DEM0016796MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: December 24, 1952. Advertised on March 22, 1956

GERMAN PATENT OFFICE

The invention relates to a device for measuring irregular surfaces, in particular leather, hides and the like, according to the strip summing method, in which the area to be measured is measured by scanning devices, which generally consist of a large number of measuring wheels lying next to one another, into one proportional to it Number of current pulses resolved and the area measure is determined as the sum of the current pulses.

Such measuring devices are already known in which the size of the obtained by scanning Current impulses limited by a unit capacitor and the one representing the area measure sought Sum of the current pulses is determined by measuring the total charge of summing capacitors, which are charged by the current pulses generated during scanning. The counting is done in such a way that that the unit capacitors each have a certain number of impulses on summation capacitors transferred, which in turn cause thyratrons to ignite and thereby electromechanical Operate counters.

There are also surface measuring machines known in which during the scanning of the material to be measured electrical voltage pulses are generated in a contactless way and the number of these pulses by means of Counting devices is registered. Here, the voltage pulses are either directly or after the previous one Reinforcement and circumcision initiated in counting devices equipped with reduction stages are. The voltage pulses can also be generated capacitively by touching each other passing platelets each time for a short time

509 698/148

M 16796IX / 42 c

a capacitor is formed, which influences the grid of an electron tube and converts the fluctuations in capacitance into voltage pulses, the then get to the count. The generated pulse is emitted again immediately. Finally are Arrangements for counting pulses become known in which the current pulses for charging of a capacitor and their number can be determined by measuring the capacitor voltage will. These arrangements are practically a breaker of those known from atomic physics Type and are designed to count those impulses that come from a single generator, whereby these impulses do not fall below a certain minimum time interval in their succession may.

All of these known devices for area measurement only work properly if it is ensured that the scanning devices never two or more impulses are given to the counter at the same time, because several coincident times Impulses have the same effect on the counters as a single impulse. For the Scanning process absolutely necessary free mobility of the individual measuring wheels can this condition not or at most for the beginning of the measurement. During the passage of the material to be measured However, there is no way to influence the contact sequence, because the throughput speed of the material to be measured under the individual measuring wheels fluctuates in a completely indefinite way, because the work piece depending on its shape by the operator at one point or another must be held for a short time in order to smooth out wrinkled corners or flanks when entering the machine. A permanent mutual alignment of the scanning elements in order to ensure the temporal Successive current pulses are therefore not possible, and the coincidence of several current pulses cannot be avoided.

In order to correctly detect all sampling pulses in the count, according to the invention for Counting does not use the current pulses themselves, but each scanning device is a separate one Unit capacitor assigned, and these unit capacitors give their measuring charge according to the measure of the sampling pulses independently of one another to a common summing capacitor, whose Capacity a multiple of the product of the capacity of a unit capacitor and the maximum possible number of charges of the unit capacitors taking place during a measurement process. is. This device of the invention provides the essential advantage over the known arrangements achieves that it does not require a chronological sequence of the individual measuring pulses, but rather delivers the correct total value even when several measuring pulses coincide exactly.

According to further features of the invention, the voltage on the is directly used as a measure for the scanned area Summing capacitor used and one out of three during the measurement by each scanning device Contact springs of the existing changeover contact operated, the associated unit capacitor in the Starting position for charging with a direct current source and in the measuring position for delivery of his Charge briefly connects to the common summation capacitor.

Although it is known in electrical counting technology, a capacitor of low capacitance through a to alternately charge the changeover switch controlled by the measuring process from a direct current source and into a .summing capacitor of larger capacity and the measured on the summing capacitor To use voltage directly as a measure for the measured quantity sought. But also with this well-known Arrangement, it is only about the transmission of temporally consecutive pulses from one Single capacitor on a cumulative capacitor with subsequent registration.

In order to explain the invention in more detail, an exemplary embodiment of the same is given below of the drawings are described without being limited to this example.

Fig. Ι shows the device according to the invention in non-measuring state;

Fig. 2 shows the same device in the measuring state.

