Rheometer for rapidly measuring small quantity samples

Information

  • Patent Grant
  • 6681618
  • Patent Number
    6,681,618
  • Date Filed
    Tuesday, October 1, 2002
    22 years ago
  • Date Issued
    Tuesday, January 27, 2004
    20 years ago
Abstract
The present invention relates to a miniature rheometer and improved force sensor elements which may advantageously be used in combination with the miniature rheometer. The miniature rheometer is adapted to determine rheological characteristics of materials which are provided in the form of small quantity samples. The force sensor element according to the present invention allows simultaneous measurement of a shear force and a normal force applied to the sensor element. Moreover, the force sensor may employ stress-optic material.
Description




TECHNICAL FIELD




The present invention relates to apparatus and methods for measuring physical properties of samples when subjected to an external shear force.




BACKGROUND




Producing materials having specific required properties is steadily gaining in importance and, hence, the field of combinatorial chemistry, which generally refers to methods for creating collections of diverse materials or compounds, commonly known as libraries, is steadily increasing and has revolutionized the process of drug discovery. Combinatorial chemistry enables researchers to rapidly discover and optimize useful materials, such as polymers, superconductors, magnetic materials, etc. In order to record the various properties of the materials obtained by combinatorial chemistry, it is necessary to precisely and efficiently determine the characteristics of the materials, preferably under varying environmental conditions. One important and useful characteristic is the behavior of a material, in particular of a polymer, when exposed to an externally-applied shear force. Instruments for measuring the response of fluids to applied shear are generally referred to as rheological instruments, which may be subdivided into indexers and rheometers. Indexers measure a quantity which is correlated with the rheological characteristics, but which is difficult to analyze in terms of intrinsic material properties. Although indexers can be assembled rapidly from commercially available components, the results of measurements carried out by means of such indexers are difficult to relate to results of measurements from other indexers, or to intrinsic material properties, without extensive calibration.




Rheometers, on the other hand, measure intrinsic material characteristics, giving them broad applicability. Such generality, however, comes at a price due to design costs and complexity which are dictated primarily by the need for well-defined static and dynamic test conditions. Moreover, these known rheometers require fairly large quantities of sample in the order of 500 mg so as to obtain the required accuracy in analyzing the samples. Such large quantity samples, however, are usually not provided by combinatorial synthesizing methods in which, generally, a large amount of differing samples of small quantity are produced.




Rheological measurements on sample materials, such as polymeric materials, are performed in their simplest geometry such that the sample is placed between two parallel plates of a design area separated by a gap of known distance, wherein the sample is sheared by applying a force to one of the plates while keeping the other plate fixed. This results in a displacement, i.e. a deformation of the sample confined between the plates, which can be characterized in terms of the shear stress and the shear strain. From these quantities and the dimensions of the sample, a shear modulus may be calculated. In general, the shear modulus is a function of the sample history, the shear strain and the strain rate. For polymeric materials, the temporal dependence of the shear modulus at constant stress typically exhibits four different regimes reflecting different relaxation mechanisms available to the polymer chain.




For sufficiently small deformations, most polymers exhibit linear viscoelastic behavior in which the shear modulus is independent of the shear strain. Theories of polymer dynamics generally explain the response of a chain in terms of normal modes, each having a characteristic frequency. The linear viscoelastic theory gives, then, the response of the material as a function of shear history. In measuring the mechanical property of a sample material, the sample is subjected to a varying force, e.g. a sinusoidal-varying force, and the resulting deformation, i.e. the response of the sample is observed. The frequency response of the sample may then be analyzed in accordance with viscoelastic theories to obtain information on the required characteristic of the material.




In order to perform these measurements with a high degree of accuracy, the rheological apparatus must be capable of producing a well-defined displacement within a specified frequency range. Additionally, since each frequency corresponds to probing the response of the sample material at a particular relaxation time, such measurements take a relatively long time period when the relaxation mechanism of the samples requires the employment of low frequencies. Hence, measuring a plurality of samples which may be produced by combinatorial chemistry is a very time-consuming and therefore very expensive procedure.




Moreover, the performance of accurate measurements requires the application of suitable sensor elements for detecting the shear stress in the samples. In order to obtain meaningful experimental results, the sensor elements have to be suitably designed so as to reflect the response of the sample to the applied shear strain without any interference or at least minor interference of the sensor element.




In view of the above-mentioned problems, it is an object of the present invention to provide apparatus and methods for rheological measurements which are capable of producing reliable measurement results for a plurality of small quantity samples within a short time period.




SUMMARY OF THE INVENTION




According to one aspect of the present invention, there is provided a miniature rheometer for analyzing a small quantity sample of a material of interest, wherein the rheometer comprises a first plate and a second plate, forming a pair of plates having a known geometry for confining the sample between the plates, said sample having a volume of 200 microliters or less; an adjusting device for adjusting the separation of the plates; an actuating element mechanically coupled to the first plate, which produces a shear strain within the sample by generating a defined small-scale relative motion of the first and second plates; a sensing element which outputs a position signal indicative for a displacement of at least one of the first and second plates; and a feedback circuit for providing force rebalance of the force, applied to the sample by the small-scale relative motion of the first and second plates, on the basis of the position signal, wherein an amount of force rebalance is a measure for the stress within the sample.




The miniature rheometer according to the present invention is suitably adapted to characterize combinatorial materials. In contrast to known instruments which generally require large sample volumes, typically 10-100 times the quantity produced by current combinatorial synthetic approaches, the present invention merely requires sample quantities having a volume of 200 microliters or less, or preferably 10-50 microliters, which are easily obtained by combinatorial synthesizing methods. Since measurements on such small sample volumes requires an accurate response of the rheometer on a corresponding small length scale, the present invention provides a sensing element and a feedback circuit which provide for force rebalance of the force that is applied to the sample in order to avoid the undesired inherent displacement of conventional force sensor elements due to shear forces exerted by the sample on the force sensor. Accordingly, the force balance may be controlled such that the present miniature rheometer exhibits an extremely high effective stiffness with respect to the sample, which in turn insures accurate measurement results, even at very small displacements.




In further embodiments, the position signal which is input into the feedback circuitry so as to adjust the force rebalance is obtained from the sensing element which may comprise a deformation-sensing element, a encoder means, or any other appropriate means suitable to determine the location of the plates with a spatial resolution that is substantially smaller than a minimal displacement of the plates as required for the desired measurement accuracy. The rheometer may comprise a sensor-actuating element that is mechanically coupled to the second plate so as to maintain the second plate at a predefined position upon reception of a driving signal from the feedback circuit. Alternatively, the actuating element may be driven from the feedback circuit such that the first plate maintains a desired displacement, wherein the second plate may be a fixed plate or may be kept at a fixed position.




In a further embodiment, the actuating element used as a shear strain producing means comprises a piezo-electric actuator so as to produce the small-scale relative motion. This allows the miniature rheometer to create small relative displacements of the plates while insuring easy control and configuration of the actuator.




In a further embodiment, the plates are disposable plates. The employment of disposable plates may considerably facilitate sample preparation and sample replacement after completion of a measurement run.




