DE9016362U1 - Measuring device for measuring the relative casing deviations of helical compression springs or other objects - Google Patents

Description

Marc Andreas Wiedenhöfer Wiesentalstrasse 60

7056 Weinstadt Schnait

Description :

Measuring device for measuring the relative sheath deviations of helical compression springs and/or other objects.

The innovation relates to a measuring device for measuring the relative casing deviations of helical compression springs and/or other objects that can be placed on the measuring plate against the stop surface of the shaft.

Angle rulers or measuring angles and feeler gauges are often used to measure the relative sheath deviations of helical compression springs and/or other objects. For example, certain helical compression springs or parts must be manufactured within a specified tolerance with regard to the sheath deviation and must not exceed this. To determine these deviations, the parts to be measured are placed on the measuring angle or measuring ruler and rotated until the helical compression spring or the object to be measured still rests against the measuring angle or angle ruler at the bottom, but the optically largest possible sheath deviation is reached in the upper area.

This maximum distance between the angle and the object to be tested is now determined using the feeler gauge by guiding the gauge's steel tongues of different thicknesses between the angle and the object. Starting with the smallest thickness, the larger one is selected until no light gap is visible between the angle/gauge and the gauge/object.

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It requires a certain amount of experience to visually find the maximum distance between the angle and the object to be measured, as well as to avoid tilting or shifting the object to be tested by the measuring tongues of the feeler gauge.

The innovation is based on the task of developing a measuring device for determining the casing deviation in helical compression springs or other objects that requires less effort, is easier to handle and has greater measurement accuracy.

The task is solved in accordance with the innovation in that the shaft and the measuring plate adjustable on it belong to a signaling circuit that is closed over the object to be tested and the probe screw.

On such a measuring device, the object to be tested is first placed on the measuring plate and then adjusted so that the upper edge of the object to be measured is in the lower third of the probe screw, which is in the struck state.

The dial gauge clamped behind it under pre-tension, which is insulated from the probe screw by a plastic screw, is now set to zero. This process is not necessary in the subsequent measurements, as the dial gauge can no longer be adjusted and returns to the zero position every time it hits the insulating sleeve in the shaft.

The object to be measured is now placed on the stop surface of the shaft and rotated until the largest optically detectable distance between the probe screw and the object is reached

The touch screw is now unscrewed using the knurled nut until it comes into contact with the object, the detection circuit is closed and a current can flow through which a

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optical and/or acoustic signal is triggered by a corresponding sensor. The voltage source can be integrated into the angle or arranged externally.

In a preferred embodiment, a hole is provided in the shaft below the touch screw, offset by 90 degrees to the left, into which an indicator light is inserted.

The indicator light is preferably a luminescent diode. The optical signaling device is integrated into the bracket in this design. A unit is therefore formed that is easy to handle.

A light-emitting diode has small dimensions and low power consumption. The effort required to create the mounting hole and install the light-emitting diode is therefore low.

In addition, a battery cell can be used as an energy source for the alarm device or alarm circuit, which only discharges after a long time even if the measuring device is used frequently

The shaft is secured by a worm screw in a hole in the base and can be easily removed by loosening the worm screw, e.g. to change the battery cell.

In a particularly useful embodiment, the shaft contains a recess in which a battery cell is arranged. The battery cell as an energy source for the signaling circuit is located inside the shaft so that the external shape of the measuring device is not affected. The handling of the measuring device is thereby improved. The battery cell can preferably have one or more cylindrical

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Contain cells that are arranged in series in a hole that runs inside the shaft.

The cells are fixed in their position and connected to one another via their electrodes by a helical compression spring with a pressure head that extends over the locking screw into the bore.

In another advantageous embodiment, a plastic holder is fitted in the recess between the battery cell and the hole that leads to the touch screw, in which a contact is made between the batteries and the touch screw via the screw, the helical compression spring, the LED, the second helical compression spring and the brass bolt. If there is contact between the touch screw and the measuring plate or the shaft via a conductive object, the LED lights up.

Further details, features and advantages of the innovation are apparent from the following description of an exemplary embodiment shown in the drawing.

Show it:

Fig. 1 A measuring device for measuring the relative casing deviations of helical compression springs and/or other objects in perspective view.