At the measuring point, the material to be measured 2 arrives in the usual manner between a driven platen 1 and the measuring wheels carried along by it by surface friction 3.

Each individual measuring wheel is a separate holder 4 assigned, which is mounted on the continuous axis 29. The lower arm of this bracket 4 carries a rocker arm 7 rotatably arranged around point 6, the lower part of which is designed as a nose 8. Furthermore, a changeover contact attached to the measuring wheel axle 5 is provided for each measuring wheel, its individual contact springs 9, 10, 11 against each other and are isolated from ground and its switching by short-circuiting two of the contact springs 9, 10 or 9, 11 isolated by means of the on the rocker arm 7 attached contact sheet 30 takes place.

The contact spring 9 is via a line 13 to one pole of a capacitor 14 for each measuring wheel of relatively small capacitance (unit capacitor) connected, while the second pole the same via a line 15 with the negative pole of a direct current source 16 is in connection. the The positive pole of the direct current source 16 is connected to the contact spring 11 of the changeover contact via a line 17 connected, while the contact spring 10 via a line 18 to one pole of all measuring wheels common summation capacitor 19 is connected, which has a relatively high capacity and its second pole through the line 20 with the negative pole of the direct current source 16 in connection stands. A voltmeter 23 is connected in parallel to the summation capacitor 19 via lines 21 and 22. The connection points of the three springs 9, 10, 11 of the changeover contact are on the distribution lines 24, 25, 26, so that the contact spring 9 with the distributor line 24, the contact spring 10 with the distributor line 25 and the contact spring 11 is connected to the distributor line 26.

698/148

M 16796IX / 42c

The changeover contact springs 9, ίο, ΐΐ of all measuring wheels are attached to the three distribution lines 24, 25, 26 connected in parallel. The number of scanners and sets of contacts depends on the largest Working width of the machine.

In the non-measuring state, pins 27 run in grooves 28 of the platen 1 without them doing the Touch rocker arm 7. In this position, the contact springs 9, 11 are closed, and the unit capacitor 14 is from the power source 16 via the line 17, the contact springs 11 and 9 and the Lines 13 and 15 charged.

In the measuring state, the measuring wheel 3 swings once by the amount of the thickness of the material to be measured around the pivot point 29 upwards, and on the other hand the pins 27 are pressed upwards at the scanning point, see above that they pivot the rocker arm 7 when running against the nose 8, which thereby changes the contact position from 9.11 to 9.10. In the contact position 9, 10, the unit capacitor 14 is briefly connected to the summation capacitor 19,. to whom he hands over his charge.

If the measuring wheel 3 continues to rotate, the contact between the springs 9, 10 and the opens Rocker arm 7 swings back into the position shown in FIG. 1 as a result of its weight attachment 31, in which the contact with the springs 9 and 11 takes place again. This restores the idle state, and the unit capacitor 14 is recharged from the power source 16.

Since on each measuring wheel the recurrence of such an alternation sequence after each passage of a length measuring unit of the material to be measured takes place, the contact with the springs 9, 10 means the passage of a Length measuring unit.

The capacitance of the total capacitor 19 is a multiple of the capacitance of the unit capacitor 14 and depends on the number of surface units to be measured with the machine. Since the unit capacitor 14 delivers a unit charge to the total capacitor 19 for each unit area to be measured, its capacity must be times the capacity of the unit capacitors with a maximum measuring range of η units of area.

If the capacitance of a unit capacitor is to be denoted by C _{e , then the capacitance C 5} of the total capacitor must be at least

C, = η ■ C ₁ ,

being. In this case, when the measuring range is fully utilized, the summation capacitor 19 is charged to the voltage value of the supply current source.
With E / _8JJ as the supply voltage, one obtains the charge of a unit capacitor

Qe =

U _s

and when this charge Q _{e is transferred} to the summing capacitor, it has a charge of

Q _S = C _S -U _Z , . (3)

where U _{z represents} the voltage that occurs on the summation capacitor after Q _{e has been transferred.} Since the energy level of the charge does not change when transferring from one capacitor to the other, the right-hand sides of equations (2) and (3) can be equated and one then obtains

C _e

U _n = C _S

U _Z

(4)

Substituting the value of C ₈ from equation (1) into equation (4), one obtains

C _e -U _sp = -nC _{e -U z} ,

and it remains as a voltage on the summation capacitor after transferring a charge of a unit capacitor

U, =

If you set the value

U.