Advantageously, the deformation sensing element is coupled to the actuating element or the sensor-actuating element or to both and detects a deformation of at least a portion of the respective actuating element. The deformation sensing element measures the amount of deformation generated by the shear force applied to the sample. In this manner, the signal from the deformation sensing element may either be directly used as a measure for the shear force, or it may be supplied to the feedback circuit which adjusts the force exerted on the deformation sensing element by the actuating element or the sensor-actuating element so as to return the deformation sensing element to a predefined location, e.g. the undeflected state of the deformation sensing element.




In a further embodiment, two or more miniature rheometers may be arranged so as to form a parallel rheometer for simultaneously measuring two or more small quantity samples. To this purpose, a common control unit is provided which controls the shear strain producing means and the force sensors of the two or more miniature rheometers.




According to a second aspect of the present invention, there is provided a parallel rheometer for simultaneously analyzing material characteristics of two or more samples, wherein the parallel rheometer comprises first and second plates, respectively, having regions for receiving and confining said two or more samples, the first and second plates being moveable relative to each other; an actuator adapted to move the first and second plates relatively to each other for producing a shear strain within each sample; and at least one sensor associated with each region for simultaneously detecting shear stress within each sample.




As previously stated, standard rheological measurements often characterize materials according to their frequency response to an applied oscillatory shear force. Here, the frequencies of interest set the minimum measurement time required, which is typically three or four times the reciprocal of the frequency. Thus, by allowing the simultaneous measurement of a large number of samples by means of a parallel rheometer according to the present invention, a quick screening of a plurality of material samples (such as those produced by combinatorial synthetic approaches) is feasible. Moreover, according to the present invention, the minimum sample volume may be kept smaller than in known single-channel rheometers so as to permit measurements as a function of environmental conditions to use much faster condition change rates than are possible with large samples. To this end, the parallel rheometer as well as the miniature rheometer may comprise means for applying varying environmental conditions. Preferably, the environmental conditions to be varied, individually or simultaneously in any combination, at least include temperature, pressure at a fixed gas composition, composition of a gas atmosphere surrounding the sample, electric field, magnetic field, and time of application of one or more of the preceding quantities when adjusted to respective predetermined values. The means may be designed so as to allow the variation of the environmental conditions individually for each sample and/or simultaneously for a group of samples.




In a further embodiment, the shear stress detector comprises a micromachined sensor element at each sample position. This allows mass production of nearly identical sensor elements at low cost, wherein the required sample volume may easily be maintained relatively small due to the reduced sensor mass and increased sensitivity provided by micromachined devices.




According to a third aspect of the present invention, there is provided a rheometer, comprising:




a pair of plates spaced apart from each other by a defined distance for receiving and confining a sample therebetween, an adjusting means which adjusts the distance between the plates, a driving means coupled to at least one of the plates, which generates a relative motion between the plates without changing the distance, and a shear stress sensor, the shear stress sensor comprising a stress-sensing material of a defined stress-optic coefficient indicating one of birefringence and retardation of linearly polarized light passing the stress-sensing material, as a function of applied stress/unit path length.




The shear stress detector comprises a stress-optical sensor element which is insensitive to electric and magnetic fields, and thus allows to analyze samples within such fields without creating electrical noise.




According to a fourth aspect of the present invention, there is provided a sensor element for outputting a signal in response to a mechanical deformation applied to the sensor element, wherein the sensor element comprises: a sample plate arranged within an opening of a substrate; at least two tethers, one of each tether being attached to the sample plate, the other end of each tether being attached to the substrate so as to support the sample plate; a piezo-resistive portion in each of the tethers; and a wiring line formed on the tethers and the substrate, connecting each piezo-resistive portion with a corresponding contact pad formed on the substrate, wherein the piezo-resistive portion of one of said at least two tethers is adapted to generate a maximum change of its internal resistance when a shear force is applied to the sample plate, and wherein the piezo-resistive portion of the other one of said at least two tethers is adapted to generate a maximum change of its internal resistance when a force normal to the sample plate is applied.




As is generally known, shearing a viscoelastic material also generates a force along the shear gradient direction. Such forces are potentially of either sign and can be comparable in magnitude to the shear force. They can strongly affect the macroscopic flow properties of a material. At a minimum, rheometers must be sufficiently stiff in the shear gradient direction so that shear actuation results in as near a pure shear field as possible, and that any strain determination measures only the shear strain. By means of the sensor element provided according to the third aspect of the present invention, a shear force and a normal force applied to a sample can be detected simultaneously. This improves the accuracy of the measurement results due to separation of the total instrumental response into shear and normal force components and provides a more comprehensive picture of the response of the sample to applied shear.




This sensor element is particularly advantageous when used in combination with the above parallel rheometer.




Further advantages and objects of the present invention follow from the dependent claims and the detailed description of the preferred embodiments











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a schematic perspective view of a translational embodiment of the miniature rheometer according to the present invention.





FIGS. 2



a


-


2




c


are schematic top views of actuator elements shown in FIG.


1


.





FIG. 3

is a schematic perspective view of a rotational embodiment of the miniature rheometer according to the present invention.





FIG. 4

is a schematic top view of an actuator element as shown in FIG.


3


.





FIG. 5

is a schematic top view of a force sensor which may be used in the rotational embodiment as shown in FIG.


3


.





FIG. 6

is a schematic top view of a further force sensor, which may be used with the rotational embodiment as shown in FIG.


3


.





FIG. 7

is a schematic side view of an individual measurement element of a translational embodiment of the parallel rheometer using micromachined sensor elements.





FIG. 8

is a schematic top view of the individual measurement element of the translational embodiment of the parallel rheometer as shown in FIG.


7


.





FIG. 9

is a schematic perspective of a rotational embodiment of the parallel rheometer according to the present invention.





FIG. 10

is a schematic perspective view of an optical shear force sensing element which may be used in the parallel rheometer according to the present invention.





FIG. 11

respectively shows a further arrangement for optically detecting the shear force within a sample in a parallel rheometer according to the present invention.





FIG. 11A

shows an alternative arrangement for optically detecting the shear force within a sample in a parallel rheometer according to the present invention.





FIG. 12

schematically shows the structure of a sensor element which allows the simultaneous measuring of a shear force and a normal force applied to a sample, wherein the sensor element is preferably useable in a parallel rheometer according to the present invention.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




With reference to

FIGS. 1 and 2

, a translational embodiment, i.e. an embodiment that produces a translational displacement between a top surface and a bottom surface of a sample, of the miniature rheometer according to the present invention will now be described in detail.




In

FIG. 1

, merely a portion of the translational embodiment of the miniature rheometer of the present invention is shown. A moving plate


102


is mounted on a shaft


101


. Another plate


100


, which will also be referred to as the “fixed plate” even though this plate may be movable, is arranged parallel to the moving plate


102


. Plates


100


and


102


have surfaces which are arranged in an opposed relationship so as to be parallel to each other. The geometrical structure as well as the dimensions of the respective surfaces are selected so as to result in a desired configuration. Although the plates


100


and


102


are shown as circular elements, any other geometrical structure, such as squares or rectangles, etc., may be used for the surfaces of plates


100


and


102


. Plate


100


is also mounted on a shaft


103


. Preferably, the shafts


101


and


103


are made of a rigid, thermally insulating material. However, any appropriate material may be used, and in some cases electrical and/or thermal conductivity of portions of the shaft


101


and


103


may be desirable. Shaft


101


is attached to an actuating element


104


, which comprises a metal foil


105


which is of a rectangular shape. On at least one side of the metal foil


105


, a plate of piezoelectric material


106


is attached. In this embodiment two piezoelectric plates


106


are used with the metal foil


105


, however, it is also possible to use merely one piezoelectric plate on one surface of the metal foil


105


. Moreover, two or more piezoelectric plates may be used in accordance with design requirements. Actuating element


104


is attached to shaft


101


, preferably in a non-permanent manner, e.g. by providing a slit for receiving the actuating element


104


. This permits the use of disposable plates, which in turn facilitates measurements of samples that are difficult to remove from the plates. The actuating element


104


is further attached to a mechanical assembly, which may be provided in the form of clamping blocks


107


which comprise slits for receiving end portions of the actuating element


104


. A wiring assembly for applying a voltage to the piezoelectric plates


106


is also provided, but is not shown in FIG.


