DE633116C - Automatic integrating device - Google Patents

Description

Automatic integrator The invention relates to a Improvement of automatic integration devices for ongoing measurements. These Apparatuses are similar to the usual planimeter with a friction roller, mostly with a afflicted with the smallest measurement error, the absolute size of which is independent of the size of the planimetrizing The measured value remains approximately the same over the entire measuring range and therefore with large measured values in percentage terms little, in the case of smaller percentage matters all the more. This attribute is undesirable where it matters, with mechanical integration or planning out Obtaining results with equal percentage errors, d. H. Results equal Accuracy over the entire measuring range.

Consider e.g. B. an ordinary friction gear according to Fig. R, which consists of a rotating disk i, one of which is slidable on it Friction wheel 2 is driven, with which a counter 3 is connected. The speed of the counter 3 corresponds to the rotational speed of the disk i multiplied with a factor that results from the position of the friction roller: z. The display amount of the counter per revolution of the disc grows proportionally to the distance between the friction wheel 2 from the disc center q ..

The friction roller position is now due to a donor on the basis of some variable, continuously recorded measured variable determined, with inaccuracy the measurement or due to friction on the transmission rods a deviation from The desired value of the friction roller position is to be accepted as a rejection of the role is designated. Depending on the type of donor device, this is over in many apparatuses be the same or at least of the same order of magnitude over the entire measuring range, and as a result, the inconvenience then occurs that at high running speed the role, d. H. at a great distance from the center of the pane, their declination an insignificant percentage, but one if the running speed is slow results in counting errors that are significant in percentage terms. This means that the Apparatus works much more precisely with a low roller ratio than with a high one.

The same also applies in the event that the role is on a cone shell runs. For here, too, a rejection of the role has a change in the associated one Running circle diameter result, which is the same in every position of the role, without Consideration of the absolute size of the respective running circle diameter.

The same inconvenience also occurs with transmissions, in which one Roll runs on the jacket of a solid of revolution, the generatrix of which is an axis of the solid of revolution touching the circular arc. 11-. It's the increase though the running circle diameter experiences in the case of a misalignment of the friction wheel position, in the area smaller running circle diameter, alsb at the tip of the rotating body smaller than in the area of large running circle diameters, i.e. in the vicinity of the Base of the solid of revolution. However, in the formation of the body of revolution, the relative Errors as a result of a rejection of the. Friction wheel position in the area of the small running circle ;: diameter so large, at the top in size =. fall even infinitely large, that practical rit ;; i% `a part of the" @ solid of revolution that follows the base Can be found. As a result, however, the measuring range, i.e. H. the ratio of the greatest Running circle diameter to the smallest, restricted, so the facility for some Purposes becomes unusable.

This disadvantage is avoided by the arrangement according to the invention. This consists in that a rotary body is used as the running surface for the friction wheel whose generating line is located outside the axis of the solid of revolution Is a circular arc, and that at the same time the friction roller is supported in a swivel arm whose pivot axis is through the centers of all meridians of the body of revolution formed circle touches.

The much more uniform size of the relative Error in the range of possible friction wheel positions is due to the fact that the same size Error in the angular position of the swivel arm; if the friction wheel is on a small one Track circle (latitude) of the solid of revolution runs, much smaller differences the turning circle diameter, d. H. the absolute magnitudes of the errors are much smaller than when walking on a large turning circle, the turning circles, however, never have such small values assume that the relative errors are becoming unbearably high.

Such an arrangement is shown in Fig. 2 shown. The tread of the Friction roller 6 is created by rotating the meridian circle around the axis 12, which passes the meridian circle at a distance a. The friction wheel 6 with the counter 7 is carried by a pivot arm 8, the axis 9 of which is perpendicular to the plane of the drawing and through the center of the meridian line io of the solid of revolution lying in the plane of the drawing i i goes halfway through the centers of all meridian circles above the drawing plane and. half touched under the same circle to be thought. The friction wheel 6 runs on circles of latitude 14 of the body i i, depending on the position of the swivel arm 8 have larger or smaller diameters. The drawn meridian division corresponds to a linear increase in track circles i4, - d. H. of the count result. From the associated swivel arm rays can be seen that their angular distances an, a2 im The area of small track circles becomes large, in the area of large track circles it becomes small. For comparison the device according to the invention with the known device in which the Friction roller on the coat of a '? 2btation body runs, its generating sbogeri the 'axis of the solid of revolution: `blr'i'thrt, for the purpose of illustration =: e' The advantage obtained is the relative error resulting from a rejection calculated for some friction wheel positions: In order to compare the known device, in which the role is fixed and the rotational body is axially displaced with the To enable the device according to the invention, will also apply to this device assumed that the friction roller is mounted in a swivel arm around the center of the meridian circle lying in the plane of the drawing is rotatable. Such an arrangement is shown schematically in Fig. 3.

