DE709116C - Arrangement for generating a pulse train, the pulse frequency of which depends on the deflection of a measuring mechanism - Google Patents

Description

Arrangement for generating a pulse train, the pulse frequency of which is from depends on the deflection of a measuring mechanism Task to generate a pulse train, the pulse frequency of which depends on the deflection a measuring mechanism is dependent. So z. B. for the remote transmission of measured variables the known pulse frequency method used, the pulse frequency of the to to be transmitted measured variable. There is also a method for counting become known, in which a pulse train is generated, the pulse frequency of which the Corresponds to the course of the meter to be calibrated and compared this with a pulse sequence. which is proportional to the measured variable in question.

In both cases one has so far the relevant pulse trains -under - Generated use of electricity meter measuring mechanisms. But this procedure has the disadvantage that counter measuring mechanisms as a result of the journal friction and for other reasons do not achieve the measuring accuracy of an indicating measuring instrument.

On the other hand, an arrangement for generating a pulse sequence, the pulse frequency of which is dependent on the deflection of a measuring mechanism, has become known, in which the measuring mechanism controls a light beam that falls on a cylindrical collecting surface which revolves at a constant speed and is provided with slot-like passage openings in such a way that the light beam, depending on its deflection by the measuring mechanism, hits a photocell through a different number of openings during one revolution. The slot-shaped passage openings are 5ämtlicli s s in the direction of the generatrix of the cylinder. thus arranged at right angles to the direction of movement of the cylinder surface at equal intervals, but correspondingly graded in length. A window extending over the entire width of the cylinder and then an opaque surface adjoin these slot-shaped passage openings. To use this arrangement for the remote transmission of the measured variable indicated by the measuring mechanism; a long-distance line is connected to the photocell via an amplifier and a relay. This leads to a receiving arrangement. This consists of a number of relays and a pointer arrangement controlled by three electromagnets the three electromagnets work finitely with the help of switching mechanisms and other kinematic gears on the pointer arrangement in such a way that the pointer of the receiving arrangement is set in increments according to the respective deflection of the measuring mechanism with each rotation of the zv linear triple collecting surface.

This known arrangement has, apart from the relatively complex design of the receiving device, which is therefore prone to interference, the disadvantage that the pointer of the receiver does not hit the measuring mechanism continuously follows. In contrast, the object is achieved by the present invention solved to generate a pulse train, the pulse frequency of which in each eyelid; corresponds exactly to the deflection of the measuring mechanism, the same proportionally simple and reliable receiving devices can be used, as they are called the well-known pulse frequency method of remote measurement Viblich. are and continuous Gbertrarung the \ Teßwerl: Ausclilages enable.

This is called an arrangement for generating a pulse train whose Pulse frequency depends on the deflection of a measuring mechanism at which the measuring mechanism controls a light beam that falls on a cylindrical collecting surface, which revolves at a constant speed and in such a way with slot-shaped Passage openings is provided that the light beam depending on its deflection by the measuring mechanism during one revolution by a different number of Openings on a l ', otocell, achieved according to the invention in that the slot-shaped passage openings against the direction of movement of the collecting surface are inclined so that the distance between the slots, measured in the direction of movement, in the direction of the deflection of the light beam changes continuously.

Fig. I in the drawing is a schematic representation of an embodiment (leg '@: ingenious, where Fig. 2 illustrates the collecting area in the development.

1 # ig. 3 shows the arrangement of an intermediate mirror for influencing the dependence of the pulse frequency on the leasehold.

Fig..I illustrates the use of the finding for a remote measurement and FIG. 5 for a device for counting.

A light duel .Io illuminates a slit diaphragm42 by means of a lens .4i, the length of which is perpendicular to the plane of the drawing. [- 'in (ybjel: tiv 43 now creates an image of the S S ZD paltblende 42. whereby the light beam is guided over a \ leßwerl: mirror, .4. and a cylindrical lens 45 in such a way that..`3 -ein im A substantial point-like image of the diaphragm 4.2 arises on a collecting surface 4.6 which is arranged on the circumference of a cylindrical drum 4. The measuring mechanism mirror 4.4 is controlled by a measuring mechanism 48, the deflection of which is to be converted into a corresponding pulse train.

For this purpose, the collecting surface .1G, as shown in Fig. 2, provided with slit-shaped passage openings through which the light beam on one inside the drum 4 .; arranged concave mirror .1d can fall, the directs the light to a photocell 5o. The drum -1 -; is in a warehouse 51 rotatable around its axis. The drive takes place via a transmission gear 52 from an engine, e.g. B. from a synchronous motor 53, which is from an alternating current network Regulated frequency is fed, so that he finitely exactly the same constant the drum Speed drives.

As seen from Fig. A, the slot-shaped passage openings against the longitudinal direction of the strip, ie against the direction of movement inclined in such a manner are arranged reasonable that the distance of the slots, enjoy in the direction of movement z. B. is smaller on the left side of the strip than on the right side and increases steadily from left to right.

