DE2353473B2 - DEVICE FOR MEASURING AND REGISTERING RELATIVE FREQUENCY FLUCTUATIONS - Google Patents

Description

The invention relates to a device for measuring and registering relative frequency fluctuations in a pulse train, in which a frequency-voltage converter and an electronic quotient network are connected in series, the quotient network being formed by a quadrupole with a non-similar characteristic curve, to which the fluctuation magnitudeIZ ₁ and the mean value U _n , are fed to the pulse train and set by the quadrupole to each other ms ratio. In particular, the invention is suitable for monitoring the speed fluctuation of rotating shafts or the speed fluctuation of uniformly moving paper or film webs. In devices of this type, a frequency proportional to the speed or speed is converted into a speed-analog voltage with the help of a frequency-voltage converter and set in relation to the mean value of the frequency by means of an electronic quotient network.

Pulse sequences can be used, for example, by means of electronic Generators, but also through mechanical pulse generators on optical, inductive or mechanical Create a basis.

In many cases the speed of work determines a production machine directly the quality or the physical or chemical properties of the product. For example, a mechanical pulse generator is coupled with a negligibly small one Pitch error on a rotating shaft of such a machine can be seen from the fluctuation the frequency of the pulse train directly on the fluctuation of the rotational speed or peripheral speed close this wave. Conversely, the pulse train fluctuation provides one with constant angular velocity driven pulse encoder whose division error. Further application examples are the Measurement of pitch fluctuations on tape recorders, frequency jitter in pulse generators.

Many measuring methods working on the basis of pulse train fluctuation measurements require this Knowledge of the relative frequency fluctuation, based on the mean value of the pulse train over time.

Such a measuring device is described, for example, in German patent specification DT-PS 10 56403. With the help of a quotient network, this device forms the quotient from the fluctuation amplitude and the mean value of the pulse train over time The built-in magnetic switch ensures the accuracy and scope of the measuring range and the quotient level is severely limited. With sequential operation of the measuring device with several measuring points the device has too long a setting time.

The main object of the invention is therefore to improve this measuring device. In particular is intended to increase operational reliability, measurement accuracy, measurement scope and calibration stability will.

This object is achieved in the device described above according to the invention in the following way: The quotient network consists of an amplifier with a logarithmic characteristic, the output of which is followed by a high-pass filter, the time constant of which is automatically reduced when the long-term mean value U _n at the output of the quotient network changes , while at the same time the output AC voltage Ujt) of the quotient network is automatically separated from the input of the high-pass filter by a low-pass blocking element connected upstream of the high-pass filter.

In a preferred embodiment of the invention, the locking member is designed as a KC low-pass filter

Time constant by means of a field effect transistor T ₂ * ^ ί fun '

eldjffel

By the relation (4) and the equation U) this quotient is proportional to the speed surman kung. based on the average speed

ransistcrs i, aui nicuiigcic »» v ^ _u . ·. ^ .. ». ^^ ^ -

Further improvements to the device, for example

Apr Installation of a display lock, see such as a border

value display, are in the claims be

ujit)

(7)

⁸ MU the new device will have a significantly higher temperature stability, a larger frequency range, a longer offset and a better linear measurement. Another advantage lies in the extended measuring range with simultaneously improved accuracy. It achieved a measuring accuracy of approx. ± 1%. Since drh can display a logarithmic function precisely even over long periods, the previously necessary recalibration of the measuring device is no longer necessary. With the switchable high-pass filter, you achieve a shorter reloading time of the high-pass filter and thus a reduction of the response time to <> s.

The following is an example of the Invention described in more detail with reference to drawings. The principle of the circuit is also described

f ¹ p

^ SfBbCkSaIIbUd of the measuring arrangement. Pie "-> the principle of F / U conversion. Fig. 3 the mode of operation of the quotient nei / -

l Tau switchable high-low-pass filter with 'esDerre and limit value display. S: object to be measured. For example, a rotating shaft 1, st mechanically coupled directly to a photoelectric encoder 2. The time function of the speed "(M can be divided into two components

n (t) =

(Il

decompose, a constant component / i ", (mean speed) and a fluctuation component n _s (r). 4 ·

The time function of the pulse frequency / Cf) of the encoder 2 is proportional to the time function n (r) of Wave 1:

This frequency-time function is converted into a proportional voltage-time function UU) by the frequency voltage converter 3 (F / U conversion).

that is, the desired measurand.

