ROTARY SPEED SENSORS

Abstract

A speed detection device includes a comparator module, a sensor lead with a node connected to the comparator module, and a limit set module. The limit set module is connected to the sensor lead node and to the comparator by an upper limit lead and a lower limit lead to provide upper and lower limits to the comparator that vary according to amplitude variation in voltage applied to the sensor lead.

Claims

1. A rotary speed detector, comprising: a comparator module; a sensor lead with a node connected to the comparator module; a limit set module connected to the sensor node and the comparator module, wherein the limit set module is connected to the comparator module by an upper limit lead and a lower limit lead to provide upper and lower limits to the comparator module that vary according to an oscillating voltage waveform applied to the sensor lead.

2. A rotary speed detector as recited in claim 1, further including a buffer connected in series with the sensor lead node.

3. A rotary speed detector as recited in claim 1, further including rotation sensor connected in series with the sensor lead node.

4. A rotary speed detector as recited in claim 1, wherein the comparator module has a sensor input terminal, an upper limit input terminal, a lower limit input terminal, and a digital output.

5. A rotary speed detector as recited in claim 1, where the limit set module includes a constant voltage source coupled to upper limit lead and a lower limit lead by the limit set module.

6. A rotary speed detector as recited in claim 1, wherein the limit set module includes an inverting amplifier connected in series with the lower limit lead.

7. A rotary speed detector as recited in claim 1, wherein the limit set module includes a summing or maximum value selection module connected to a constant voltage source and coupled to the sensor lead node.

8. A rotary speed detector as recited in claim 7, further including a peak amplitude detection module connected in series between the sensor lead node and the summing or maximum value selection module.

9. A rotary speed detector as recited in claim 7, further including a root-mean-square (RMS) level detection module connected in series between the sensor lead node and the summing or maximum value selection module.

10. A rotary speed detector as recited in claim 1, further including a rotation sensor connected in series with comparator module by the sensor lead, the sensor including: a rotatable gear element having at least one tooth; a coil fixed relative to the gear element and electrically connected to the sensor lead; a pole piece extending through the coil; and a magnet connected to the power piece, wherein the coil is configured apply a voltage to the sensor lead that varies in amplitude according rotational speed of the gear element.

11. A rotary speed detector, comprising: a comparator module; a sensor lead with a node connected to the comparator module; a limit set module connected to the sensor lead node; an upper limit lead connecting the limit set module to the comparator module; a lower limit lead connecting the limit set module to the comparator module, wherein the limit set module includes a peak amplitude detection module connected to the sensor lead node, and wherein the limit set module includes a summing or max value selection module connected in series between the peak amplitude detection module and the comparator module.

12. A rotary speed detector as recited in claim 11, further including an inverting amplifier module connected in series between the summing or max value selection module and the lower limit lead.

13. A rotary speed detector as recited in claim 11, wherein the summing or maximum value selection module is connected directly to the comparator module by the upper limit lead.

14. A rotary speed detector as recited in claim 11, further including a constant voltage source connected to the summing or maximum value selection module.

15. A rotary speed detector, comprising: a comparator module; a sensor lead with a node connected to the comparator module; a limit set module connected to the sensor lead node; an upper limit lead connecting the limit set module to the comparator module; a lower limit lead connecting the limit set module to the comparator module, wherein the limit set module includes a root-mean-square (RMS) level detection module connected to the sensor lead node, and wherein the limit set module includes a summing or max value selection module connected in series between the RMS level detection module and the comparator module.

16. A rotary speed detector as recited in claim 15, further including an inverting amplifier module connected in series between the summing or max value selection module and the lower limit lead.

17. A rotary speed detector as recited in claim 15, wherein the summing or maximum value selection module is connected directly to the comparator module by the upper limit lead.

18. A rotary speed detector as recited in claim 15, further including a constant voltage source connected to the summing or maximum value selection module.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] So that those skilled in the art to which the subject disclosure appertains will readily understand how to make and use the devices and methods of the subject disclosure without undue experimentation, embodiments thereof will be described in detail herein below with reference to certain figures, wherein:

[0013] FIG. 1 is a schematic block diagram of an exemplary embodiment of a rotary speed detector constructed in accordance with the present disclosure, showing a rotation sensor electrically connected to a rotary speed detector;

[0014] FIG. 2 is a schematic block diagram of the rotary speed detector of FIG. 1, showing the a limit set module providing upper and lower limit waveforms that vary in magnitude according to rotational speed of a rotating shaft;

[0015] FIG. 3 is a schematic block diagram of the a rotary speed detector of FIG. 1, showing a limit set module having a peak amplitude detection module connected to a comparator module upper and lower limit leads; and

[0016] FIG. 4 is a schematic block diagram of another exemplary embodiment of a rotary speed detector of FIG. 1, showing a limit set module having a root-mean-square detection module connected to a comparator module upper and lower limit leads.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0017] Reference will now be made to the drawings wherein like reference numerals identify similar structural features or aspects of the subject disclosure. For purposes of explanation and illustration, and not limitation, a partial view of an exemplary embodiment of a rotary speed detector in accordance with the disclosure is shown in FIG. 1 and is designated generally by reference character 100. Other embodiments of rotary speed detectors and related methods in accordance with the disclosure, or aspects thereof, are provided in FIGS. 2-4, as will be described. The systems and methods described herein can be used in engine control systems for determining the speed of rotary components in aircraft gas turbine engines, though the present disclosure is not limited to engine control systems, gas turbine engines, or to aircraft in general.