1


. Depending on the crystallographic orientation of the piezoelectric plates


106


, metal foil


105


may serve as a common electrode for applying a desired voltage to the plates


106


. Alternatively, metal foil


105


may be covered by a thin, electrically-insulating layer on the middle portion, where the piezoelectric plates


106


cover the metal foil so that a voltage may be applied to the piezoelectric plates


106


by means of the electrically conductive end portions of the metal foil


105


, which are clamped in place by a clamping blocks


107


, which then preferably may be made of an electrically conductive material so as to serve as electrodes.




In this embodiment, the assembly regarding the fixed plate


100


is identical to the structure referring to moving plate


102


, i.e. shaft


103


is attached to an actuating element


108


comprising a metal foil


109


with piezoelectric plates


110


on either side. Clamping blocks


111


are provided in order to clamp the actuating element


108


in place. Regarding electrical connections to the piezoelectric plates


110


, the wiring is configured in an analogous manner as previously described with reference to plates


106


.





FIG. 2



a


is a schematic top view of the actuating element


104


or of the actuating element


108


of FIG.


1


. For the sake of clarity only, the reference signs regarding actuating element


104


are shown. As the piezoelectric plates


106


are made of piezoelectric material, the plates


106


will undergo dimensional changes in response to an applied electric field. In

FIG. 2



a


, the piezoelectric plates


106


are arranged such that the application of a voltage of known polarity will cause a contraction of the this plate along the longitudinal axis as indicated by corresponding arrows in the figure.





FIG. 2



c


schematically shows the bent actuating element


104


, when the end portions thereof are clamped in place by the clamping blocks


107


. The application of a voltage to the clamped actuating element


104


produces a quadruple bend that is symmetric about the center portion of the actuating element. Reversing this voltage reverses the bend. Application of an alternating voltage to the actuating element


104


therefore results in reciprocating linear translation of the center of the actuating elements as is indicated by arrow


112


.




In operation, a sample of a material of interest, preferably a material produced by combinatorial synthetic approaches, is disposed in the gap between the moving plate


102


and the fixed plate


100


. In order to obtain well-defined experimental conditions, means may be provided to remove excess sample material, which may have accumulated during sample loading, from the edges of the plates. This is typically accomplished by providing a sharpened punch which translates and/or rotates along the plate edges so as to cut away excess material which extends beyond the edges of the plates. After having arranged the samples, which can be prepared by molding or otherwise forming samples to the dimensions of the plates


100


and


102


, the plates


100


and


102


are translated so as to be brought into contact with the formed sample. For this purpose, means are used which is not shown in the figures, but, which may, as the person skilled in the art will readily appreciate, be any appropriate mechanical assembly used in this field for translating the plates along a line normal to the opposing surfaces of the plates, so as to correctly adjust and define the distance of the gap. Alternatively, material may be placed on one plate and the other plate may be translated to a defined relative gap distance in order to mold specimens of known thickness. In this case, excess sample material is removed as previously pointed out.




Next, a defined voltage is applied to the actuating element


104


, preferably an alternating voltage with known rate and amplitude, so as to achieve a desired displacement of the middle portion of the actuating element


104


, as has been explained with reference to

FIGS. 2



a


-


2




c


. Thus, plate


102


which is coupled to the middle portion of the actuating element


104


by the rigid shaft


101


is also reciprocally displaced.




As previously mentioned, the actuating element


108


may be constructed in the same way as the actuating element


104


. In this embodiment, the actuating element


108


serves as a force sensor detecting the force which is required to hold plate


100


in place. For this purpose, preferably one of the piezoelectric plates


110


acts as an actuating element, whereas the other one of the piezoelectric plates


110


serves as a deformation sensor element. As can be readily appreciated, both piezoelectric plates


110


may serve as an actuating element and an additional deformation sensor element. The deformation sensor element may be a piezoelectric plate or a conventional mechanical deformation sensor, such as a strain gage, attached to actuating element


108


. The middle portion of actuating element


108


will be displaced in response to the shear force applied to the sample confined between the plates


100


and


102


. This displacement is detected by one of the piezoelectric plates


110


or, alternatively, by an additionally applied deformation sensing element, and is output as an electrical signal to a feedback circuitry which is not shown in the figures. The feedback circuitry, in turn, will supply a voltage to the piezoelectric plate


110


which serves as an actuating element, so as to generate a force which opposes the shear force applied by the sample to the plate


100


. Accordingly, the feedback circuitry may be controlled such that the actuating element


108


, and thus the plate


100


, may be maintained in an undeflected state or any desired position when an offset voltage is added to the voltage supplied to piezoelectric plate


110


. Advantageously, the voltage applied to the piezoelectric plate


110


, which serves as an actuating element, may also serve as an output of the force sensor for determining the shear force within the sample. In comparison with traditional force sensors, this “force rebalance” sensor is exceptionally stiff, i.e. the fixed plate


100


remains fixed for a wide range of applied shear forces, and hence it is possible to accurately determine the shear strain, i.e. the difference in the lateral position between the moving plate


102


and the fixed plate


100


.




The output of the force sensor, i.e. the actuating element


108


, may then be processed in any desired manner, i.e. the voltage obtained from the force sensor may be amplified, converted into digital signals, stored in a corresponding memory, or processed by a microprocessor so as to receive required force-displacement curves, which can be related to various rheological or mechanical characteristics of the sample, wherein the dimensions of the plates


100


and


102


are taken into account. In a typical application for polymeric materials, the moving plate


102


executes sinusoidal varying motions with frequencies from 0.01-1000 rad/s with an amplitude of, at most, 1% of the spacing between the plates


100


and


102


. The sinusoidally-varying signal is observed at the force sensor, wherein the ratio of force waveform amplitude to the displacement waveform amplitude is related to the modulus of the material at that frequency. The existence of a difference in phase between the force and displacement waveforms implies that this modulus may be represented as a complex quantity. The real part of this complex modulus corresponds to the “elastic” or “storage” modulus of the viscoelastic material; the imaginary part corresponds to the “viscous” or “loss” modulus.




Although the above embodiment is described using the piezoelectric actuator


104


, it is also possible to employ any appropriate means for displacing the sample, such as a motorized stage, which then may preferably include a second force sensor for determining any force exerted along a line joining the centers of the moving plate


102


and the fixed plate


100


when the plates are positioned above one another. This type of force is usually referred to as normal force. A variety of force sensors are suitable for this purpose, in particular the piezoelectric force sensor as described above.




With reference to

FIGS. 3 and 4

, a further embodiment is described which is capable of generating a rotational displacement with respect to the surfaces of a small quantity sample.

