DE3008876A1 - Mechanical speed measurement circuit - uses speed to frequency conveyor and dual interval measurement cycle avoiding pulse interval inversion - Google Patents

Abstract

A circuit for determining mechanical speed involves a pulse transducer giving an output measurement pulse train with frequency proportional to speed and enables dynamic corrections, including at low speeds, despite l.f. noise. The difficulty of forming a reciprocal time value is overcome. As soon as a measurement train pulse begins a time pulse train count interval is started. After the number of clock pulses counted has reached a defined level the clock pulse-count is then continued until a further defined number of measurement pulses is received. The mechanical speed is then proportional to the ratio of the total number of clock pulses counted and the further number of measurement pulses counted in the second interval.

Description

Method and circuit arrangement for determining the

mechanical speed The invention relates to a method for determining the mechanical speed according to the preamble of the patent claim 1 and a circuit arrangement for carrying out this method according to the preamble of claim 2.

Pulse converters are used to measure the mechanical speed used, the output of which is a pulse train with a mechanical speed proportional frequency supplies. The demands on the information that go beyond the Pulse train to be obtained determine the nature of their processing.

The simplest way is based on counting the pulses in a constant Time interval. However, this very simple method is of no use whatsoever in the Pulse train contained information and is therefore suitable for from dynamic Point of view from less demanding static corrective titles or Corrections.

The use of a frequency-to-analog converter is of the dynamic type From an advantageous point of view, the static accuracy of this method is used can be increased with the help of a numerical correction channel. trouble occur at low speeds when the converter output (even at constant Speeds or revolutions) are burdened with considerable low-frequency interference signals that cannot be sifted out without a loss of dynamism.

The apparently perfect use of the information from the point of view the dynamics from is based on measuring the interval between two neighboring ones Impulses. To determine or determine the speed, a reciprocal value must be used Size can be formed, for example from a numerical circle or from a Microprocessor.

With a wide range of measured speeds and with The high accuracy required at the same time is also, for example, in the measurement the interval duration by counting clock pulses or hourly pulses in the range of 10 4 s with a relative accuracy of 10 ° to 10 it is difficult to count the clock pulses, the frequency of which in this case must be in the range from 10 to 100 znHz. aside from that If the measuring range is 1: 100, the word length of the reciprocal value is extended by two decades calculating circle.

It is therefore a task. of the invention, a method and a circuit arrangement z-tlr performing this procedure to indicate with which the ears pointed Disadvantages are avoided.

The method according to the invention for determining the mechanical speed eliminates these disadvantages mentioned and solves the task at hand in that with the moment of arrival of the pulse of the measuring pulse train a Interval of counting the pulses of a clock pulse train starts that from the moment in which the number of counted pulses of this clock pulse sequence is a preselected number n1 reached, counting the clock pulses until the moment of arrival of the very next k-th pulse of the measuring pulse train progresses, and that the measured mechanical Speed as proportional to the ratio of the total number n of counted Clock pulses to the number k of pulses of the measuring pulse train is evaluated.

What is particularly advantageous about the invention is that the speed is measured at an incidentally constant interval chosen to be the dynamics of the tax system are not devalued.

The speed is thus approximately constant in the invention Interval measured, which is chosen so that the dynamics of the control system not is devalued.

At least one pulse converter is used to determine the speed used, at the output of which is a measuring pulse train whose frequency is proportional to mechanical speed is.

In the drawing, for example, is a circuit arrangement for Implementation of the method according to the invention shown.

A control block 1 is with its second input 13 to the first Output 22 of a first counter 2, with its first input 12 at the first output 32 of a second counter 3, with its first output 14 at the second input 21 of the first counter 2, with its second output 15 connected to the first input 30 of the second counter 3 and with his third output 16 to the second input 53 of a divider 5 connected. The indicated inputs 10, 11 of the control block 1 are only used here to represent the numbers n1 of the clock or Hourly pulses and k of the measuring pulses. The first counter 2 is at its first input 20 to the output of a pulse sensor 8 and with its second output 23 to the first input 51 of the divider 5 connected. The second counter 3 is with his second input 31 to the output of a clock or hour pulse generator 4 and its second output 33 is connected to the third input 53 of the divider 5. The output 54 of the divider 5 is via the pulse converter 8 to a speed controller 7 connected.

At the moment of the arrival of the impulse to the first input 20 the measuring pulse sequence supplied to the first counter 2 begins the counting interval of the pulses the clock pulse train fed to the second input 31 of the second counter 3. from the moment at which the number of counted pulses of the clock pulse train the Number has reached n1, the counting of the clock pulses continues up to the instant continued, in which the further next, for example k-th pulse of the measuring pulse sequence arrives. A total of n pulses of the measuring pulse train are counted. The measured mechanical speed is then proportional to the ratio n: k, where this is processed by the control block 1 and the divider 5. If T is the interval duration between two adjacent pulses of the measuring pulse train and to is the interval between two adjacent pulses of the clock pulse train is - if T is much smaller than ntO is - the speed measured at an incidentally constant interval, that is chosen so that it does not devalue the dynamics of the tax system. Also for very sophisticated industrial control systems can range up to this interval 10 3 s. The use of clock pulse frequencies up to 10 mHz can then be used accuracy in area 10 4 ensure.

The information obtained in the divider 5 can be used in the speed loop of the control system either directly in numerical form or after conversion in the pulse converter 6 can be used in an analogous form. At constant speed this has in the Speed controller 7 introduced output signal of the pulse converter 6 no ripple and thus enables a significantly higher speed to be achieved. Simultaneously it is obvious that the word length of the divider 5 depends only on the target speed and does not depend on the measuring range.

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Claims (2)

Claims by means of a method for determining the mechanical speed by means of at least the pulse converter, at its output a measuring pulse train with a frequency proportional to the mechanical speed, thereby - that with the moment of arrival of the pulse of the Neßimpulssequence an interval of counting the pulses of a clock pulse train begins, - that of the Moment at which the number of counted pulses of this clock pulse train a selected number n1 is reached, counting the clock pulses up to the moment of the Arrival of the very next k-th pulse of the measuring pulse sequence advances, and - that the measured mechanical speed as proportional to the ratio the total number n of counted clock pulses to the number k of pulses in the measuring pulse train is evaluated. 2. Circuit arrangement for performing the method according to claim 1, .with a control block, counters, a clock pulse generator and a divider, thereby marked, - That the control block (1) with its second input (13) to the first output (22) of the first counter (2), with its first input (12) to the first output (32) of the second counter (3), with its first output (14) to the second input (21) of the first counter (2), with its second output (15) to the first input (30) of the second counter (3) and to its third output (16) is connected to the second input (52) of the divider (5), - that continues the first counter (2) with its first input (20) to the output of a pulse sensor (8) and with its second output (23) to the first input (51) of the divider (5) is connected, and - that the second counter (3) with its second input (31) to the output of the clock pulse generator (4) and to its second output (33) is connected to the third input (53) of the divider (5). Circuit arrangement according to Claim 2, characterized in - that the output (54) of the divider (5) via a pulse converter (6) to a speed controller (7) is connected.