Piezoelectric polymer laminates for torsional and bending modal control
First Claim
1. Apparatus for sensing and controlling complex motions in a mechanical structure comprising:
- an integrated distributed piezoelectric sensor/actuator for attachment to a mechanical structure including;
a laminate comprising at least four stacked laminae of piezoelectric material;
each of said lamina having top and bottom sides, a thickness, and a principal axis defining the direction along which the top side of the lamina will contract or expand relative to the bottom side of the lamina upon application of an electrical signal across the thickness of the lamina, and conversely defining the direction along which when the lamina is contracted or expanded, an electrical signal will be generated across the thickness thereof;
wherein a first pair of said at least four laminae have their principal axes skewed with respect to one another and include means to sense electrical signals generated across the thicknesses thereof in response to stress or strain applied thereto; and
,a second pair of said at least four laminae have their principal axes skewed with respect to one another and include means to supply electrical signals across the thicknesses thereof to impart bending motions to the second pair of laminae;
whereby,when the laminate is attached to a mechanical structure, both bending and torsional motions of the structure can be determined without signal processing from signals generated by the first pair of laminae, and bending and torsional motions can be generated in the mechanical structure by supplying electrical signals to the second pair of laminae.
1 Assignment
0 Petitions
Accused Products
Abstract
Laminates of polyvinylidene fluroride (PVDF) are employed as piezoelectric sensors and actuators which can sense and/or generate complex motions that include bending, stretching, and twisting components. The laminates can be attached directly to a mechanical structure whose motions are to be sensed and/or controlled. By skewing the principal axes of each of the lamina in the laminate with respect to one another, the laminate is responsive not only to bending motions, but to torsional motions as well. Surface electrodes are disposed on the top and bottom sides of each of the lamina to either sense voltage generated by the lamina in response to motion imparted thereto, or supply voltage to the lamina to induce motion therein. The shape of the surface electrode patterns can be varied to control the particular components of motion to which each of the lamina is responsive (e.g., bending modes). The polarization profile in each of the lamina can also be varied for this purpose. Mechanical oscillators and dampers can be constructed using the laminates.
142 Citations
54 Claims
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1. Apparatus for sensing and controlling complex motions in a mechanical structure comprising:
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an integrated distributed piezoelectric sensor/actuator for attachment to a mechanical structure including; a laminate comprising at least four stacked laminae of piezoelectric material;
each of said lamina having top and bottom sides, a thickness, and a principal axis defining the direction along which the top side of the lamina will contract or expand relative to the bottom side of the lamina upon application of an electrical signal across the thickness of the lamina, and conversely defining the direction along which when the lamina is contracted or expanded, an electrical signal will be generated across the thickness thereof;wherein a first pair of said at least four laminae have their principal axes skewed with respect to one another and include means to sense electrical signals generated across the thicknesses thereof in response to stress or strain applied thereto; and
,a second pair of said at least four laminae have their principal axes skewed with respect to one another and include means to supply electrical signals across the thicknesses thereof to impart bending motions to the second pair of laminae;
whereby,when the laminate is attached to a mechanical structure, both bending and torsional motions of the structure can be determined without signal processing from signals generated by the first pair of laminae, and bending and torsional motions can be generated in the mechanical structure by supplying electrical signals to the second pair of laminae. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13)
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14. Apparatus for sensing complex motions in a mechanical structure comprising:
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an integrated distributed piezoelectric sensor which includes; a laminate having at least a first and a second lamina of piezoelectric material;
each of said lamina having top and bottom sides, a thickness, and a principal axis defining the direction along which when the top side of the lamina is contracted or expanded relative to the bottom side of the lamina, an electrical signal will be generated across the thickness thereof;wherein, said first and second lamina have their principal axes skewed with respect to one another and include means to sense electrical signals generated across the thickness thereof in response to stress or strain applied thereto; whereby, when the laminate is attached to a mechanical structure, the torsional and bending motions of which are to be sensed, the lamina will generate electrical signals, from which the magnitude and direction of the torsional and bending motions can be determined without signal processing. - View Dependent Claims (15, 16, 17, 18, 19, 20, 21, 22, 23, 24)
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25. Apparatus for generating complex motions in a mechanical structure comprising:
- an integrated distributed piezoelectric actuator which includes;
a laminate having at least a first and a second lamina of piezoelectric material;
each of said lamina having top and bottom sides, a thickness, and a principal axis defining the direction along which the top side of the lamina will contract or expand relative to the bottom side of the lamina upon application of an electrical signal across the thickness of the lamina;wherein, said first and second laminae have their principal axes skewed with respect to one another and include means to apply electrical signals across the thicknesses thereof; whereby, when the laminate is attached to a mechanical structure, bending and torsional motions can be generated in the structure through application of electrical signals to the laminae. - View Dependent Claims (26, 27, 28, 29, 30, 31, 32, 33, 34, 35)
- an integrated distributed piezoelectric actuator which includes;
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36. Apparatus for sensing or generating particular components of motion in a mechanical structure comprising an integrated distributed piezoelectric sensor or actuator including:
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at least a first layer of polarized piezoelectric material for attachment to a mechanical structure, said piezoelectric material having top and bottom sides, and a thickness; and
,surface electrode means disposed on the top and bottom sides of said layer for either sensing an electrical signal generated across the thickness of the layer in response to stress and strain imparted to the layer from the motions of a mechanical structure to which the layer is attached, or supplying an electrical signal to the layer for imparting stress or strain thereto; said surface electrode means being shaped to control the particular components of motion to which the sensor or actuator is responsive; and
,the direction and magnitude of the polarization of said layer being nonuniform throughout the layer to further control the particular components of motion to which the sensor or actuator is responsive. - View Dependent Claims (37)
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38. Apparatus for sensing or generating particular components of motion in a mechanical structure comprising an integrated distributed piezoelectric sensor or actuator including:
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at least a first layer of piezoelectric material for attachment to a mechanical structure, said piezoelectric material having top and bottom sides, and a thickness; and
, said layer being divided into first and second sections;surface electrode means disposed on the top and bottom sides of said first and second sections of said layer for either sensing an electrical signal generated across the thickness of the layer in response to stress and strain imparted to the layer from the motions of a mechanical structure to which the layer is attached, or supplying an electrical signal to the layer for imparting stress or strain thereto; said surface electrode means being shaped to control the particular components of motion to which the sensor or actuator is responsive; and
,means to electrically connect the top surface electrode means of said first section to the bottom surface electrode means of said second section, and the top surface electrode means of said second section to the bottom surface electrode means of said first section;
whereby,the polarities of the first and second sections are opposite to one another so that the particular components of motion to which the sensor or actuator is responsive are further varied.
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39. Apparatus for sensing or generating particular components of motion in a mechanical structure comprising an integrated distributed piezoelectric sensor or actuator including:
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at least a first layer of piezoelectric material for attachment to a mechanical structure, said piezoelectric material having top and bottom sides, and a thickness; and
,surface electrode means disposed on the top and bottom sides of said layer for either sensing an electrical signal generated across the thickness of the layer in response to stress and strain imparted to the layer from the motions of a mechanical structure to which the layer is attached, or supplying an electrical signal to the layer for imparting stress or strain thereto; said surface electrode means being shaped to control the particular components of motion to which the sensor or actuator is responsive, and being separated into segments which can be selectively combined electrically to create a sensor or actuator that is responsive to more than one component of motion. - View Dependent Claims (41)
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40. Apparatus for sensing or generating particular components of motion in a mechanical structure comprising an integrated distributed piezoelectric sensor or actuator including:
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at least a first and a second layer of piezoelectric material for attachment to a mechanical structure, said piezoelectric material layers each having top and bottom sides, and a thickness; surface electrode means disposed on the top and bottom sides of each said layer for either sensing an electrical signal generated across the thickness of each of the layers in response to stress and strain imparted to the layers from the motions of a mechanical structure to which the layers are attached, or supplying an electrical signal to the layers for imparting stress or strain thereto; said surface electrode means being shaped to control the particular components of motion to which the sensor or actuator is responsive; means to attach said first and second layers of piezoelectric material together to form a laminate which is a sensor or actuator that is responsive to more than one particular component of motion. - View Dependent Claims (42, 53)