FIG. 3

shows a perspective schematic view of a rotational embodiment of the present invention.




Between a moving plate


300


and a fixed plate


302


, a small quantity sample of a material to be characterized may be arranged. Regarding the preparation of the sample and adjusting the distance between the plates


300


and


302


, the same considerations as given with respect to the translational embodiment shown in

FIG. 1

also apply in this case. Moving plate


300


is mounted on a shaft


301


which, in turn, holds an actuating element


304


. Actuating element


304


is comprised of a metal foil


305


of rectangular shape. Attached to metal foil


305


are four piezoelectric plates


306


, wherein two of the piezoelectric plates


306


are arranged on one surface of the metal foil separated by the shaft


301


and the other two of the piezoelectric plates


306


are arranged on the other surface of metal foil


305


. Thus, two of the respective piezoelectric plates


306


are arranged in an opposed relationship with metal foil


305


disposed in-between. The metal foil


305


is clamped in place by a mechanical assembly provided as clamping blocks


307


.





FIG. 4

shows a schematic top view of the actuating element


304


. Similarly, as already explained with reference to

FIGS. 2



a


-


2




c


, two opposing piezoelectric plates


306


sandwiching the metal foil


305


are electrically connected to a voltage supply in such a way that application of a voltage leads, for example, to an expansion of the upper piezoelectric plate and a contraction of the lower piezoelectric plate on the right side of

FIG. 4

, and the piezoelectric plates


306


on the left side are accordingly wired so as to exhibit the inverse behavior. Thus, a central axis of the metal foil perpendicular to the drawing plane of

FIG. 4

is subjected to a rotational displacement.





FIG. 5

shows a schematic top view of the torque sensor


308


. The shaft


303


, which may be made of a thermally insulating material, is attached, preferably in a non-permanent manner so as to permit the use of disposable plates, to at least two piezoelectric plates. In the present case, however, four piezoelectric plates


309


are employed and are attached to the surface of the shaft


303


, such that one end of each piezoelectric plate


309


is tangential to the surface of the shaft


303


. The other end of each piezoelectric plate is tethered to the rigid support


311


. The crystal structure of plate


309


is aligned such that applying a voltage across the plate causes the greatest dimensional change along the line tangential to the shaft


303


. As is shown, the piezoelectric plates


309


are preferably aligned along opposite sides of the shaft


303


so that the net torque resulting from the application of a voltage across the piezoelectric plates does contain a component which would tend to rotate the shaft out of its un-energized orientation.




The torque sensor


308


further contains a sensing element, in this case in the form of the other two of the piezoelectric plates


309


. The sensing element may, however, be any conventional strain gage or piezoelectric element which generates a signal upon rotation of the shaft


303


. A feedback circuit which is not shown in the figure monitors this signal and adjusts the voltage applied to the piezoelectric plates


309


, which act as an actuating element so as to rebalance the force applied to the shaft


303


and to return the shaft


303


to the un-rotated position or any desired position when a corresponding offset voltage is added to the voltage supplied to the piezoelectric plates


309


. Advantageously, this voltage may also serve as a measure of the torque at the shaft


303


.




As in the case of the translational embodiment, this design is exceptionally stiff so that the fixed plate


302


remains fixed for a wide range of supplied shear forces. Hence, the torque sensor as described above permits the shear strain, i.e. the difference in angular position between the moving plate


300


and the fixed plates


302


, to be accurately determined.





FIG. 6

shows an alternate form of the torque sensor. In this alternative embodiment, the torque sensor


308


comprises two or more piezoelectric assemblies, each consisting of at least one piezoelectric plate


319


bounded to a metal foil


315


, which are attached to the surface of the rigid shaft


303


such that one of the edges of the foil is parallel to the axis of the shaft


303


and that the other edge of the foil lies along a line perpendicular to the axis of the shaft. The edge of metal foil


315


opposite the edge in contact with shaft


303


is clamped in place by means of the rigid support


311


. In the embodiment described with reference to

FIG. 5

, applying a voltage to the piezoelectric plates produces the expansion or contraction of the assembly along a line tangential to the shaft


303


, resulting in a torque. In this alternative embodiment, applying a voltage to the piezoelectric assembly comprising the piezoelectric plate


319


and metal foil


315


produces the buckling of the metal foil


315


and thus the rotation of the “shaft end” of the assembly about the “clamped end”, also resulting in a torque being applied to the shaft


303


. In this embodiment, four piezoelectric assemblies, each comprising a piezoelectric plate and a metal foil are employed. As it will readily be appreciated, more than one piezoelectric plate


319


per piezoelectric assembly may be used. Moreover, any number of piezoelectric elements may be employed, wherein advantageously at least one of the piezoelectric assemblies may be used as a deformation sensing element in combination with a feedback circuit so as to maintain the shaft


303


on its un-rotated position, thereby providing an exceptionally stiff torque sensor element.




Sample preparation and operation of the rotational embodiment is carried out in a similar way as described with reference to the translational embodiment. Although moving plate


300


and fixed plate


302


have been described as plates with flat surfaces, any appropriate geometry of the plate surface may be employed. For example, one of the plates may consist of a cone of known apex angle, which is well-known in the art as “cone and plate” geometry.




Furthermore, as already pointed out with reference to the translational embodiment, the shafts


301


and


303


are preferably made of a rigid, thermally insulating material so that varying the temperature of the sample disposed between the plates


300


and


302


would not be affected by the shafts


301


and


303


coupled to actuating element


304


and torque sensor


308


, respectively. Moreover, the shafts


301


and


303


are preferably attached to the actuating element and the sensor element in a non-permanent manner so as to permit the use of disposable plates, thereby increasing the speed of sample replacement.




In a further variation, which is not shown in the figures, the rheometer comprises a first plate that is mechanically coupled to an actuating element such as actuating element


104


as previously described with reference to FIG.


1


. However, any other appropriate actuating element which allows a translational or rotational displacement between the first and the second plates may be used. A sensing element such as a deformation sensing element as described with reference to

FIGS. 1-6

may be employed to output a signal to a feedback circuit in response to the displacement of the first plate. The feedback circuit, in turn, outputs a voltage to the actuating element so as to return the actuating element to a predefined position, thereby effecting a force rebalance of the force applied to a sample confined between the first and second plates. The voltage provided to the actuating element may serve as an indication of the shear stress within the sample. As can be readily appreciated, the second plate can be maintained at a fixed position, either by a second actuating element coupled to the second plate, or a fixed support holding the second plate. While the former alternative provides for the possibility to perform measurements as described with reference to

FIGS. 1-6

and in a way as described in this paragraph, with the same apparatus, the latter alternative obviates the necessity for a second actuating element.




Moreover, the displacement can be detected by any suitable encoder means, such as an optical sensor, etc. to provide the position signal for the feedback circuit. Furthermore, all of the embodiments as described above may additionally comprise an environmental condition controller


350


(e.g., an environmental chamber) as shown in

FIG. 1

, so as to vary physical properties such as pressure, gas composition of an atmosphere surrounding the sample, temperature, electric and magnetic fields by providing, for example, electrodes and coils providing an electrical and magnetic field across the sample, etc. In addition, two or more of the above embodiments may be combined to form a rheometer “array” or a “parallel rheometer”, wherein advantageously a central control unit is provided so as to monitor and control the performance of individual rheometer elements of the rheometer array. Thus, a large number of small quantity samples may be characterized within a short time period, wherein the exceptionally stiff force sensor elements provide for accurate measurement results, even for the small scale displacements required for these samples.