The alternating voltage occurring at the output of the quotient network 4 is then a switchable high-low-pass filter 5 is supplied and after amplification in the amplifier 6 by the display instrument or the dial 7 is displayed. The individual function groups 2 to 6 described in more detail.

1st giver

The encoder 2 has the task of a rotary movement or one that is mapped as a rotary movement Another process of generating a number of electrical impulses proportional to the angle.

Hr is 7th R designed as a photoelectric transmitter and consists of a rotatably mounted pulse disc. those with a spoke-shaped slot or S'richmarke classification is given away with high graduation accuracy. The pulse disc interrupts through their division marks periodically a light beam emitted by a fixed light source «J a fixed photodiode is directed. The photodiode converts the light pulses into voltage pulses.

2. F U converter

In the F U converter 3 (FIG. 2), the voltage pulses from the transmitter 2 are converted into voltage pulses of constant pulse height U ₁ and constant pulse duration r by a monosable multivibrator. If the following active low-pass filter suppresses all frequency components above a cut-off frequency, the output voltage U _{11 of} the low-pass filter is obtained

'■ U ₀ F ■. 4,, \

1 ! ₌ = TC ₁ , ./Hl.

(8th)

(3)

Since there is proportionality between the output voltage of the frequency converter and the speed according to relationship (2), this results

UU) - n (t) (41

and taking into account equation (i)

UU) = U _n , + Li, U). (5)

The following quotient stage 4 forms the quotient from the fluctuation function i ' _s (/ l and the mean voltage U _m, that is to say a voltage proportional to the rotational speed or speed.

3. Quotient network

In the quotient net / work (Fig. 3) one obtains a non-linear characteristic curve with the Output voltage of the F / U converter 3 according to equation (8) the quotient according to equation td). as the logarithmic functio-

lion

Q -

U, U)

u ", at the operating point A of the characteristic curve, which is set by the voltage U _n , results in the output alternating voltage U ₁ Jt)

'' Jf) "- ■ I - '(U _1n ) - UJfI. UO)

The gain 1 (U _1n ) is the Quoiientcnstufc

equal to the slope of the characteristic at working point A (U _1. = UJ

V (UJ =

you.

(H)

With equation (9) now becomes

\ nU _e ) \ k

) _Vm = _Ue

thus equation (10) is obtained

Ujt) = k- ψ ^] ,

(13)

thus the required quotient according to equation (7).

4. Switchable filter with amplifier (Fig. 4)

The AC output voltage U _ax (t) of the quotient network 4 is decoupled by a high-pass filter R ^ C ₁ , amplified in V ₁ , converted in a further amplifier V ₂ to a current proportional to U _as (t) and a recorder calibrated in% 7 supplied. For the detection of very low-frequency modulated pulse train fluctuations (~ speed fluctuations) - here 0.01 Hz - R ^ C ₁ = 16 s is dimensioned; but that means z. B. with sequential operation of the device with several encoders of different mean speed an unreasonably long transient response of the device depending on R ₁ C _1. Date the time constant R ₁ C ₁ is reduced with T ₁ so that C ₁ can adjust to U _a " in a few seconds. At the same time, U _as (t ) is separated from the input of the high-pass filter by a low-pass filter R ₂ C _{2 that can be switched on with T 2.}

The operation of the device under frequently changing operating parameters (continuous or spontaneous changes in the long-term mean value U _am , exceeding the measuring range by U _a j, t)) requires a control of the device to avoid overloading the recording device and later inexplicable diagram recordings Display lock. As long as the pulse generator does not deliver a pulse train (machine standstill), the display by the flip-flop FF via the rest position of the mono-flip-flop MF via the connection of the OR gate R is blocked, i.e. T _{1 is} conductive and T _{2 is} blocked (the source of T ₁ is virtually on FO).

If the pulse repetition frequency of the pulse generator, which increases from 0 when the machine starts up, exceeds a predetermined value, the retriggerable mono flip-flop MF does not flip back, so that the mono flip-flop-side blocking of the FF is canceled via the R input. At the same time, however, the capacitor C _{x is} charged to U _n , via the impedance converter 7 and holds the device with the flip-flop FF via the charging current detector 7 _cl - D with the logic output Z ₁ , = 0 via R locked for so long until no more charging current flows through C _1. If C _{1 is} loaded, the logic signal I _n - 0 appears. The logic signal I _c2 = 0 appears when U _as (t) goes through 0. Both

s Signals are linked in the AND gate U and enable the flip-flop FF . This means that T _{1 is} blocked and T _{2 is turned} on after a delay Z.

