DE29703041U1 - Highly accurate electronic angle measuring device - Google Patents

Description

Description

High-precision electronic angle measuring device

Angle measuring devices of a similar design have a potentiometer or a stroboscope disk as a measuring sensor. Patent application 11 29/90 at the Austrian Patent Office works with the same precision, but two computers must be installed to produce the electronic circuit. This angle measuring device is equipped with a binary counter and can be used together with a pocket calculator.

The invention specified in claim 1 is based on the problem of creating an angle measuring device that displays two binary frequency values. One for the full circle and one for the partial section of the angle to be measured. The binary numerical values are called up by touching the sensor buttons, noted on a list and converted into decimal numbers.

The smaller number is divided by the larger number, resulting in a number equal to or less than one. This number is multiplied by the number 400, resulting in the value of the angle to be measured in Gom (gradients).

The invention makes it possible to determine an angle with high precision, up to seven decimal places, in conjunction with a pocket calculator.

An advantageous embodiment of the invention is achieved by using a stepper motor to drive the gear and measuring discs. The rotational speed of the measuring discs is thus stabilized.

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An embodiment of the invention is explained using Figures 1 to 7. They show:

Figure 1, the device in position for an angle measurement, with the housing 1 and the housing 2, which are connected so that they can rotate around the vertical axis 4. Both housings are aligned parallel to the sides of the angle when measuring the angle. The sensor buttons 3 are attached to the housing 1. When the right and middle buttons are touched, the value for the angle to be measured is displayed.

When you touch the left and middle buttons, the value for the full circle is displayed on the LEDs 5.

With 6, transparent set squares are attached to the bottom surfaces of the two housings 1 and 2.

The gear motor 7, the circuit 8 and the binary counter 9 with the readout 5 are housed in the housing 1. The batteries for the circuit 8 and the gear motor 7 are installed in the cavity 10.

The circuit 10 with the associated battery is housed in the housing 2.

Figure 2 shows the assembly of the motor and gearbox 7 in the housing 1.

Figure 3 shows the housing 2 from below with the connection to the housing 1, with the light-emitting diodes 19 and the fork light barrier 20 from the circuit 10 from Fig. 6.

The shaft 12 of the gearbox and motor 7 carry the discs 13 and 14. An additional cover is inserted with 11.

Figure 4 shows the sliding surface of housing 1 viewed from below.
The hatched circular areas 15 and 16 show the openings in the plate.
The shaft 12 runs through the openings 16. The screws 17 from Fig. 5 are screwed into the openings 15.

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The phototransistors 18 and the light-emitting diodes 19 from the circuit 10 work as optocouplers. When the disk 13 interrupts the light in the fork light barrier 20, the circuit 10 passes a signal to the phototransistors 18 via the light-emitting diodes 19.

Figure 5 shows the attachment of the upper plate of housing 2 to the lower plate of housing 1.

The steel ring 21 protects against abrasion. The screws 17 with the ball bearings 22 and the washers 23, screwed into the openings 15 via the steel ring 21, create a bearing-mounted, rotatable connection between housing 1 and housing 2.

In Figure 6, the fork coupler24 gives a signal when the disk interrupts the light on the phototransistor and is re-illuminated.

The falling edge sets the R-S flip-flop 28 and the dual flip-flop 29 via the NAND gate 25, the differentiating element 26 and the transistor 27. When the shaft 12 continues to rotate and the disk 13 releases the light in the fork coupler 20 onto the phototransistor, the phototransistors 18 are blocked. This positive signal at the input of the AND gate 30, via the differentiating gate 31 and the transistor 32, resets the R-S flip-flop 28. The LED 33 lights up for the time that the shaft 12 needs for the angular rotation from the fork coupler 24 to the fork coupler 20.

The shaft 12 continues to rotate and the disk 14 passes the fork coupler 24 again.

This resets the dual flip-flop 29. The LED 34 lights up for the time it takes for the shaft to rotate in a full circle.

When the sensor button 3 is touched below and in the middle, the outputs of the NAND gates 37 and 38 become positive.

This allows the signal from the flip-flop 29 to reach the input of the Nand gate 46 via the AND gate 41 and the OR gate 44. The output of the OR gate 40 is also positive, and therefore the Nand gate output 50 is also positive. The differentiator 52 generates a

positive needle pulse, and transistor 53 inverts the reset line for counter 9 in Fig. 7. The counter resets. The output of NAND gate 58 becomes positive, and the frequency from gates 47 and 48 is passed through to the output of AND gate 49. Counter 9 counts from the beginning.

If the output of R-S flip-flop 28 becomes negative, a positive state is created via the AND gate 41 and the OR gate 43 at the output of the NAND gate 45. The transistor 55 is switched through for a needle pulse via the differentiator 54.

The pulse is passed on to the memory modules 56 via the AND gate 51. The second input of the AND gate 51 is also at positive potential via the output of the OR gate 39. The memory modules 56 pass the data from the counter modules 57 on to the binary outputs A to X. The LED display 5 shows the binary frequency count for the pulse from FF 28.