Next, with reference to

FIGS. 7-12

, a further embodiment of a rheometer is described which allows simultaneous measuring of a plurality of samples.





FIG. 7

shows a schematic cross-sectional side view of an exemplary embodiment of the parallel rheometer of the present invention. In

FIG. 7

, a parallel rheometer


700


comprises a shear plate


701


which may contain, at predefined locations, raised regions


702


of known dimensions. Samples


703


are disposed between the shear plate


701


and a fixed plate


704


at the predefined regions. In this embodiment, the fixed plate


704


is made of an appropriate substrate carrying corresponding micromachined sensor elements. However, any appropriate fixed plate, preferably made of a rigid material such as aluminum or stainless steel, may be employed. The shear plate


701


and a fixed plate


704


are arranged parallel to one another with typical plate separations at the predefined regions of under 1 mm. With each predefined region, i.e. with each sample, there is associated a sensor element


705


in order to detect a force applied to the sensor element


705


by the shear plate


701


via the sample


703


. Although in

FIG. 7

a micromachined silicon force sensor is shown as the sensor element


705


, any appropriate sensor may be employed, including those sensor elements that are described later with reference to

FIGS. 10-12

. The sensor element


705


has been micromachined in a silicon substrate, however any appropriate material such as silicon nitride and silicon dioxide may be used for the fixed plate


704


and the sensor elements


705


.





FIG. 8

shows a schematic top view of one rheometer element with shear plate


701


removed. The sample


703


is placed on a rectangular silicon plate of the force sensor element


705


. The rectangular plate is attached to the fixed plate


704


, i.e. in this case a silicon substrate, by means of four tethers


706


. The tethers


706


are equipped with piezoelectric material or any other appropriate means for sensing a deformation of the tethers


706


.





FIG. 9

is a schematic perspective view of a further embodiment of the parallel rheometer according to the present invention. In

FIG. 9

, a fixed plate


904


comprises predefined regions


902


for receiving a sample of a material of interest. An array of test fixtures


901


is movably mounted on a means which is not shown in the figure, so that the test fixtures


901


may be lowered onto the predefined region


902


and positioned at a known distance from the fixed plate


904


. The text fixtures


901


acting as actuating elements may have any appropriately structured surface so as to define a required shape of the actuator-sample contact. In

FIG. 9

, a cone-and-plate geometry is shown in which the actuator is a cone of known apex angle. Other geometries, however, such as a parallel plate geometry in which the actuator is a flat disk parallel to the sample surface, may be employed as well. As in the previously-described embodiment, entrainment of viscous fluids is sufficient to keep the samples confined within a column capped by the actuator and the raised regions on the fixed plate


904


. The test fixtures


901


are individually coupled to respective motors


910


via respective encoders


911


. Advantageously, the predefined


902


contain respective force sensor elements.




Again referring to

FIGS. 7 and 8

, a strain field is generated across each sample by attaching the shear plate


701


to a translation stage


710


. This translation stage


710


moves in the plane of the plate-sample contact at a controlled rate so as to approximate a sinusoidal displacement of a required amplitude and frequency. The fixed plate


704


remains fixed in position, resulting in a shear field extending through each sample. Appropriate translation stages providing the required displacement with appropriate amplitude and frequency are well-known to those skilled in the art.




In a further embodiment, a micromachined electrostatic drive can be associated with each sample, thereby permitting independent control of the strain field for each sample for extremely small displacements. Such actuators are preferably fabricated from silicon, silicon nitride, or any other suitable materials.




In the embodiment described with reference to

FIG. 9

, the motors


910


are actuated to provide a rotational displacement which may be provided to the samples in the form of a sinusoidal displacement of a desired amplitude and frequency or in the form of a continuous, i.e. a non-reciprocating shear at a defined shear rate. Compared to the translational embodiment described with reference to

FIGS. 7 and 8

, the rotational embodiment permits measurements under steady, shear conditions and can also be configured to operate as a controlled stress rheometer, as will be described below.




The translational embodiment as well as the rotational embodiment includes a shear stress sensor at each sample position. One version of this sensor element is described with reference to

FIGS. 7 and 8

and consists of a micromachined silicon rectangle which is tethered to the surrounding silicon substrate by four micromachined silicon tethers. The surface of the rectangle lies in the plane of the surrounding silicon surface. Applying a shear stress to this rectangle by any of the means as described above generates a piezoelectric response in the four silicon tethers which can be detected by conventional electronic means such as a resistance bridge. Any variations in the geometry of this sensor element may be performed so as to permit it to be optimally used in all of the embodiments described above, i.e. the number of tethers, the shape of the silicon plate for receiving the sample, the location of the individual tethers, etc. may be adapted to the type of displacement required.




Although the operation of the embodiments of the parallel rheometer according to the present invention is described by means of a sinusoidal reciprocating motion in which, for example, an external processor directs the translation stage attached to the shear plate


701


, or individually directs the micromachined electrostatic actuators, or individually directs the motors


910


to execute periodic motion in the plane of the plate-sample contact, other types of displacement such as triangular displacement of known amplitude and frequency, in which the strain rate is constant except at the turning points of the motion, and a motion which approximates a square wave of known amplitude and frequency may be employed as well. The raw data obtained from the sensor elements consists of the shear stress as a function of time and may be reduced and/or processed so as to yield a single amplitude for the shear stress waveform for each sample, wherein the data processing may be performed sequentially as well as in a parallel manner, depending on the computational ability of corresponding signal processing means. At any rate, signal processing speed is high compared to the mechanical time constant involved in the response of the sample so that a “quasi”-parallel output of measurement results is obtained, even if the sensor signals are sequentially processed.




It is also possible that the samples are subjected to a step shear and the resulting strain is determined as a function of time. This may be accomplished by providing the square wave displacement described above. Moreover, the embodiments described above may also be operated in a controlled stress mode. In this case, an external processor directs the actuator, i.e. the shear plate


701


, the micromachined actuators, or the motors


910


, to move so as to produce a certain shear stress within each sample. The displacement required to produce this stress is recorded with the aid of appropriate means, such as encoders


911


. As before, the raw data consists of the displacement as a function of time which may be processed in any desired manner.




In other embodiments, the parallel rheometer of this invention preferably includes means for controlling and changing environmental conditions. This may be accomplished by mounting the embodiments in a temperature-controlled environment (not shown in the figures), permitting measurements to be made as a function of temperature, as a function at one or more temperatures, as a function of one or more temperature ramp rates, or as a combination of two or more of the preceding measurement criteria. In this case, temperature sensing can be provided by a thermocouple, thermistor or any other appropriate temperature-sensitive element attached to the shear plate or the fixed plate. Moreover, a thermocouple may be attached to each sensor or a standard micromachined resistor may be associated with each sensor.




Moreover, the embodiments of the parallel rheometer may be mounted in a pressure-tight enclosure (not shown in the drawings) permitting measurements to be made as a function of pressure, as a function of time at one or more pressures, as a function of pressure change rate, or as a combination of two or more of the preceding measurement criteria. Preferably, the enclosure is fitted with a purge valve enabling variation of gas composition and permitting measurements to be made as a function of composition, of time at a given composition, as a function of composition change rate, or as a combination of two or more of these criteria.