A limit detector GWl generates a logic signal at its output when I / _as (() exceeds the limit of the MCiJ range of the device, represented by a threshold voltage U _GWl . A new blocking of the device can now only be initiated by means of the limit detector GWl - and if necessary via the logic signal / _fl * 0 in the sense described above

is maintained, U _as (t) exceeds a second (digitally adjustable) threshold voltage U _GW1 <U _6m . so the limit value detector GWl generates a logic signal at its output, which via a retriggerable mono flip-flop the fast pre-

2ü push of a recorder switches on. If the relative pulse train fluctuations or speed fluctuations with U _as (t) _exceed the threshold voltage U 0W2 several times per unit of time, an alarm signal is triggered.

5. Control and calibration generator

As an operative function testing and calibration of the instrument with artificially generated at the encoder defined pulse sequence variations is not possible, this function is performed by a built-in digital frequency-modulated pulse generator selectively to the input of F / V converter - can be connected - also during the actual measurements . Here, a quartz generator generates a pulse repetition frequency via a frequency divider with a finely graded digitally selectable division factor. A continuous digital change in the division factor in very small binary steps in a time-constant sequence between two digitally defined limits results in a quasi-linear triangular frequency modulation of the pulse repetition frequency with an absolutely defined frequency deviation. The stroke frequency is expediently chosen so that it is well below the limit frequency of the recorder.

"6. Technical data for an exemplary embodiment

With the device described above for measuring and registering relative frequency fluctuations

effects of a pulse train for a measuring range

= ± 10% the following outstanding data were achieved:

a) The formation of the quotient

over one

Range from 1 U _n , to ^ 40l / _m .

b) Measuring range of the fluctuation frequency 0.01 H2 to 100 Hz (- 3 dB) for f {t) > 300 Hz (for the definition of f (t) see equation 2).

c) Measuring accuracy over the quotient measuring range s ± 1% for / (t)> 1300 Hz.

For this purpose 2 sheets of drawings

Claims (8)

Patent claims: 1. Device for measuring and registering relative frequency fluctuations in a pulse train, in which a frequency-voltage converter and an electronic quotient network are connected in series, the quotient network being formed by a quadrupole with a non-linear characteristic curve, to which the fluctuation amplitude U and the mean value U _m Pulse train are supplied and are set in relation to one another by the quadrupole, as characterized in that the quotient network consists of an amplifier with a logarithmic characteristic, the output of which is a high-pass filter Bach connected, the time constant of which is automatically reduced when the long-term mean value U _n , am The output of the quotient network (4) changes, while at the same time the output AC voltage U _as (t) of the quotient network is automatically separated from the input of the high-pass filter by a low-pass blocking element connected upstream of the high-pass filter. 2. Apparatus according to claim 1, characterized in that the blocking element is an RC low-pass filter (R ₂ C ₂ ) , the time constant of which can be switched by means of a field effect transistor T ₂ . 3. Apparatus according to claim 1-2, characterized in that the high-pass filter is a CR element (C ₁ R ₁ ) , the time constant of which can be switched to lower values by means of a field effect transistor T _1. 4. Apparatus according to claim 1 to 3, characterized in that the display of the device when changes occur in the long-term mean value U _m for the duration of the resulting charge reversal of the capacitors C ₁ and C _{2 is} blocked. 5. Apparatus according to claim 1-4, characterized in that the low-pass filter is switched by means of the field effect transistor T ₂ later than the high-pass filter through the field effect transistor Ά- 6. Apparatus according to claim 1-5, characterized in that a display lock is provided which comes into operation when the fluctuation amplitude U _s (t) exceeds a limit value U _{CWl of} the measuring range. 7. Apparatus according to claims 1-6, characterized in that a further limit value switching device is provided which only releases the measured value registration for a defined time when the fluctuation _amplitude U _s (t) exceeds a digitally adjustable limit value U GW2. 8. Device according to claim 1-6, characterized in that that in addition a digital frequency-modulated calibration generator (8) for control and calibration is built in.