force is applied to the object 11 to be measured, which results in the second measurement value being displayed in the sign 23. The difference between the first and second measured values corresponds to the deformation value. The clamping sleeve 8 receiving the tip support 9 brakes the tip support 9 by deformation. The deformation occurs by the magnet 29 forcing the clamping screw 6 to rotate by means of the lever 5.

Claims (5)

Patent claims A measuring apparatus for determining the value of deformation, which is mounted on a pedestal and is located above the support; provided with means for determining the measurement value, namely, a vertically movable measuring pin, a road sign, an additional measuring pin and a load transfer device, characterized in that the measuring value measuring means are movable vertically connected to a peak support (9) for arresting, a braking device is provided with a magnet (29) and connected to a signal transducer (23). Measuring device according to Claim 1, characterized in that a road mark (23) is provided in the peak support (9) with a measuring pin (22). Measuring device according to claim 1 or 2, characterized in that the common structural unit is connected to a motor-driven rope pulling device. 4. A measuring device according to any one of the preceding claims, characterized in that the load transmitting device is adapted to continuously increase the load to a specified value. 5. Measuring device according to one of Claims 1 to 3, characterized in that the measuring support is provided with a support arm (7) for receiving the peak support (9), which comprises a pedestal (1), a column (2) on the pedestal (1) and a handwheel ), wherein a support (12) is arranged on the pedestal (1) for accommodating the object (11) to be measured.