Moreover, either the shear or the sample plate may be fitted with one or more or an array of electrodes which serve to generate an electric field across each of the samples or across the samples as a whole. Measurements may be made as a function of field amplitude, field frequency, the rates of change of these two quantities, time at a given value of these two quantities, or a combination of two or more of these criteria.




In further variation, either plate can include one or more or an array of coils which generate a magnetic field across each sample. Alternatively, the entire parallel rheometer may be placed between the poles of a large magnet or a pair of Helmholtz coils. In this case, the devices surrounding the sample, i.e. the shear plate


701


and the fixed plate


704


or


904


have to be constructed of a non-magnetic material in order to avoid eddy currents associated with the motion of the plates. Again, measurements may be made as a function of field amplitude, field frequency, the rates of change of these two quantities, time at a given value of these two quantities or a combination of two or more of these criteria.




Preferably, in the embodiments having electrodes or coils generating a magnetic field, a force sensor element may be employed that is immune to electromagnetic noise, such as the sensor elements described below. However, the electronic sensor as described above with reference to

FIGS. 7 and 8

may, nevertheless, be used as well.




Furthermore, in another embodiment, some or all of the environmental conditions delineated above may be varied simultaneously.




Next, a variety of force sensor elements are described which may be used in a rheometer, such as the above-described miniature rheometer and the parallel rheometer of the present invention, or any other appropriate rheometer known in the art.




Some of the sensor elements described below and referred to as “stress-optic” employ a material with a known stress-optic coefficient. This coefficient describes the birefringence, or anisotropic retardation of linearly-polarized light, of a material as a function of the applied stress per unit path length.





FIG. 10

is a schematic perspective view of the first embodiment of a stress-optic sensor according to the present invention. In

FIG. 10

, an optical fiber


1001


is attached to a block of stress-optic material


1002


. The bock


1002


is made of suitable sensor material, including transparent plastics such as polymethyl methacrylate, suspensions of liquid crystals in a polymeric matrix, and certain silica glasses. A fixed plated


1003


, preferably made of a rigid material such as stainless steel or aluminum is attached to the block


1002


in order to receive a sample. Opposed to fiber


1001


is a second fiber


1004


which is optically coupled to a detector element


1005


. Fiber


1001


serves as an input fiber and is designed as a single mode optical fiber allowing the propagation of linearly polarized light. Accordingly, only linearly polarized light will enter block


1002


, and the polarization direction of the input light will be changed in conformity with the shear force applied to the sample which is indicated by the arrow in FIG.


10


. Preferably, optical fiber


1004


, acting as an output fiber, is also designed as single mode fiber with its polarization direction selected such as to be perpendicular to the polarization direction of the light output by fiber


1001


. Preferably, the stress-optic material of block


1002


is prepared so as to exhibit zero birefringence in the absence of stress. Hence, substantially no light will be output by fiber


1004


and input into detector element


1005


when no shear stress is applied to a sample on plate


1003


. Application of stress to the sample and thus to the sensor element alters the polarization of the light transmitted to block


1002


and produces a measurable signal at detector element


1005


. The signal increases with increasing shear stress a lied to the sample.




Alternatively, a polarizing element


1006


may be used between fiber


1004


and detector element


1005


when input fiber


1001


and output


1004


are of the same type, i.e. have the same polarization direction. Polarizing element


1006


is oriented such that its polarization direction is perpendicular to that of the fibers


1004


and


1001


.




In a further alternative, the stress-optic material of block


1002


may be replaced by a short length of input fiber


1001


or output fiber


1004


, which retards the polarization state of the transmitted light beam in response to a shear stress applied to the sample.





FIG. 11

schematically shows a further embodiment of a stress-optic sensor element according to the present invention. In

FIG. 11

, a light source


1101


, preferable a laser, emits linearly polarized light. The light emitted by light source


1101


passes through a half-mirror


1102


and is input into a multimode fiber


1103


. A y block of stress-optic material


1104


is attached to the other end of fiber


1103


. The end block


1104


opposing the fiber


1103


is provided with a sample plate


1105


which is preferable made of a rigid material such as stainless steel or aluminum which is capable of reflecting light. Above sample plate


1005


, a “moving” plate


1106


, acting as an actuator, is positioned such that a sample


1107


is confined between sample plate


1105


and actuator


1106


. In this embodiment, actuating element


1106


and sample plate


1105


exhibit a cone-and-plate geometry, however, any other appropriate geometry such as a parallel-plate geometry may also be used as previously mentioned. Further, in the optical path of light reflected by half-mirror


1102


, a polarizing element


1108


id disposed in front of a detector


1109


.




In operation, light source


1101


, such as a laser, emits linearly polarized light which passes half-mirror


1102


and enters optical fiber


1103


which may be a multimode fiber. The light introduced into optical fiber


1103


is guided to the stress optic material of block


1104


and is reflected by sample plate


1105


. The polarization direction of the light is altered due to a shear force applied to the sample


1107


by the actuating element


1106


which, in turn, induces a force in the stress-optic material


1104


. The reflected light having the altered polarization direction due to its interaction with the stress-optic material is partly reflected by half-mirror


1102


and directed to polarizing element


1108


whose polarization direction is perpendicular to that of light source


1101


. Hence, detector


1109


will detect a light intensity in response to the shear force prevailing in the stress-optic material


1104


. Alternatively, optical fiber


1103


may be a single mode fiber with its polarization direction adjusted to be parallel with that of light source


1101


. In this case, polarizing element


1108


may be omitted so that detector


1109


will detect a decreasing light intensity with increasing stress applied to the sample.




Alternatively, referring to

FIG. 11A

, light from the light source


1101


is transmitted through a circular polarizer


1102




b.


Circularly polarized light is then introduced into the optical fiber and is guided to the stress optic material and reflected back by the sample plate. The polarization state of the light is altered due to the stress induced in the stress-optical material by shear applied to the sample by the actuating element. The reflected light having an altered polarization state due to its interaction with the stress-optic material is partly transferred back through the circular polarizer


1102




b.


Hence detector


1109




b


(positioned beside light source


1101


) will detect a light intensity in response to the shear force prevailing in the stress optic material.




Alternatively, the linearly polarized light may be directed onto the stress-sensor material at an oblique angle. Some fraction of the light is transmitted through the sensor material and is then reflected from the sample plate


1105


to pass back through the stress-optic material. In this case, the optical fiber


1103


may be omitted and some fraction of the reflected light is transmitted through the material-atmosphere interface and is incident onto the appropriately-placed polarizing element


1108


and detector


1109


.




In a further embodiment not shown in the FIGS., using a single mode optical fiber as the input, the sensor material and the output fiber are combined into a single length of a single mode optical fiber. Applying a shear stress to a “sensor” section of this optical fiber rotates the polarization direction of the light passing through it due to the “stress optic” characteristics of the sensor section, as previously pointed out. The output section of this single mode optical fiber transmits only that portion of the light which has a polarization direction parallel to that transmitted by the input section. Thus, the intensity of light exiting the output section decreases with increasing shear stress applied to the sample. Quantitative measurements may be facilitated by comparing the output of this single mode optical fiber to that transmitted by a second, unstressed length of a single mode optical fiber.