[0018] With reference to FIG. 1, rotary speed detector 100 is shown. Rotary speed detector 100 is connected to a rotation sensor 10 that is configured and adapted to provide a signal including information relating to the rotational position of a shaft, e.g., shaft 2. Rotation sensor 10 includes a rotatable gear element 12 having one or more teeth 14, a coil 16, a pole piece 18, and a magnet 20. Gear element 12 is fixed relative to shaft 2 and rotates in concert with shaft 2. Coil 16 is fixed relative to gear element 12, is electromagnetically coupled to teeth 14, and is electrically connected to a sensor lead 102, which is electrically connected to rotary speed detector 100. Coil 16 is wrapped about a pole piece 18. Pole piece 18 is connected to a magnet 20 such successive passes of teeth 14 induce a voltage in coil 16 that oscillates according to the rotational speed R of shaft 2 about a rotation axis A. This causes coil 16 to apply an oscillating voltage to sensor lead 102.

[0019] With reference to FIG. 2, a block diagram of rotary speed detector 100 is shown. Rotary speed detector 100 includes a limit set module 104, a comparator module 106, a node lead 108, an upper limit lead 110, and a lower limit lead 112. Sensor lead 102 has a sensor lead node 114 that is connected in series between rotation sensor 10 and comparator module 106. Node lead 108 connects sensor lead node 114 with limit set module 104. Upper limit lead 110 and lower limit lead 112 each connect limit set module 104 with comparator module 106. A buffer 122 is connected in series with sensor lead node 114 between rotation sensor 10 and comparator module 106.

[0020] Comparator module 106 has a sensor input terminal 116, an upper limit input terminal 118, and a lower limit input terminal 120. Comparator module 106 also has an output terminal 123 that is configured an adapted to receive an output lead. Sensor lead 102 is connected to sensor input terminal 116 and applies thereto an oscillating voltage waveform 22 from rotation sensor 10. Upper limit lead 110 is connected to upper limit input terminal 118 and applies thereto an upper limit voltage waveform 24 generated by limit set module 104. Lower limit lead 112 is connected to lower limit input terminal 120 and applies thereto a lower limit waveform 26, also generated by limit set module 104.

[0021] Comparator module 106 is configured and adapted to apply a digital output voltage waveform 28 to output terminal 123. Digital output voltage waveform 28 is a binary waveform that toggles between a HIGH state and a LOW. In the illustrated exemplary embodiment digital output voltage waveform 28 toggles to a HIGH state when comparator module 106 detects that oscillating voltage waveform 22 crosses a predetermined level, e.g., zero voltage, with a positive slope, and toggles LOW when comparator module 106 detect that oscillating voltage waveform 22 crosses the predetermined level with a negative slope. The LOW state to HIGH states in a given time interval thereby correspond to passes of teeth 14 (shown in FIG. 1) by coil 16 (shown in FIG. 1), providing indication of rotational speed of shaft 2 (shown in FIG. 1).

[0022] Comparator module 106 is configured and adapted to generate digital output voltage waveform 28 from oscillating voltage waveform 22 using increasing hysteresis of oscillating voltage waveform 22. This generally entails comparing an input signal to a predetermined value that is adjusted according to the increasing amplitude of oscillating voltage waveform 22, which occurs as the rotational speed increases, to determine if the input signal is higher or lower than the predetermined value. The threshold level may be considered a dividing line whereby an input signal is considered either logic level HIGH if it is equal to or above the threshold level or logic level LOW otherwise. As will be appreciated by those of skill in the art in view of the present disclosure, oscillating waveforms such as oscillating voltage waveform 22 can include noise. Sources of such noise may include inaccuracies in gear tooth design or placement, electrical noise in the wiring harness or other structure connected to the sensor, and/or flux variation due to sensor vibration, shaft vibration, and/or vibration in other structure in proximity to the sensor. Such noise, or non-monotonic behavior, can cause additional toggle events between HIGH state and LOW states, which can cause errors in determination of the rotational speed of the shaft.

[0023] Comparator module 106 employs threshold adjustment to overcome the noise that can be present in oscillating voltage waveform 22. In this respect comparator module 106 receives from limit set module an upper limit voltage waveform 24 at sensor input terminal 116 and a lower limit voltage waveform 26 at lower limit input terminal 120. These waveforms are adjusted according to the peak amplitude of oscillating voltage waveform 22 and or the root-mean-square (RMS) level present in the signal. In addition to the increased hysteresis necessary to detect rotational speed at high shaft speeds, this provides noise rejection at low rotational speeds. It can also provide noise rejection when the noise is close to the fundamental frequency of the sensor output that filtering is ineffective due to excessive attenuation of the underlying signal.

