This application claims priority to GB Application No. 1010497.4 filed 22 Jun. 2010, the entire contents of which are incorporated herein by reference.
The present invention relates to variable reluctance probes used for measuring the speed and torque applied to rotating shafts. Probes of this type are typically found in gas turbine engines or in gear boxes used in aircraft.
Variable reluctance sensors are used to monitor both the speed of rotating shafts and the torque loading on shafts in gas turbine engines and gear boxes connected to gas turbine engines. For example,
When a load is applied to a power transmission shaft it will twist. For a known modulus of elasticity and at a constant temperature, the amount of twist (A) is proportional to the torque transmitted. This basic principle is used to measure torque.
The assembly shown in
From
The distance between the phonic wheel teeth will be seen as the distance between the zero crossovers in the A/C signal produced by the variable reluctance sensor. The change in distance in the zero cross over will be directly proportional to the angle of the twist of the shaft (θ) and so the torque transmitted by the shaft. A typical clean signal waveform from a variable reluctance sensor sensing the passage of the teeth can be seen in
The same basic principle is equally applicable for the measurement of rotational speed via a phonic wheel. The time between the passings of adjacent teeth past a sensor can be measured to provide a signal from which rotational speed can be calculated.
Both the conventional type of variable reluctance sensor, where many turns of a conductive wire are wrapped around a magnetic pole piece, and the transformer type as described in U.S. Pat. No. 7,148,679, where a few turns of a primary turn of conductive wire are wrapped around magnetic pole piece, can be used.
The sensor of
As each tooth of the phonic wheels passes close to the front face of the pole piece there is a change in the magnetic flux experienced by the conductive wire 31, due to the change in the reluctance of the magnetic circuit consisting of the pole piece 30, the phonic wheel and the air gap between the two. The changing magnetic flux results in a variable current induced in the conductive wire 31, from which the timing of the passage of the teeth on the phonic wheels past the pole piece can be determined.
In both torque and speed measurement, it is important that the waveform produced by the variable reluctance sensor is very clean and there is no noise or additional modulations, known as microphony, on the signal waveform.
One major cause of noise in the output from variable reluctance sensors, producing the additional modulations or microphony, is vibration from the surrounding environment. Vibration can be created from many areas of a gas turbine engine and surrounding ancillary equipment, such as the power gear box where large intermeshing teeth create vibration, out of balance shafts, bearings and compressor/turbine blades and discs.
The reason that vibrations cause noise in the output signal is the affect that they have on the pole piece. Vibration in the sensor environment can cause stress in the pole piece that alters its magnetic permeability. The change of the magnetic permeability of a material when subjected to a mechanical stress is known as the Villari effect. The stress energy created in the pole piece causes strain, which affects the permeability and so alters the reluctance of the device. As the pole piece has conductive wires wrapped around it and a magnet or coil attached at one end, the change in reluctance will cause a change in the magnetic flux around the pole piece, inducing an additional electrical current in the conductive wire wrapped around the pole piece. This additional induced current is the source of noise or microphony in the output signal. This effect is more noticeable at high vibration frequency levels because of the greater rate of change of permeability of the pole piece.
A problem with existing sensors, as illustrated in
In a sensor as illustrated in
The encapsulation material does, to some extent, reduce the transfer of vibration to the pole piece, and epoxy resin as an encapsulation material has proven to be the most effective material. However, at high frequency and high temperature there is still significant noise in the sensor output as a result of environmental vibrations. One factor is that, at the high temperatures found in gas turbine engines, the epoxy resin used as an encapsulating material is relatively soft.
It is an object of the present invention to substantially reduce the sensitivity of variable reluctance sensors, suitable for use in gas turbine engines, to noise resulting from environmental vibrations.
The present invention is defined in the appended claims to which reference should be made. Preferred features of the invention are set out in the dependent claims.
In a first aspect, the invention comprises a variable reluctance sensor for sensing the speed or torque of a shaft in a gear box or gas turbine engine, comprising:
a magnetic pole piece;
a conductive wire wrapped around the pole piece;
a housing surrounding the pole piece, the housing having a front face and at least one side wall, wherein, in use, the front face is positioned proximate to an object to be sensed,
wherein the pole piece is rigidly fixed to the side wall of the housing.
By fixing the pole piece to the side wall of the sensor housing, strain in the pole piece as a result of external vibration is significantly reduced. The strain is effectively transferred to the side wall of the housing rather than along the length of the pole piece. Preferably, the pole piece comprises a longitudinal shaft proximate to the front face of the housing, wherein the conductive wire is wrapped around the longitudinal shaft, and a head end remote from the front face of the housing, wherein the head end is fixed to the side wall of the housing.
Preferably, the pole piece is rigidly fixed to a plurality of points on the housing. By connecting the pole piece to the housing at a plurality of points or over an extended area, the transfer of strain can be increased. “Rigidly fixed” in this context means more than simply held in place through an interference fit with other components of the sensor or with an encapsulation material. It requires a positive fixing means. The pole piece may be fixed to the side wall or side walls of the housing by any suitable means, such as welding, brazing or by using some mechanical fixing, such as a screw fitting. It is also possible to include a rigid intermediate structure between the pole piece and the housing to provide the rigid fixing. The pole piece is then directly fixed to the intermediate structure and the intermediate structure directly fixed to the housing. This may have advantages in the assembly of the sensor.