Fig. 2 The measuring device according to Fig. 1 in side view, partly in section.

Fig. 3 The measuring device according to Fig. 1 and Fig. 2 in front view, partly in section.

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Fig. 4 The measuring device according to the previous drawings in rear view, partly in section.

Fig. 5 The measuring device according to the previous drawings in a schematic view with the circuit of a signaling circuit.

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A measuring device in which the shaft (5), the stop surface (26) located on it and the measuring plate (4) form a right angle stands out, as can be seen from Fig. 1 to Fig. 4, in that:

The shaft (5) is clamped in the vertical hole (28) in the base (19) by a worm screw (18). The shaft (5) contains a cylindrical recess (25) which runs in the form of a hole in the interior in the longitudinal direction. The recess (25) is open on one side. The diameter of the recess (25) is adapted to the diameter of the battery cells (20). The length of the recess (25) is intended, for example, for two battery cells (20) which are inserted one behind the other into the recess. The part of the recess (25) adjacent to the opening has an internal thread which is intended to accommodate the screw plug (17). The screw plug (17) is made of a conductive material. A helical compression spring (16) is arranged above the screw plug (17), one end of which rests on the screw plug (17), while a pressure head (15) is attached to the other end of the helical compression spring (16). When screwed in, the pressure head (15) is pressed against one of the electrodes of the battery cell (20) under the tension of the helical compression spring (16) so that a current can flow via the above-mentioned parts to the shaft (5) and the measuring plate (4) clamped to it.

In the upper part of the shaft (5), the recess (25) opens into a smaller (30) hole in the insulating sleeve (2). In the upper part of the recess (25) there is a plastic holder (9) between the battery (20) and the touch screw (1). In this there is a hole (32) which has a cross hole (33) in which one of the contact legs of the LED (24) is clamped by a helical compression spring (7). The helical compression spring (7) is put under tension by the screw (0) in order to ensure optimal clamping of the contact leg of the LED (24).

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The screw (10) is in contact with the upper electrode of the battery cell (20). In the upper area of the plastic holder (9) there is a second hole (31) which has a cross hole (34) into which the second contact leg of the light-emitting diode (24) is clamped by the helical compression spring (6). There is a brass bolt (8) on the helical compression spring (6). The brass bolt (8) is pressed onto the thread of the probe screw (l) by the helical compression spring (6).

From the battery cell (20) via the screw (10), the helical compression spring (7), the LED (24), the helical compression spring (6), the brass bolt (8) to the probe screw (l) and the knurled nut (21) clamped onto it, an electrical circuit is created that is insulated from the rest of the measuring device by the insulating sleeve (2) and the plastic holder (9).

The circuit is only closed when contact is made between the probe screw (1) and the shaft (5) or measuring plate (4) via a conductive object; the LED (24) lights up.

The light-emitting diode (24) is visibly mounted in the shaft (5).

The light-emitting diode (24) is fixed in the bore (29) in the shaft (5) by a clamping ring (27).

From Fig. 5 it can be seen that the negative pole of the battery cell (20) is connected to the shaft (5) or the measuring plate (4), while the positive pole of the battery cell (20) is connected to the stripped probe screw (1) via the light-emitting diode (24). It is assumed that the sheath deviation is to be measured on an object not shown, for example on a helical compression spring.

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The probe screw (1) is returned to its stop position in the shaft (5) using the knurled nut (21). In the angle (22) secured in the shaft (5) by the screw (23), a dial gauge is secured in the holder (12) provided for it under pre-tension using the clamping screw (11) and set to zero. The probe pin of the dial gauge is electrically insulated from the rear end of the probe screw (1) by the plastic screw (3) so that no electrical circuit can be created via the shaft (5), the angle (22) secured in it and the dial gauge to the probe screw. The helical compression spring is placed on the measuring plate (4) and placed on the stop surface (26) of the shaft (5). The tilt clamp lever (13) is opened and the measuring plate is moved until the upper edge of the helical compression spring is in the lower third of the probe screw (1). The tilt clamp lever (13) is then tightened again and presses a brass bolt (14) against the shaft (5) in order to avoid damaging it when clamping.

The helical compression spring is now rotated on the stop surface (26) of the shaft (5) until the largest optically detectable distance between the upper edge of the helical compression spring and the feeler screw (1) is reached.