When the sensor button 3 is touched at the top and in the middle, the outputs of the NAND gates 35 and 36 become positive. Via the OR gates 39 and 40, one input each of the gates 42, 46 and 51 becomes positive.

The positive signal from the dual flip-flop 29 initially resets the counter 57, and when the edge falls, the memory 56 receives the signal that passes the data to the LED display 5.

Using sensor button 3, the path is switched through once for the signal from 28 and once for the signal from 29.

The inputs of NAND gates 35 and 37 have a larger series resistance to plus than the inputs of NAND gates 36 and 38. This results in a small delay.

This small time shift blocks gates 51 and 46 against interference signals.

The frequency at the output of gate 49 is switched through like the selected signals.

In order for the counter to display zero or a small number even at a very small angle, the potentiometer in the differentiator 58 is used to switch the transistor 60 through via the NAND gate 59 until the

Reset signal occurs. Transistor 60 inverts the frequency until transistor 53 switches through and inverts. The delay via gates 41, 44, 46 and 50 is thus compensated.

The positive battery connection of circuit 8 is made via a 5 watt resistor 61 with 0.5 ohms with a potentiometer 62 connected in parallel.

The voltage is 12 volts to 15 volts.

The circuit 10 in Fig. 6 in the housing 2 causes the LEDs 19 to light up when the phototransistor in the fork light barrier 20 is not illuminated, thereby applying voltage to the base of transistor 61 and the inputs of the gates 62 to 65 become negative.

The outputs are positive, and the LEDs 19 are lit for the time when the phototransistor in 20 is not illuminated. The voltage for this circuit is 9 volts.

The gear motor 7 is connected to a 4.5 volt battery, which is housed in the housing 1. The gear motor is suppressed by the coils and capacitors connected upstream of the gear motor.

In Figure 7, the CMOS components 40 161 are used as counter components 57.

To forward the signal from Co to CLK, the signal is inverted via the NAND gates 66 to 70. The inputs CEP, CET and PE are connected positively. The parallel inputs are connected negatively. The outputs QO to Q3 are connected to the inputs of the memory modules 56.

E1 is connected to plus via a high-value resistor. EO is connected to the output of gate 51 in Fig. 6. The IC CMOS 4042 is used as the memory module.

The outputs DO to D3 in the right memory IC are connected to the LEDs A to D in the readout 5. The connection of the right counter module 57 with the right memory module 56 and the LEDs A to D applies analogously to all other modules and LEDs in Fig. 7.

The reset line of the counter modules 57 is connected to the transistor 53 in Fig. 6.

The data can be written down using a list with the letters A to X.

The adjustment is carried out by turning the discs 13 and 14 relative to each other on the shaft 12. If the housings are parallel to each other - the housing 2 is located under the housing 1, the readout 5 must show the same number with each signal.

Claims (6)

Protection claims 1. High-precision electronic angle measuring device with two measuring marks arranged in two housings, which can be rotated relative to one another about an adjustment axis and can be aligned relative to the legs of the angle to be measured, and with a measuring device for the angular distance of these measuring marks in relation to the adjustment axis, which is connected to a display for the measurement result, characterized in that two disks (13, 14) which can be driven to rotate about an angle axis (12) are provided between the two measuring marks, each of which has an optoelectronic fork coupler (20, 24), and an optoelectronic signal transmission (18, 19), that the signals are generated in two different circuits (8, 10), one of which processes the signals, that this measuring device consists of a pulse generator (47, 48) and a binary counter (57) connected to this pulse generator, whereby this binary counter (57) can be optionally controlled via the sensor button (3), which has two signal paths controls, counts the frequencies for the signal from memory (28) and memory (29) separately, and that the binary data of the counter (57) with the display (5) can be read out via the memory 56. 2. Device according to claim 1, characterized in that both fork couplers (24, 20) are arranged radially from the adjusting axis 4, and that the shaft (12) rotating in the adjusting axis (4) carries two disks (13, 14), one of which signals the longitudinal axis of the housing (1) via the fork coupler (24), and one is provided for the signal interruption of the fork coupler (20) in the rotatably adjustable housing 2 parallel to one leg of the angle to be measured. 3. Device according to claim 2, characterized in that the discs (13, 14) are designed with a tooth-shaped enlargement. 4. Device according to one of claims 1 to 3, characterized in that the signal from the R-S flip-flop (28) is compared in time with the signal from the dual flip-flop (29) via the binary counter (9). 5. Device according to claim 4, characterized in that the number of frequencies for the angle is divided by the number of frequencies for a full circle, and this number < 1 is multiplied by 400, thus giving an exact measurement in grads for the measured angle. 6. Device according to claim 1, characterized in that the path for the signals from memory (28) or memory (29) in the circuit (9) is optionally displayed on the light-emitting diodes (5) via the sensor button (3) in the circuit (8).