Suitable polarizers which may be employed in some of the above-mentioned embodiments include sheets of polarizing films, polarizing mirrors, and the direction of an initially polarized light beam onto the surface of the stress-optic material at the brewster angle. For the detectors used in the several embodiments mentioned above, films, photomultipliers, avalanche photodiodes, conductive photocells, and CCD cameras may be employed.




The above-described embodiments of stress-optic sensors according to the present invention provide for ease of parallel data acquisition, immunity to electromagnetic noise, and great robustness at low temperatures.




With reference to

FIG. 12

, an improved force sensor element is described which allows the simultaneous measurement of a shear force and a normal force.




In

FIG. 12

, a recess portion


1201


is formed in a substrate


1202


comprising silicon or any other appropriate material such as silicon nitride or polyimide, etc., by standard micromachining manufacturing steps such as photolithography and etching. Within the recessed portion


1201


, a rectangular plate


1203


is formed which is tethered by four tethers


1204


,


1205


,


1206


, and


1207


to the substrate


1202


. Each of the tethers


1204


-


1207


comprises two regions that have piezo-resistive properties, which are shown as “N-doped” regions as indicated by “n” in the figure. The tethers


1204


and


1207


are electrically connected by a wiring line


1208


which, in turn, is electrically connected to contact pads


1209


and


1210


, respectively. Similarly, tethers


1205


and


1206


are electrically connected by a wiring line


1211


which, in turn, is electrically connected to contact pads


1212


and


1213


, respectively.

FIG. 12

is not to scale and the width of the tethers


1204


-


1207


is exaggerated in comparison with the side length of the plate


1203


. In a preferred embodiment of the force sensor according to the present invention, the width of the tethers is about 80 μm and the side length of plate


1203


is in the range of one to several mm. The length of the tethers is about 1 mm and the length of a single piezo-resistive area, i.e. of any N-doped regions in the surface layer of each tether, is about 300 μm.




As the skilled person will readily appreciate, the above dimensions may be varied in numerous manners so as to satisfy design and application requirements.




The force sensor according to the present invention is preferably manufactured as an array on a silicon substrate such as a lightly N-doped silicon wafer having a thickness of about 400 μm by means of conventional semiconductor manufacturing procedures which are well-known to the person skilled in the art. Hence, a detailed description of the various procedural steps in manufacturing the force sensor array will be omitted.




In operation, an input voltage is applied to the contact pads


1209


and an output voltage is obtained at contact pad


1210


which represents the middle terminal of a piezo-resistive bridge formed by the respective N-doped regions of the tethers


1204


and


1207


, respectively. Similarly, an input voltage, possibly of the same amount as that applied to contact pads


1203


, is applied to contact pads


1212


and an output voltage can be detected at contact pad


1213


which represents the middle terminal of a piezo-resistive bridge formed by the respective N-doped regions on the tethers


1205


and


1206


, respectively. When a shearforce is applied to the plate


1203


, i.e. a force which, in the configuration of

FIG. 12

, is substantially oriented in the plane of the plate


1203


and normal to the axes of the tethers


1204


-


1207


, so as to cause a slight displacement of the plate


1203


, thereby generating a deformation of the tethers


1204


to


1207


. The N-doped regions of tether


1207


are mirror-symmetrically arranged with respect to a vertical middle axis of plate


1203




50


that the change in resistance of the tethers


1204


and


1207


will substantially cancel out each other. Accordingly, the voltage detected at contact pad


1210


substantially remains unchanged.




Contrary to this, on the tethers


1205


and


1206


, N-doped regions are vertically arranged side by side so that upon application of a shear force, a maximum change of resistance in the doped regions of tether


1205


and


1206


will be obtained. Moreover, the doped regions on tether


1205


are inversely arranged to that of tether


1206


so that a maximum shift of the voltage detected at contact pad


1213


will occur. Accordingly, a shear force applied to the plate


1203


will provide a substantially unchanged output voltage on contact pad


1210


, irrespective of the magnitude of displacement of plate


1203


, and a maximally-shifted output voltage on contact pad


1213


depending on the magnitude of displacement. Hence, tethers


1205


and


1206


act as a shear force sensor element.




Similarly, when a force is applied to the plate


1203


which is directed perpendicular to the drawing plane of

FIG. 12

, the tethers


1204


-


1207


are deformed in such a way that the output voltage on contact pad


1210


is maximally shifted depending on the magnitude of displacement of plate


1203


in the direction perpendicular to the drawing plane, whereas the output voltage detected at contact pad


1213


remains substantially unchanged, irrespective of the magnitude of the displacement. Accordingly, the tethers


1204


and


1207


act as a normal force sensor element.




Although the force sensor which is able to simultaneously detect a shear force and a normal force has been described with reference to the embodiment as shown in

FIG. 12

, a variety of modifications may be performed still providing the same advantages as the embodiment described above.




For example, although the shear and normal force sensor element has been described to comprise four tethers, each including four appropriately-doped resistive regions, it is not necessary to provide four tethers per sensor plate. In certain circumstances, it may be preferable to have merely one tether for the normal force sensor element, or the shear force sensor element, or both. In this case, a corresponding displacement of the plate


1203


causes a deformation of the four-doped regions on each tether. When a shear force is applied, the deformation of the doped regions, which are arranged as shown, for example, on tether


1205


will lead to a change of resistance, which can be detected when a constant current is supplied to the tether. Similarly, a normal force applied to the tether will result in a change of resistance when the tether has an arrangement as shown with reference to tether


1204


.




Moreover, in order to provide a stiffer behavior of the sensor element in responding to the shear force, it may be advantageous to arrange the tethers and doped regions thereon in such a way that the shear force is applied in the longitudinal direction of the tethers. For this case, tether


1207


of

FIG. 12

will be doped as is shown in the figure and tether


1206


will be doped as tether


1204


of

FIG. 12

, wherein contact pads


1209


and


1212


are electrically connected so as to serve as a middle terminal of the normal force resistant bridge. The shear force bridge formed of tethers


1204


and


1205


include, respectively, at least one doped region, wherein contact pads


1209


and


1212


are connected to serve as a shear force output. An input voltage common to the shear force sensor bridge and the normal force sensor bridge is applied at the contact pads


1210


and


1213


.




Furthermore, the geometric arrangement of the tethers and the plate may be adapted so as to appropriately detect a rotational displacement applied to the plate


1203


. This may include an arrangement in which the sample plate


1203


is tethered to the supporting substrate


1202


by diagonally-arranged tethers. Moreover, the plate


1203


may be formed in a circular shape and the tethers, provided in any appropriate number, may radially extend to the surrounding substrate.




The preferred layout of N-doped piezo-resistor regions shown in

FIG. 12

is preferably aligned along the direction of maximum tension and preferably along the direction of maximum change in piezo-resistance, to get maximum sensitivity. For the embodiment shown in

FIG. 12

, the


100


direction is the direction of both maximum tension and maximum piezo-resistance change. Although the use of N-doped regions is shown, all N-doped regions may be replaced with P-doped regions. Also, the device alternatively may have different orientations of the piezo-resistor. For example, a P-doped piezo-resistor would preferably be aligned along the


110


direction, at 45 degrees to the direction of longitudinal forces for maximum sensitivity. In alternative embodiments for the

FIG. 12

embodiment of this invention, the N-doped regions may be replaced with any suitable piezo-resistive element, for example, piezo-resistive metal wires or doped polycrystalline silicon.