The touch screw (1) is now unscrewed using the knurled nut (21) until it comes into contact with the helical compression spring, thus closing the circuit.

This circuit contains the battery (20), the light-emitting diode (24), the probe screw (1) and the shaft (5) or the measuring plate (4).

A current flows in the circuit, causing the LED (24) to light up.

The lighting of the LED (24) signals to the operator that the probe screw (1) is in contact with the helical compression spring and that the maximum sheath deviation can be read on the dial gauge.

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The luminescent diode (24) lights up even at a slight
Contact of the probe screw (1) with the helical compression spring on

With the measuring device described above, the casing deviations of helical compression springs and other objects can be measured more quickly and accurately than with the methods commonly used up to now.

Another advantage of the above described, by using
With a digital dial gauge with data output, the determined values can be forwarded to data processing devices to be stored and further processed, for example as a statistical printout.

Claims (14)

Marc Andreas Wiedenhöfer Wiesentals tr.60 Weinstadt-Schnait Protection claims 1. Measuring device for measuring the relative casing deviations of helical compression springs and/or other objects, characterized in that the helical compression springs or objects resting on the measuring plate (4) are placed on the stop surface (26) of the shaft (5) so that the upper edge of the helical compression spring or object is in the lower third of the insulated probe screw (1). The helical compression spring or object is rotated on the measuring plate (4) until the greatest distance between the probe screw (1) and casing surface is reached in the upper area of the object to be tested. Unscrew the probe screw (1) using the knurled nut (21) until the probe screw (1) rests against the helical compression spring or the object, the circuit is closed and the LED (24) lights up. The measured value is read from the dial gauge which is attached under pre-tension in the angle (22) with the clamping screw (11) and which is insulated from the probe screw (1) by the plastic screw (3). 2. Measuring device according to claim 1.
characterized in that the measuring plate (4) is continuously adjustable and lockable in the vertical direction by means of the tilting clamping lever (13) and the brass bolt (14) which protects the shaft from damage when locking. -2- 3. Measuring device according to claim 1 or 2, characterized in that the recess (25) for the batteries (20) can be closed by a locking screw (17) with a helical compression spring (16) projecting into the recess, which has a pressure head (15). 4. Measuring device according to one of the preceding claims , characterized in that the indicator light is a luminescence diode (24). Measuring device according to one of the preceding claims , characterized in that the recess (25) is a cylindrical bore which runs vertically in the shaft (5). Measuring device according to one of the preceding claims , characterized in that in the angle (22) which is made in a groove in the shaft (5) by the fastening screw (23). A dial gauge can be fastened in the holder (12) by means of the clamping screw (11). 7. Measuring device according to one of the preceding claims , characterized in that the dial gauge is insulated from the probe screw (1) by a plastic screw (3) and the probe screw (1) and the dial gauge are adjustable by the knurled nut (21). 8. Measuring device according to one of the preceding claims , characterized in that the shaft (5) is fastened by the worm screw (18) in the bore (28) which is made in the base (19). -3- 9. Measuring device according to one of the preceding claims , characterized in that the probe screw (1) uses the insulating sleeve (2) as a stop and is flat with the stop surface (26) in the stopped state. 10. Measuring device according to one of the preceding claims , characterized in that the probe screw (1) is insulated from the shaft (5) by a plastic bushing (2). 11. Measuring device according to one of the preceding claims , characterized in that the luminescence diode (24) is clamped in the plastic holder (9) by the helical compression springs (6), (7). 12. Measuring device according to one of the preceding claims , characterized in that the brass bolt (8) is pressed against the probe screw (1) by the helical compression spring (6) in the plastic holder (9), and is in contact with the batteries (20) via the light-emitting diode (24), the helical compression spring (7) and the screw (10) which are located in the plastic holder (9). 13. Measuring device according to one of the preceding claims characterized in that in the shaft (5) the bore (29), which is offset by 90 degrees to the left under the touch screw (1), is provided for receiving a light-emitting diode which is fastened with the clamping disk (27). 14. Angle according to one of the preceding claims, characterized in that the negative pole of the power supply is set to earth and that the measuring plate (4) has contact with earth via the shaft (5), the locking screw (17), the helical compression spring (16) and the pressure head (15).