It means p the radius of the friction roller, .izl the speed of rotation of the rotating body, n is the speed of the friction roller, r is the radius of the track circle.

The relationship exists between these radii and speeds The relative error, - ie the ratio of the difference between the actual speed and the target speed to the target speed of the friction roller as a result of a misdirection of the friction wheel arm. the change in the turning radius of d a- is caused by this For the arrangement according to Fig The following applies to the arrangement according to the invention (Fig. 2), in which the axis of the rotational body passes the meridian circle at a distance a If one uses these formulas to calculate the smallest error F for various angular positions a of the friction wheel arm @ es based on a declination da = o, or7 (approximately i ') and assuming the ratio a: R = 1 / e, the following table results: 2 0 Fa 0/0 C 0 / 0- 0 00 0 io 18.5 2.1 20,917 3.1 30 6.3 3.3 40 47 3.0 50 3.6 2 @ 7 6o 2.9 2.4 70 2.4 2.1 80 2.0 1.8 9o 1.7 1.5 It is thus evident that the arrangement according to the invention has a very small error which changes only insignificantly over the entire measuring range. The known device, on the other hand, has errors in the area of small angles a which very restrict the use of this device. If you want to avoid errors in the known device that are greater than the errors occurring in the device according to the invention, you can, as the table shows, only use the part of the rotational surface between the pivot angles a = 50 ° to a = 90 °. However, a significantly smaller measuring range is then obtained; for the specified limits, the largest track circle diameter is only 2.7 times the smallest, in contrast, in the case of the arrangement according to the invention, it is 8 times. The advantage of the arrangement according to the invention, the practically constant error, can therefore only be achieved in the known arrangement by dispensing with a large measuring range, which is indispensable for some purposes.

Theoretically, it would be the most favorable case in terms of uniform accuracy can be achieved if the meridians of the rotational body could be designed in such a way that that the diameters of the different track circles angle sizes a1, a. the swivel arm position which increase according to the logarithmic measure of the track circles.

Such a scheme is shown in Figure 4 for explanation. The axis of the friction wheel swivel arm 17 goes perpendicular to the plane of the drawing through the point 16. -The circle bb around 16 has the logarithmic division I 'to VIII' in the pivoting range that is used. The axis 18 of the rotation body is in turn in the plane of the drawing. The lines I ", II" etc. to VIII "are drawn parallel to it at the same distance. The points of intersection I to VIII of these parallels with the rays drawn through 16 and I 'to VIII' are the geometric location for the meridian line of the solid of revolution, It can be seen from the figure that, according to the logarithmic angular division, a misalignment of the swivel arm 17 by an angle d a, which, for example, would result in errors in the area of the track circle I with a diameter of 10 mm and If the friction wheel ran on the track circle with a diameter of II mm instead of 10 mm, in the area of e.g. ii-log io = log 66-log 6o = log i, i. The declination therefore remains the same percentage in both cases, namely io%.

However, such a body of revolution as shown in Figure 4 would be difficult to manufacture and would both unequal lengths of the swivel arm 17 and misalignment of the Friction wheels to the running surface for the individual role positions require, while at the arrangement according to the invention according to Fig. 2 gives the possibility of the friction wheel to be placed perpendicular to the running surface and with the same length of the swivel arm even easier to pivot than with conventional friction gears which the roller axis or the running surface is shifted in a straight line. thats why to describe it as particularly welcome that in the arrangement according to Fig. 2 the Approach to the mentioned best case of Fig.4 is already so great that it is entirely sufficient for practical purposes.

Integrators according to this arrangement are special for running counting : suitable when the swivel arm of the friction wheel is controlled by levers or organs whose position changes themselves also according to the logarithmic measure of the factor take place whose influence they have to transfer, because then as a result of this suffice Parallelism of the movement characteristics between these levers and the swivel arm simple coupling rods or curve thrusts with a very even slope, whose Equally favorable adjustment effect of the accuracy of the display over the entire measuring range benefits. As is well known, levers with a logarithmic law of motion are now used For their part, it is particularly useful for multiplication gears, d. H. if it is a matter of several changeable factors continuously mechanically with one another to multiply. As a result, the present integrating work is ideally suited for a combination with such logarithmic multipUation gears, i.e. it is particularly useful where there are several changing factors to make the product and this as a. variable factor with the differential a continuously to be counted further measured variable, z. B. time or amount to integrate is.