[0024] With reference to FIG. 3, limit set module 104 is shown. Limit set module includes peak amplitude detection module 124, summing or maximum voltage selection module 126, a constant voltage source 128, and an inverting amplifier module 130. Peak amplitude detection module 124 is connected to sensor lead node 114 by node lead 108, and is configured to receive therethrough oscillating voltage waveform 22. Peak amplitude detection module 124 contains circuitry and/or software configured and adapted to determine the peak amplitude of the waveform dynamically, i.e. as the peak amplitude changes, and apply the peak as a peak voltage signal 30 to summing or maximum value selection module 126 through a peak amplitude lead 132.

[0025] Summing or maximum value selection module 126 is connected to peak amplitude detection module 124 through peak amplitude lead 132 and receives therethrough peak voltage signal 30. Peak amplitude detection module 124 is also connected to constant voltage source 128 through a contact voltage source lead 134 and receives therethrough a constant voltage signal 32. Summing or maximum value selection module 126 has circuitry and/or software that is configured and adapted to compare peak amplitude signal 32 to peak voltage signal 30, and based on the comparison (a) sum peak voltage signal 30 with peak amplitude signal 32 when peak amplitude signal 32 is below a predetermined value, or (b) select peak amplitude signal 32 when it is of a magnitude that is greater than the predetermined value.

[0026] Summing or maximum value selection module 126 thereafter applies the sum or selected voltage signal to upper limit lead 110, which provides sum or selected voltage signal directly to comparator module 1006, and lower limit lead 112, which inverts the sum or selected voltage signal using inverting amplifier module 130 such that an inverse of the sum or selected voltage signal is provided to comparator module 106. As will be appreciated by those of skill in the art in view of the present disclosure, this provides automatic hysteresis control for both high rotational speed, where the upper and lower limits increase in magnitude according to increasing rotational speed, and low rotational speeds, wherein the upper and lower limits remain fixed below a certain rotational speed as reflected in the amplitude of oscillating voltage waveform 22 (shown in FIG. 2).

[0027] With reference to FIG. 4, a rotational speed detector 200 is shown. Rotational speed detector is similar to rotary speed detector 100 (shown in FIG. 3), and additionally includes a limit set module 204 with an RMS level detection module 224. RMS level detection module 224 is connected to node lead 108 and receives therethrough oscillating voltage waveform 22. RMS level detection module 224 has circuitry and/or software that is configured and adapted to determine the amount of RMS error in the oscillating voltage waveform 22. As will be appreciated by those of skill in the art, RMS error oscillating voltage waveform 22 increases as rotational speed of shaft 2 decreases, increasing the likelihood of pulse generation by comparator module 106.

[0028] Based on the determined RMS in oscillating voltage waveform 22, RMS level detection module 224 applies either the amplitude of oscillating voltage waveform 22 to summing or maximum value selection module 126 of a predetermined voltage that is below a voltage provided by constant voltage source 128. This cause the upper limit voltage waveform 24 provided to comparator module 106 and the lower limit voltage waveform 26 to be fixed when rotational speed of shaft 2 (shown in FIG. 1) drops below a rotational speed where hysteresis thresholding is effective. As will be appreciated, this rotational speed varies according the cause(s) of the noise in oscillating voltage waveform 22, such as vibration, electrical noise in the sensor harness, and/or noise frequency by way of non-limiting example.

[0029] A method of determining rotary speed of a rotatable component, e.g., shaft 2 (shown in FIG. 1), includes receiving an oscillating voltage (e.g., oscillating voltage waveform 22 shown in FIG. 2), indicative of rotational speed of the rotatable component. Amplitude of the oscillating voltage is determined using a limit set module, e.g., limit set module 104 (shown in FIG. 2). When amplitude of the oscillating voltage waveform is below a predetermined value a hysteresis level is set according to a fixed reference voltage, e.g., peak amplitude signal 32 (shown in FIG. 3). When amplitude of the oscillating voltage waveform is above the predetermined value, the hysteresis level varies according to the amplitude of the oscillating voltage, as shown with peak voltage signal 30 (shown in FIG. 4). The hysteresis level is applied with the oscillating voltage waveform as upper and lower limits to a comparator, e.g., comparator module 1106, and rotational speed is determined by counting peaks in an output waveform, e.g., digital output waveform 28 (shown in FIG. 2) from the comparator over time.

[0030] It is contemplated that amplitude of the oscillating voltage waveform can be determined based on peak voltage of the oscillating voltage waveform, e.g., using peak amplitude detection module 124 (shown in FIG. 3). Amplitude of the oscillating voltage waveform can be determined based on RMS level of the oscillating voltage waveform, e.g., RMS level detection module 224 (shown in FIG. 4).

[0031] The methods and systems of the present disclosure, as described above and shown in the drawings, provide for rotary speed detectors with superior properties including rotational speed detection at low rotational speeds where the amplitude of the sensor output signal is low or noise present in the sensor output signal has a fundamental frequency that is close to the underlying positional signal. While the apparatus and methods of the subject disclosure have been shown and described with reference to preferred embodiments, those skilled in the art will readily appreciate that changes and/or modifications may be made thereto without departing from the scope of the subject disclosure.