If now the collecting surface 46 at a constant speed is moved, the light falling on the surface will only pass through if the point-like image designed by the diaphragm 4.2 straight onto one of the slits falls, and the frequency with which the photocell 5o is periodically illuminated changes constantly with the position of the Light point on the collecting surface, thus with the deflection angle of the light beam which is dependent on the deflection of the measuring mechanism q. The electrical impulses generated by the photocell 5o are therefore dependent on (learn Deflection of the measuring mechanism 48 ..

The outer surface of the drum 47 can, for. B. made of sheet metal into which the corresponding slots are milled. But you can also use the drum made of transparent material, e.g. B. Glass, produce and on 'the surface with cover with an opaque layer, cut out at the passage openings is. This layer can also be produced by photographic means.

If the deflection angle to be used for conversion to a pulse train a of the measuring mechanism mirror 4.4. and thus also the deflection angle 2 a of the light beam If it is very small, there is proportionality between the deflection angle with a large approximation a and the corresponding movement of the point of light on the collecting surface: I6, see above that the pulse frequency is linearly dependent on the angle of deflection α. If now there is also a linear relationship between the angle α and the measured variable, then there is thus a linear relationship also between the pulse frequency and the measured variable, which is often requested. But if one of these conditions is not met, then if necessary, a corresponding compensation is created by optically, -, 1, means, z. B. by placing an intermediate mirror between the measuring mechanism mirror and the collecting surface arranged, the shape of which is chosen so that the frequency of the generated by the photocell Impulse is linearly dependent on the measured variable fed to the measuring unit.

Such an arrangement is shown schematically in FIGS the designations 4.o to 4.4, 46 and 4.8 have the same meaning as in Fig. i. Between the measuring mechanism mirror and the collecting surface q.6, which is only through a line is indicated, there is a mirror 54, the shape of which is known per se Means is adjustable so that a linear relationship between the movement of the Light point on the collecting surface 4.6 and the measured variable exists, so that the The pulse frequency generated depends linearly on the measurement size.

In order to use the pulse sequence generated by the photocell 5 o for remote transmission of the measured variable, as shown in FIG feed, such is z. B. from a changeover relay 57, ' whose winding 58 the pulses are supplied. As a result, with the aid of a current source 59, capacitors 6o, 61 are charged in a manner known per se and discharged via a display instrument 62 whose measuring value is provided with sufficient inertia so that the deflection corresponds to the mean current strength. It is important that one z. B. with an intermediate mirror according to FIG. 3 can influence the scale profile of the receiving instrument 62 as desired in one direction or the other.

Fig. 5 shows a counter test device in which the invention is used is used to generate a comparison pulse train based on the deflection of a Power meter is dependent, which serves as a standard instrument.

The measuring mechanism disk i of the meter to be calibrated is, as usual, with a colored brand? Mistake. To generate a pulse train zii, its pulse frequency depends on the running of the meter to be calibrated, is a light source 3 provided, which irradiates the counter disk i via an optics .4. so that the thrown back Light illuminates a photocell 5. The lighting changes every time the market is irradiated. As a result, pulses are generated in a manner known per se, which are fed to the winding 7 of an electromagnet via an amplifier 6: whose armature 8 is attracted with each current surge and a contact 9 closes. So that the circuit of an auxiliary power source is OK via two electromagnetic windings i i, 12 and a break contact 13 closed, the contact 9 by one of the armature i of the electromagnet i i actuated contact 15 is bridged.

The armature 16 of the electromagnet 12 is now a push button 17 actuated. This will make a hand 18 of a twin stopwatch i9 with your not particularly shown clockwork coupled, where .the pointer 18, starting from the zero position, turns 2o in front of a dial. Simultaneously with the anchor 8 is attracted by the electromagnet, 7 an armature 21, which is a pawl moves, which rotates a ratchet wheel 22 each time by one division. Here you can the armatures 8 and 21 can also be combined in one component. With the ratchet 22 is a cam plate 23 adjustably connected, on which a spring 24 slides, the cooperates with contact 13.

According to a dial 22 that can be selected by setting the VTokken: Number of power surges, the nose of the spring 24 falls from the \ ockenscheibe and opens contact 13. This interrupts the circuit of the auxiliary power source io and thus the coupling of the pointer 18 solved with the clockwork, so that the pointer stops.

In substantially the same way, a time pointer 25 of the Controlled photocell 5o an arrangement according to the invention, the relevant Push button 28 is actuated by the armature 29 of an electromagnet 3o. This arrangement can e.g. B. be built according to Fig. I, the same designations in Fig. 5 are chosen for the same parts. 4.8 is the measuring mechanism of a precision power meter, which is designed as a light pointer instrument. The photocell 5o then generates a Comparison pulse train, the pulse frequency of which is linearly different from that of the power meter and the power supplied to the meter to be calibrated.

The calibration is now valid in the following way The arrangement controlled by your measuring mechanism 4.8 generates 2,000 pulses per kilowatt hour and the meter to be calibrated makes 10000 revolutions per kilowatt hour, provided that it runs flawlessly. If now the two pointers 18 and 25 after stopping should indicate the same time, the number of pulses or revolutions must obviously can be selected according to the respective counter constant.