U.

= K,

Since both {7 _SP as the supply voltage and η represent a constant, when χ unit charges are transferred to the total capacitor, a total voltage of the size χ ■ K results, i.e. the measured voltage is directly proportional to the number χ of unit charges transferred. But since this is also equal to the number of scanned area units, it represents according to the equation

is a direct measure of the surface scanned and the scale of the measuring instrument can be read directly in Area units are calibrated. Here, the unit charges from the unit capacitors in Completely any sequence or at the same time can be delivered to the summation capacitor.

Since the summation capacitor is charged according to an exponential law, the capacitance _{value of C 8 is} preferably chosen to be at least equal to το ηC _e , so that the charging process of the summation capacitor takes place essentially in the straight part of the exponential characteristic and thus a linear calibration of the measuring scale becomes possible.

The power source 16 shown as a battery in the exemplary embodiment can also be used in practice be replaced by a stabilized power supply unit. The voltage of this power supply is appropriately so chosen that the entire system can be designed as a low-voltage system, so that no special Protective measures are required.

The voltmeter 23 required for voltage measurement must have the lowest possible internal power consumption to prevent the instrument from discharging the summation capacitor too quickly. A tube voltmeter or a measuring instrument with a similarly low internal consumption fulfills these requirements.

The measuring principle described makes it possible to measure the voltage on the total capacitor of the respective Adjust the size of the material to be measured and thereby increase the accuracy of the measurement. This can

509 698/148

M 16796IX / 42 c

can be achieved by simply switching the range of the voltmeter to greater sensitivity.

Claims (8)

PATENT CLAIMS: 5 1. Device for measuring areas according to the strip totaling method, in which the to measuring surface into a proportional number of current pulses by scanning devices ίο is resolved, the size of which is limited by a unit capacitor and in which the The sum of the current impulses that is the desired area measurement by measuring the total charge is determined by summing capacitors, which are generated by the current pulses generated during scanning are charged, characterized in that each scanning device has a separate Unit capacitor (14) is assigned and that these unit capacitors (14) their Measurement charge in accordance with the sampling pulses independently of one another to a common Summing capacitor (19), the capacity of which is a multiple of the product of the Capacity of a unit capacitor and the is the maximum possible number of discharges of the standard capacitors occurring during a measurement process. 2. Device according to claim 1, characterized in that that the voltage on the summation capacitor (19) is used directly as a measure for the scanned area. 3. Device according to claim 1, characterized in that that each scanning device during the measurement one of three contact springs (9,10, 11) existing changeover contact actuated, the associated unit capacitor (14) in the starting position for charging with a DC source (16) and in the measuring position to deliver its charge briefly with the common Summing capacitor (19) connects. 4. Device according to claim 3, characterized in that the change in contact positions (9, 11 or 9, 10) of the changeover contact by pivoting a rocker arm (17) rotatable in a holder (4). 5. Device according to claim 2, characterized in that the measurement of the voltage on Summing capacitor (19) by a voltmeter (23) with low internal consumption and high internal resistance takes place, which is provided with a scale directly calibrated in units of area. 6. Device according to claim 1 to 5, characterized in that the capacitance of the summing capacitor (19) equal to or greater than ten times the product of the number of maximum measurable Area units and the capacitance of a unit capacitor (14). 7. Device according to claim 3, characterized in that as a direct current source for the the actual measuring device is a voltage-stabilized mains rectifier (16), preferably a lower one Voltage is used. 8. Device according to claim 5, characterized in that the voltmeter (23) to different Sensitivity ranges is switchable. Referred publications:
German Patent No. 875 572;
British Patent No. 471731; U.S. Patent No. 2359934;
Electronic Engineering, 1951, pp. 213-216. 1 sheet of drawings © 509 698/148 3.56