In order to achieve accurate measurement results, preferably each sensor element is calibrated by applying a defined normal force and shear force and detecting the corresponding output voltages so as to determine the degree of mixture of these two force components for each sensor device.




In an alternative embodiment, not shown in the figures, a device that has both piezo-resistive readout as well as capacitive electrodes to measure non-uniform forces acting on the plate may be used. In the preferred embodiment, four capacitive bond pad areas are placed at the four corners of the floating plate. Using both the piezo-resistor and the capacitive readouts, all the forces including the shear, the normal forces, and the rotational forces could be deconvolved. A skilled practitioner of the art can change the capacitor placement as well as change the capacitance area to maximize the device sensitivity.




Since the sensor element according to the present invention is preferably manufactured as an array of sensor elements on an appropriate substrate, this sensor element is advantageously used in combination with a parallel rheometer as previously described. Moreover, since these sensor elements may be produced in mass production at low cost, the sensor element may be designed as a disposable device so as to significantly facilitate sample preparation for a parallel rheometer. The inventive sensor element, however, may as well be used in combination with a single sample rheometer.



Claims
  • 1. A rheometer, comprising:a pair of plates spaced apart from each other by a defined distance for receiving and confining a sample therebetween, an adjusting device which adjusts the distance between the plates, a driving stage coupled to at least one of the plates, which generates a relative motion between the plates without changing the distance, and a shear stress sensor, the shear stress sensor comprising a stress-sensing material of a defined stress-optic coefficient indicating one of birefringence and retardation of linearly polarized light passing the stress-sensing material, as a function of applied stress/unit path length.
  • 2. The rheometer of claim 1, wherein polarized light is input into said stress-sensing material, and light having passed the stress-sensing material is guided through a polarizer means having a polarization direction different from that of the input light.
  • 3. The rheometer of claim 2, wherein the input light is polarized by a single mode input fiber.
  • 4. The rheometer of claim 3, wherein said stress-sensing material is a short portion of the single mode input fiber.
  • 5. The rheometer of claim 2, wherein the polarizer means has a polarization direction that is perpendicular to that of the input light.
  • 6. The rheometer of claim 1, wherein a single mode fiber comprises a light input portion, a middle portion as the stress-sensing material, and a light output portion.
  • 7. The rheometer of claim 1, wherein a surface of the stress-sensing material, which may be brought into contact with a sample is provided with a reflective layer, and the polarized light is directed to the stress-sensing material by an oblique angle with respect to the reflective layer, whereby the polarizer means is positioned to receive light reflected by the reflective layer.
  • 8. The rheometer of claim 1, further comprising a detector arranged so as to detect a signal output by the stress-sensing material.
  • 9. A rheometer, comprising:at least one pair of spaced opposing surfaces having a first surface and a second surface adapted for receiving at least one sample having a volume of 200 μl or less; at least one driving stage for generating a relative motion between the first surface and the second surface thereby placing a stress upon the at least one sample, and at least one force sensor having a detector and a stress-optic material with a known stress-optic coefficient wherein the detector is configured to receive light after the light has passed the at least one sample and the stress-optic material such that the at least one force sensor can provide a signal related to the shear stress of the at least one sample.
  • 10. The rheometer of claim 9 further comprising:an adjusting device for adjusting the spacing between the first surface and the second surface.
  • 11. The rheometer of claim 10 wherein the first surface and the second surface are plates and the at least one sample includes a plurality of samples and wherein the at least one shear stress sensor is adapted to provide a signal related to the shear stress of each of the plurality of samples.
  • 12. The rheometer of claim 11, wherein the light is polarized light that is input into the stress-sensing material, and is guided through a polarizer means having a polarization direction different from that of the input light.
  • 13. The rheometer of claim 12, wherein the input light is polarized by a single mode input fiber.
  • 14. The rheometer of claim 13, wherein said stress-sensing material is a short portion of the single mode input fiber.
  • 15. The rheometer of claim 14, wherein a single mode fiber comprises a light input portion, a middle portion as the stress-sensing material, and a light output portion.
  • 16. The rheometer of claim 15, wherein a surface of the stress-sensing material, which may be brought into contact with a sample is provided with a reflective layer, and the polarized light is directed to the stress-sensing material by an oblique angle with respect to the reflective layer, whereby the polarizer means is positioned to receive light reflected by the reflective layer.
  • 17. The rheometer of claim 12, wherein the polarizer means has a polarization direction that is perpendicular to that of the input light.
  • 18. The rheometer of claim 9, wherein the light is polarized light that is input into the stress-sensing material, and is guided through a polarizer means having a polarization direction different from that of the input light.
  • 19. The rheometer of claim 18, wherein the input light is polarized by a single mode input fiber.
  • 20. The rheometer of claim 19, wherein said stress-sensing material is a short portion of the single mode input fiber.
  • 21. The rheometer of claim 20, wherein a single mode fiber comprises a light input portion, a middle portion as the stress-sensing material, and a light output portion.
  • 22. The rheometer of claim 21, wherein a surface of the stress-sensing material, which may be brought into contact with a sample is provided with a reflective layer, and the polarized light is directed to the stress-sensing material by an oblique angle with respect to the reflective layer, whereby the polarizer means is positioned to receive light reflected by the reflective layer.
  • 23. The rheometer of claim 18, wherein the polarizer means has a polarization direction that is perpendicular to that of the input light.
  • 24. The rheometer of claim 9 wherein first surface and second surfaces are provided by plates, which are spaced apart from each other by a defined distance for receiving and confining the at least one sample therebetween.
  • 25. The rheometer of claim 9 wherein the relative motion between the first surface and the second surface occurs without changing the distance between first and second surfaces.
  • 26. The rheometer of claim 9 wherein the stress-optic material is formed of a transparent plastic material.
  • 27. The rheometer of claim 9 wherein the at least one pair of surfaces includes a plurality of pairs of surfaces and each of the surfaces of the plurality of pairs of surfaces is provided by a plate.
  • 28. A rheometer, comprising:a pair of opposing surfaces spaced apart from each other by a defined distance for receiving and confining a sample therebetween, the sample having a volume of 200 microliters or less; an adjusting device which adjusts the distance between the surfaces; a driving stage for generating a relative motion between the surfaces thereby placing a shear stress upon the sample without changing the distance between the surfaces; and a shear stress sensor for sensing the shear stress placed upon the sample, the shear stress sensor comprising: i) a stress-sensing material having a defined stress-optic coefficient, the stress sensing material formed of a transparent plastic material, which exhibits zero birefrigerance in the absence of stress; ii) a first optical fiber associated with the stress-sensing material for polarizing light once the light has passed through the sample and the stress-sensing material; and iii) a second optical fiber optically connected to a detector element, which detects the polarized light.
  • 29. The rheometer of claim 28 wherein the shear stress sensor is configured for sensing shear stress of a plurality of samples simultaneously.
Parent Case Info

This application is a divisional of copending application: Application No. 10/205,060 filed on Jul. 25, 2002 which is a continuation of Application No. 09/632,378 filed on Aug. 3, 2000 now U.S. Pat. No. 6,484,567 and claims priority of the filing date of both applications.

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Continuations (1)
Number Date Country
Parent 09/632378 Aug 2000 US
Child 10/205060 US