3-dimensional pressure sensor
First Claim
1. A method of measuring shear forces and normal forces produced by an elastomeric object using a single sensor comprising the steps ofa) disposing at least one layer of piezoelectric material having two conductive surfaces and shear orientation such that generated piezoelectric voltage is sensitized in a single axis of a shear plane and converts mechanical stresses into voltage changes on a substrate material;
- b) covering said piezoelectric material with an elastomeric pad, said piezoelectric material, said substrate, and said elastomer pad comprising said sensor;
c) contacting said sensor with an elastomeric object;
d) stimulating said piezoelectric material ultrasonically and measuring a responsive ultrasonic signal indicating the amount of compression of said pad;
e) measuring tension and compression by the generation of opposite polarity voltages;
f) calculating normal forces by measuring the TOF of the signal and taking into account the stiffness of the elastomeric layer according to the formula
space="preserve" listing-type="equation">d.sub.1 -d.sub.2 =1/2c(t.sub.1 -t.sub.2) (1)
space="preserve" listing-type="equation">F=k(d.sub.1 -d.sub.2)=1/2kc(t.sub.1 -t.sub.2) (2) where;
d1=the original thickness of the pad over the elementd2=the thickness of the compressed padt1=time-of-flight of ultrasound through the noncompressed rubbert2=time of flight of ultrasound through compressed rubberF=compressing forcec=speed of sound in the elastomer, andk=elastomer stiffness;
g) measuring piezoelectric voltages generated by contact of the elastomeric article with the sensor;
H) calculating shear forces by combining ultrasonic output with piezoelectric output such that the outputs cancel, thereby providing a pure measure of shear force; and
i) resolving the shear vector by the polarity of the voltage generated.
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Accused Products
Abstract
Use of ultrasonic stimulation together with a pressure sensitive piezoelectric material in a sensor makes it possible to obtain three dimensional pressure measurements on an object in one operation. A piezoelectric material which is manufactured with a conductive surface on both sides, and shear orientation (i.e. piezo voltage produced by pressure on the material is sensitized in a single axis of the shear plane), and generates a proportional voltage when stretched or compressed (and tension and compression is sensed by the generation of opposite polarity voltages), makes it possible to measure normal forces by ultrasonic stimulation, and shear forces by the generation of piezo voltages, using the same sensor. In a preferred embodiment, multiple sensors are disposed in a high density array, and the various axes for the three dimensional measurements are obtained by varying the orientation of each sensor relative to an adjacent sensor. In an alternative embodiment, at least two differently oriented layers of film are included in each sensor.
48 Citations
9 Claims
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1. A method of measuring shear forces and normal forces produced by an elastomeric object using a single sensor comprising the steps of
a) disposing at least one layer of piezoelectric material having two conductive surfaces and shear orientation such that generated piezoelectric voltage is sensitized in a single axis of a shear plane and converts mechanical stresses into voltage changes on a substrate material; -
b) covering said piezoelectric material with an elastomeric pad, said piezoelectric material, said substrate, and said elastomer pad comprising said sensor; c) contacting said sensor with an elastomeric object; d) stimulating said piezoelectric material ultrasonically and measuring a responsive ultrasonic signal indicating the amount of compression of said pad; e) measuring tension and compression by the generation of opposite polarity voltages; f) calculating normal forces by measuring the TOF of the signal and taking into account the stiffness of the elastomeric layer according to the formula
space="preserve" listing-type="equation">d.sub.1 -d.sub.2 =1/2c(t.sub.1 -t.sub.2) (1)
space="preserve" listing-type="equation">F=k(d.sub.1 -d.sub.2)=1/2kc(t.sub.1 -t.sub.2) (2)where; d1=the original thickness of the pad over the element d2=the thickness of the compressed pad t1=time-of-flight of ultrasound through the noncompressed rubber t2=time of flight of ultrasound through compressed rubber F=compressing force c=speed of sound in the elastomer, and k=elastomer stiffness; g) measuring piezoelectric voltages generated by contact of the elastomeric article with the sensor; H) calculating shear forces by combining ultrasonic output with piezoelectric output such that the outputs cancel, thereby providing a pure measure of shear force; and i) resolving the shear vector by the polarity of the voltage generated.