The pole piece may extend through the front face of the housing and it may be advantageous that the pole piece is not fixed to the front face of the housing, so as to minimise the transfer of strain from the front face of the housing. Whether a connection between the pole piece and the front face of the housing is required depends on whether a seal is required isolating the interior of the housing and the environment in which the sensor is operating.
Alternatively, or in addition, the front face of the housing may be made substantially less stiff that the side wall of the housing. By having a front face that is able to flex, less stress is exerted on the pole piece under external vibration.
It is important that the conductive wire does not move relative to the pole piece. A packing material, such as fibre glass tape covered in varnish, or an epoxy resin, may be provided around the conductive wire and the portion of the pole piece around which the wire is wrapped, to secure the wire relative to the pole piece.
The variable reluctance sensor may further comprise a permanent magnet within the housing and adjacent to the pole piece. In this case, typically, the pole piece has a front end adjacent to the front face of the housing and a rear end positioned adjacent to the permanent magnet, with the rear end fixed to the side wall of the housing. The permanent magnet may be rigidly fixed to a side wall to minimise relative movement between the magnet and the pole piece.
In a second aspect, the invention comprises a variable reluctance sensor for sensing the speed or torque of a shaft in a gear box or gas turbine engine, comprising:
a magnetic pole piece;
a conductive wire wrapped around the pole piece;
a housing surrounding the pole piece, the housing having a front face and at least one side wall, wherein, in use, the front face is positioned proximate to an object to be sensed,
wherein the pole piece extends through the front face of the housing and the front face of the housing is substantially less rigid than the side wall of the housing.
Optional or preferred features described in relation to the first aspect may equally be applied to the second aspect of the invention.
In a third aspect, the invention comprises a gas turbine engine comprising:
a rotating shaft;
a phonic wheel mounted to the shaft for rotating with the shaft; and
a variable reluctance sensor according to the first or second aspect, wherein the front face of the housing is positioned proximate to the phonic wheel.
Embodiments of the invention will now be described in detail, by way of example, with reference to the accompanying drawings, in which:
a is perspective, partially cut away, view of a phonic wheel assembly for torque measurement;
b illustrates a variable reluctance sensor positioned adjacent to a phonic wheel;
a is a schematic representation of the teeth of the phonic wheels of
b is a schematic representation of the teeth of the phonic wheels of
The basic arrangement for a variable reluctance sensor for detecting speed or torque in a gas turbine engine or gear box connected to a gas turbine engine has been described previously with reference to
As described above, the longitudinal strain in the pole piece results from vibration of the sensor assembly, and in particular is transferred to the pole piece both from the permanent magnet 32 and from the front face of the housing 33b. Typically, although the pole piece extends through the front face of the housing, it is attached to the front face of the housing by a welded or brazed joint. The pole piece is therefore effectively trapped between the front face of the housing 33b and permanent magnet 32.
As a result of these modifications, strain in the pole piece, resulting in the force exerted by the permanent magnet 72 is transferred to the side walls 73a of the housing, rather than all being concentrated along the longitudinal shaft 70b of the pole piece, as illustrated by arrows 75. This results in a significant reduction in the strain within the pole piece and hence a reduction in the noise in the output of the sensor. The fact that the front face of the housing 73b is more flexible, means that less force is applied to the pole piece from the front face of the housing. This also reduces noise in the output from the sensor.
The pole piece may be fixed to the front face 73b of the housing, for example by welding, if it is required to have a good seal so as to protect the interior of the housing from the outside environment. However, if a good seal is not required, the pole piece may advantageously not be connected to the front face 73b of the housing, so that the housing exerts no significant force on the pole piece when it vibrates.
The materials used to make the sensor shown in
The encapsulation material is a high temperature epoxy resin, a powdered material, or a ceramic paste or silicone rubber.
The permanent magnet may formed from any suitable material such as Samarium Cobalt, Alcomax™, Hycomax™, and Alnico™. The conductive wires are typically formed from insulated copper or copper alloy winding wire. The housing is formed from stainless steel.
In the embodiment shown in
Alternatively, other means of rigidly fixing the pole piece to the housing may be used, such as a screw fixing or a clamp fitting. The pole piece might also or alternatively be glued to the side walls of the housing.
In both the embodiment of
Variable reluctance sensors in accordance with the present invention are able to measure speed or torque parameters reliably in harsh, vibrating environments, both at low and high vibration frequencies, and at high temperatures. They are also protected from instantaneous shock loads which would otherwise induce strain in the pole piece.
Number | Date | Country | Kind |
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1010497.4 | Jun 2010 | GB | national |
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4444063 | Snowden et al. | Apr 1984 | A |
4829245 | Echasseriau et al. | May 1989 | A |
5744951 | Babin et al. | Apr 1998 | A |
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Entry |
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UK Search Report dated Sep. 16, 2010 for GB 1010497.4. |
UK Search Report dated Nov. 24, 2010 for GB 1010497.4. |
UK Search Report dated Mar. 23, 2011 for GB 1103608.4. |
Number | Date | Country | |
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20110308331 A1 | Dec 2011 | US |