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43. Apparatus for sensing and controlling complex motions in a mechanical structure comprising:
- an integrated distributed piezoelectric sensor/actuator for attachment to a mechanical structure including;
a laminate having at least two laminae of piezoelectric material, each of said lamina having top and bottom sides, a thickness, and a principal axis defining the direction along which the top side of the lamina will contract or expand relative to the bottom side of the lamina upon application of an electric signal across the thickness of the lamina, and conversely defining the direction along which when the lamina is contracted or expanded, an electrical signal will be generated across the thickness thereof; wherein each of said lamina have their principal axes skewed with respect to one another and each include means to sense electrical signals generated across the thickness thereof in response to stress or strain applied thereto, and means to supply electrical signals across the thickness thereof to impart motions to each of the lamina;
whereby,when the laminate is attached to a mechanical structure, the complex motions of the structure can be sensed and controlled by the laminate without signal processing. - View Dependent Claims (44, 45, 46, 47, 48, 49, 50)
- an integrated distributed piezoelectric sensor/actuator for attachment to a mechanical structure including;
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51. A method for sensing and/or controlling complex motions in a mechanical structure comprising the steps of;
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forming an integrated distributed piezoelectric sensor/actuator from at least a first layer of piezoelectric material which generates an output, in response to complex motions imparted thereto, that does not require signal processing, and conversely which generates complex motions in response to an input signal; varying the polarization profile of the piezoelectric material layer to vary its response characteristics; attaching said integrated distributed piezoelectric sensor/actuator to a mechanical structure whose complex motions are to be sensed or controlled; and
,determining from the output generated by the sensor/actuator, the complex components of motion of a mechanical structure to which the sensor/actuator is attached, and/or supplying an electric signal to the sensor/actuator to impart complex motions to a mechanical structure to which the piezoelectric sensor/actuator is attached.
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52. A method for sensing and/or controlling complex motions in a mechanical structure comprising the steps of;
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forming an integrated distributed piezoelectric sensor/actuator which generates an output, in response to complex motions impared thereto, that does not require signal processing, and conversely which generates complex motions in response to an input signal;
said step of forming comprising;(a) forming a flexible laminate from a plurality of piezoelectric material layers so that at least two of said layers have principal axes which are skewed with respect to one another;
where the principal axis defines the direction along which a top side of a layer will contract or expand relative to a bottom side of a layer upon application of an electric signal across a thickness of the layer, and conversely defining the direction along which when the layer is contracted or expanded, an electrical signal will be generated across the thickness thereof;(b) disposing surface electrodes on opposite sides of each said piezoelectric material layers and shaping said surface electrodes to cause the laminate to be responsive to particular components of motion; and
,(c) varying the polarization profile of each said piezoelectric material layer to further vary the response characteristics of said laminate; attaching said integrated distributed piezoelectric sensor/actuator to a mechanical structure whose complex motions are to be sensed or controlled; and
,determinig from the output generated by the sensor/actuator, the complex components of motion of a mechanical structure to which the sensor/actuator is attached, and/or supplying an electrical signal to the sensor/actuator to impart complex motions in a mechanical structure to which the piezoelectric sensor/actuator is attached.
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54. A piezoelectric sensor/actuator that is responsive to selected bending modes in a mechanical structure comprising:
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at least a first layer of piezoelectric material having a length defining an x axis;
a width defining a y axis;
a thickness defining a z axis; and
top and bottom sides; and
,means to cause said sensor/actuator to be responsive to, or generate, only selected bending modes comprising first and second surface electrodes disposed on said top and bottom sides for either sensing an electrical signal generated across the thickness of the layer in response to stress and strain imparted to the layer by bending about the y axis, or supplying an electrical signal to the layer to cause it to bend about the y axis; each said surface electrode means having a shape defined by the area between a curve of a function F(x) and the x axis, where F(x) is directly proportional to the second derivative of a mode shape function φ
n (x), where φ
n (x) defines the displacement in the z direction of said layer as a function of x for a selected bending mode n, where n=1, 2, 3, etc.
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Specification