As an example, consider a gearbox for the automatic reduction of the display of a volume gas meter for gases from a variable state to a normal state. The volumetric meter, e.g. B. a drum gas meter, drives the rotating body zz of the counting apparatus in Fig. 2. The swivel arm 8 of the friction wheel is to be adjusted by a lever 2-o, the position of which is decisive for the size of the respective reduction number x. Now the reduction number x can be formed as the product where p1 is the absolute Pressure, T ,. the absolute Mean temperature of the gas. One can therefore use one of the known multiplication gears to adjust the lever 2o, in which the product of the folding gates p and Tl is formed by logarithmic addition, by using measuring instruments for the absolute pressure and the temperature, the measured values of which in logarithmic measure - z. B. by cornering thrusts - are transmitted. A particular advantage of this is that, in the case of a piece-wise execution, the relevant curve thrusts can be used at the same time to take into account the calibration characteristics of the measuring instruments.

The deflections of the lever 2o driven in this way follow then even logarithmic values of the reduction factor x, that of the one to be driven Pivoting lever 8, however, must also do it approximately according to what has been said above. As a result, the cam thrust 21 to be engaged between the two levers can be a simple one Obtained form of uniform slope, so that through it no additional unequal Error sizes are carried into the various working positions. The counting yard of the gas meter thus gives, provided that the volumetric meter and the measuring instruments display correctly yourself, results of the same percentage over the entire measuring range Accuracy.

In order to be able to press the friction wheel sufficiently, according to the invention made a special arrangement of the same according to Fig. 5. The carrying fork 57 of the friction wheel 38 is rotatable about an axis 6o which is directed perpendicular to the running surface of the wheel is. This allows the wheel to pivot. The curve thrust 21 of the lever 2ö (Fig. 2) not the support arm of the friction wheel itself is pivoted, but (Fig. 5) a tiller 59 attached to the rotatable roller fork 57, approximately below Mediation of the guide arm 4o, which is also rotatable about the axis 36 of the support arm. If the latter is adjusted with the lever: 2o (Fig. 2), this is very necessary low force. Because the running-in of the spring-pressed friction wheel into the Position of the guide arm corresponding track circle takes place automatically and enforces in this way, following the support arm 576o with a large adjustment force that not the lever 2o (Fig. 2), but the rotating body, d. H. the gas meter, borrowed will. The drawbar arrangement thus acts like a relay with a servo motor.

The drive of the counter from the mobile roller 38 is advantageous passed over the pivot axis 36 of the pivot arm 40, such as. B. shown in Fig. 6. In this way, any repercussions of this work to be done on the pivotability .of the arm 40 avoided. In Fig. 6 a 'double lever So, the one on the swivel arm is stored at 5 t, by a cam or eccentric connected to the friction wheel 55 a pendulum motion. Where the lever So intersects the axis 36 of the swivel arm, is through a ball joint or the like. A reciprocating movement of the lever The counter drive 58 converts into a unidirectional rotating movement (clamping jaw, Ratchet drive o. The like.) Articulated, which is independent of the pivot position of the arm 4o drives the counter.

Claims (3)

PATENT CLAIMS: r. Automatic integration device for running Measurement using one on top of that of a circular arc-shaped generatrix formed concave surface of a rotating body running friction wheel, thereby characterized in that the generating meridian circle is outside the axis of the body of revolution lies and the friction wheel is mounted in a swivel arm whose swivel axis is the touches the circle formed by the centers of all meridians of the body of revolution. 2. Automatic integrating device according to claim z, characterized in that the fork (57) of the friction wheel (38) is rotatably mounted on a special support arm (6o) and is pivotable by a drawbar (59) located on the fork, on which the setting of the support arm (6o) takes place by pivoting the friction wheel (38). 3. Automatic integration device according to Claim i and 2, characterized by a lever (5o) which is rotatably mounted on the swivel arm (4o) and which, with the aid of an eccentric (55) located on the friction roller (38) or a cam in oscillation is displaceable and in the point where it is the extended axis (36) of the roller supporting swivel arm (4.o) cuts, with a back and forth movement of the lever (So) into a unidirectional rotating movement of the counter drive is articulated. q .. Automatic integrating device according to claim i to 3, characterized by driving the pivot lever of the friction wheel by means of an after logarithmic measure of its setting values moved lever, which is connected to a known, multiplication gear based on logarithmic addition is connected. The patent seeker has been identified as the inventor; Dipl.-Ing. Friedrich of Schütz in Berlin-Lichterfelde-West ..