You can therefore z. B. adjust the cam 23 so that it After six rotations of the counter measuring mechanism to be calibrated, a push button 17 is pressed and thus the pointer 18 stops while the corresponding cam disk opens the side of the comparison instrument is set so that, by means of the push button 28 stops the pointer 25 after twelve revolutions. If the pointer 25 now z. B. stops after 60 seconds and the pointer i8 after 55 seconds, what you can see on the Dial 2o can be read, this is a sign that the meter to be calibrated has advanced at a ratio of 55: 6o. The error is therefore -i-% 0 or -I- 8.33 ° / °. I! @ In order to be able to read off the percentage of errors immediately, the in the Drawing indicated facility are provided. The dial: 2o wears on. Edge another logarithmic division similar to a slide rule. she is surrounded by an equal logarithmic division on a by means of a Knob 31 rotatable ring 32 is attached. The ring 32 carries zero on its outer Edge a second division that coincides with the one attached to the inner edge. however, the numbering is chosen so that the value ioo on the inner scale is the Designation o l /, on the outer corresponds and the relevant - tick marks to the left of it with -1- i0 ° / 0, -r @ o ° @ "" etc. and to the right of it with -1o °% 0, = 200j ° etc. are designated. Opposite (lem graduation ioo on the fixed logarithmic scale a fixed mark 33 is arranged.

If z. B., as shown, the pointer 25 on the graduation 6o and the pointer 18 has stopped at the graduation 55, it is rotated by means of of the button 31 the ring 32 so that the graduation 55 on the inner scale of the ring 32 is opposite the graduation 6o on the outer scale of the disk 2o. Then can the error of the meter to be calibrated at the position of the outer scale of the thing 32 directly compared to the fixed mark 33 as a percentage.

To find out the error of the meter to be calibrated with any other Load, e.g. For example, to determine the maximum load at 5o '/, it is advisable to use one - So-called matching converter for connecting the power meter .I8. where one is the gear ratio selects this converter so that the power meter always works at full load. In this case the ratio of the number of pulses must be adjusted accordingly of the nock washer. At 50 ° / 0 the rated load can be used for this purpose z. B. the number of pulses coming from the power meter to six instead of twelve or the number of pulses generated by the meter to be calibrated to twelve instead of six can be set. This ensures that the power meter is only at one load point needs to be precisely calibrated.

The inclination of the slot-shaped passage openings in the collecting surface .I6 can then be selected so that the pulse frequency is within the range specified by the expected small power fluctuations given limits is changed. There it is easily possible, within this small scale range, to determine the measurement errors of the Keeping performance inessers very small is a very precise determination in this way the measurement error of the meter to be calibrated regardless of any fluctuations in power possible.

Claims (7)

PATENT CLAIMS: i. Arrangement for generating an Inipulssequence whose Pulse frequency depends on the deflection of a measuring mechanism. where the measuring mechanism controls a light beam that is directed to a cylindrical; Collecting area falls, which rotates at a constant speed and so with slot-like passage openings is provided that the light beam depending on its deflection through (read 1leßwerk while one revolution through a different number of openings on a photocell meets; characterized in that the slot-shaped passage openings such against the direction of movement of the collecting surface (46) are inclined that the distance of the slots from each other, measured in the direction of movement, in the direction of the The deflection of the light beam changes constantly. 2. Arrangement according to claim i, characterized by. that the carrier (47) of the collecting surface (46) is transparent and is covered with an opaque layer in which the passage openings are recessed. 3. Arrangement according to claim i or 2, characterized ', d.aß from a diaphragm (42) illuminated by a lamp (4o) by means of an optical one Arrangement (43) via a mirror (44) controlled by the measuring mechanism (48) essentially punctiform image is designed on the collecting surface (46). 4. Arrangement according to Claim 3, characterized in that between the measuring mechanism mirror (44) and the Arranged collecting surface (46) is an intermediate mirror (54), the shape of which has been selected is that the frequency of the pulses generated by the photocell (5o) is linear from the the measured variable fed to the measuring mechanism (48) is dependent. 5. Arrangement according to one of the Claims i- to 4, characterized in that those generated by the photocell (50) Pulses from a receiving device known per se for remote pulse frequency measurement are fed. 6. Arrangement according to one of claims i to q. to calibrate one Electricity meter by means of an electrical one serving as a comparator Power meter, whereby a pulse train is generated, the pulse frequency of which corresponds to the Corresponds to the course of the counter measuring mechanism (i) to be calibrated and by means of one of. the Impulse controlled stopwatch telling the time for a selected number of revolutions of the Counter measuring mechanism is determined, characterized in that the deflection the power meter (48) dependent comparison pulse sequence after a suitably selected Number of pulses a second stopwatch controls so that both stopwatches after Stop showing the same time if the counter measuring mechanism to be tested is faultless runs. 7. Arrangement according to claim 6, characterized in that the two stopwatches are combined to form a twin stopwatch (i9) with a common dial (2o).