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2. A method of measuring shear forces and normal forces produced by an elastomeric object using a single sensor array comprising the steps of
a) disposing a piezoelectric material having a conductive surface on both sides and an axis of orientation on a substrate material to provide a high density array of piezoelectric material; -
b) covering said array with an elastomeric pad, said piezoelectric material, said substrate and said pad comprising said sensor array; c) contacting said sensor array with an elastomeric object; d) measuring tension and compression by the generation of opposite polarity voltages; e) calculating the tension and compression using stress constants defining the relationship of mechanical stress and generated voltage; f) stimulating said piezoelectric material ultrasonically and measuring a responsive ultrasonic signal indicating the amount of compression of the pad; and g) calculating said normal forces by the measuring the TOF of the signal and taking into account the stiffness of the elastomeric layer according to the formula
space="preserve" listing-type="equation">d.sub.1 -d.sub.2 =1/2c(t.sub.1 -t.sub.2) (1)
space="preserve" listing-type="equation">F=k(d.sub.1 -d.sub.2)=1/2kd(t.sub.1 -t.sub.2) (2)where; d1=the original thickness of the pad over the element d2=the thickness of the compressed pad t1=time-of-flight of ultrasound through he noncompressed rubber t2=time of flight of ultrasound through compressed rubber F=compressing force c=speed of sound in the elastomer, and k=elastomer stiffness; h) measuring piezoelectric voltages generated by contact of the elastomeric article with the sensor array; i) measuring shear forces by combining ultrasonic output with piezoelectric output such that the outputs cancel thereby providing a pure measure of shear force; and i) resolving the shear vector by the polarity of the voltage generated.
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3. A method of measuring shear forces and normal forces produced by an elastomeric object using a single sensor array comprising the steps of
a) disposing two layers of a piezoelectric material having a conductive surface on both sides and an axis of orientation on a substrate material such that each layer of the piezoelectric material has a different axis of orientation to provide a high density array of stacked piezoelectric material; -
b) covering said array with an elastomeric pad, said piezoelectric material, said substrate and said pad comprising said sensory array; c) contacting said sensor array with an elastomeric object; d) measuring tension and compression by the generation of opposite polarity voltages; e) calculating the tension and compression using stress constants defining the relationship of mechanical stress and generated voltage; f) stimulating said piezoelectric material ultrasonically and measuring a responsive ultrasonic signal indicating the amount of compression of the pad; g) calculating said normal forces by the measuring the TOF of the signal and taking into account the stiffness of the elastomeric layer according to the formula
space="preserve" listing-type="equation">d.sub.1 -d.sub.2 1/2c(t.sub.1 -t.sub.2) (1)
space="preserve" listing-type="equation">F=k(d.sub.1 -d.sub.2)=1/2kc(t.sub.1 -t.sub.2) (2)where; d1=the original thickness of the pad over the element d2=the thickness of the compressed pad t1=time-of-flight of ultrasound through the noncompressed rubber t2=time of flight of ultrasound through compressed rubber F=compressing force c=speed of sound in the elastomer, and k=elastomer stiffness; h) measuring piezoelectric voltages generated by contact of the elastomeric article with the sensor array; i) calculating shear forces by combining ultrasonic output with piezoelectric output such that the outputs cancel thereby providing a pure measure of shear force; j) resolving the shear vector of both axes by the polarity of the voltage generated; and k) orientating each sensor in said matrix to have a different orientation from an adjacent sensor to provide multiple axes of orientation for shear forces. - View Dependent Claims (4)
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5. An apparatus for measuring shear forces and normal forces of an elastomeric object comprising
a) at least one sensor comprising a piezoelectric material, having conductive surfaces on both sides thereof and an axis of orientation, and generating an electrical voltage in response to pressure contact; -
b) an ultrasonic pulsing source in proximity to said at least one sensor scuh that said pulsing source is capable of stimulating an ultrasonic echo in said sensor; c) means for measuring normal forces on said sensor using an ultrasonic echo; d) means for measuring shear forces and normal forces on said sensor by measuring a voltage generated by said sensor; and e) means for subtracting normal forces measured by ultrasonic means from total forces measured by said generated voltage to provide a measure of pure shear forces. - View Dependent Claims (6, 7, 8)
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9. A method of measuring shear forces and normal forces in a tire footprint comprising the steps of:
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(a) providing a sensor comprising a layer of piezoelectric material having two conductive surfaces and shear orientation and converts mechanical stresses into voltage changes to provide a measure of shear forces created by said tire footprint; (b) using ultrasonic measuring means with said sensor for measuring normal forces of said tire footprint; (c) rolling a tire over said sensor; (d) measuring tension and compression created by said rolling tire using stress constants defining the relationship of mechanical stresses and generated voltage to measure said shear forces; and (e) mapping the results showing normal and shear pressures in a point by point analysis on a complete footprint in one operation.
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Specification