FR2620226A1 - DYNAMOMETRIC PROBE FOR REAL-TIME STATIC AND DYNAMIC MEASUREMENT OF VARIOUS PHYSICOCHEMICAL, BIOCHEMICAL OR BIOLOGICAL PARAMETERS OF A LIQUID MEDIUM - Google Patents

Abstract

A particularly sensitive dynamometric probe for the detection of variations of molecular structures in a liquid medium and for the static and dynamic measure, in real time, of physical, chemical, biochemical and biological parameters of the same medium. An arm (4) integral with a torsion wire (1) carries at one of its ends an interchangeable vane (10) and a sealing lamella (12). The arm (4) under the driving effect of an electromagnetic device (6, 7, 9) oscillates around the torsion wire (1). The vane (10) is immersed into the medium to be studied (22), which slows down the movement of said vane. An optoelectronic sensor (13 to 15), comprising the sealing lamella (12), measures the angular shift of the arm (4) and emits an electric signal, in analog or digital form. Application: industries and laboratories processing more or less viscous liquid mediums as in the chemical industry, petrochemicals, the pharmaceutical industry, the agri-food industry, various research and medical analysis laboratories or others.

Description

DYNAMOMETER PROBE FOR STATIC MEASUREMENT AND DYNAMI
THAT, IN REAL TIME, VARIOUS PHYSICO-CHEMICAL PARAMETERS,
BIOCHEMICAL OR BIOLOGICAL OF A LIQUID MEDIUM
The present invention relates to a dynamometric probe intended for the detection, observation and measurement of variations in physical, chemical, biochemical or biological characteristics of a medium to be studied.

The primary object of the invention is to provide an instrument for observation and measurement, in real time, of slow variations in physical, chemical, biochemical or biological parameters of a liquid medium of any viscosity.

The dynamometric probe according to the invention is characterized in that it comprises an oscillating element carried by an axial support defining a pivot axis of this element, a motor device of the electromagnetic type which applies to the oscillating element alternating forces determined for oscillate it, a braking member in the form of a pallet or a rod which is integral with the oscillating element and which is immersed in said medium, and a displacement sensor which measures the angular displacement of the oscillating element which delivers a corresponding electrical signal.

Thus we measure the resistance that the environment studied opposes to the movement of a palette plunging into this environment. A force is therefore measured by means of a torque applied to the pallet, hence the name of the dynamometric probe.

The dynamometric probe is an instrument whose structure and operating conditions provide it with a sensitivity such that it makes it possible to detect variations in the molecular structures of the medium studied, the causes of which can be of a physical, chemical, biochemical or biological nature. It delivers an electrical signal, analog or digital, the maximum amplitude of which directly depends on this structure. The signal delivered lends itself to any analog or digital processing, thus allowing qualitative and quantitative analyzes, comparative analyzes as well as statistical analyzes of the observed processes. It allows, in particular, the graphical plot of the evolution of the physical-chinic, biochemical or biological state of the environment studied, plot which represents the image in real time, of the evolution of this state.

Thus, among the numerous applications, we can cite the trace, in real time, of the enzymatic processes, or else the thromboelastographic trace which, in addition to the usual data, provides new data not contained in the HARTERT trace and thus gives these new interest reviews.

If the state of the medium is not evolving, the amplitude of the signal delivered characterizes this state under precise physical conditions ct can therefore be used to identify this state, i.e. to measure d 'one of the characteristic parameters of this state. Thus, for example, the dynamometric probe delivers a signal whose amplitude is a linear function of the concentration of a solution, under given physical conditions. Calibrated, the probe can therefore be an instrument for measuring the concentration of a solution.

The dynamometric probe is thus an instrument for qualitative and quantitative observation of events within a liquid, capable of carrying out both static and dynamic measurements of any parameter characteristic of the medium studied. The applications relate to all industries and laboratories which use or treat more or less viscous liquid or pasty media, notably the chemical industry in general, the petrochemical industry, the pharmaceutical industry, the food industry, various laboratories of study and analysis, medical and others.

In a particular embodiment of a probe according to the invention, the axial support consists of a twist wire which is fixed at its two ends and which defines the pivot axis of the oscillating element.

The oscillating element can be formed by a rigid arm arranged perpendicular to its pivot axis, the displacement sensor being disposed near one end of this arm. Preferably, the center of gravity of the swinging arm and the motor device are located near the pivot axis, and the braking member is disposed near one end of the arm.

The motor device, in a first embodiment, comprises a fixed stator and a movable magnetic assembly fixed to the oscillating element in a symmetrical arrangement with respect to the pivot axis. In another embodiment, the motor device comprises an electric coil in the form of a mobile frame which is integral with the oscillating element and which is in a magnetic field at the intensity of the constant magnetic induction.

The braking member in the form of a cylindrical rod or a pallet is arranged vertically in the liquid medium to be studied and so as to offer maximum resistance to the movement of the oscillating element.

According to a preferred form of the invention, the displacement sensor is an optoelectronic sensor comprising a photo-emitter delivering a constant light flux, a photoreceptor which receives the light flux coming from the photo-emitter and which delivers an electrical signal whose intensity is a direct function of the light flux received, a shutter strip which is integral with the oscillating element and which has the role of closing, as a function of the angular position of the oscillating element, the light ilux captured by the photoreceptor. Thus, the photoreceptor delivers an electrical signal at its output, the instantaneous amplitude of which is directly proportional to the light flux received. Alternatively, the photoreceptor may be part of an optoelectronic generator of periodic signals, intended to deliver an electrical output signal whose frequency is a direct function of the light flux received by the photoreceptor. This output signal can for example be a sawtooth signal.

The structure and operation of a probe according to the invention are described below by example embodiments, given without limitation and with reference to the appended drawing, in which
FIG. 1 is a schematic side elevation view of a preferred embodiment of a dynamometric probe according to the invention, comprising an oscillating arm and an optoelectromic displacement sensor,
FIG. 2 is a schematic plan view of the oscillating arm and of its motor device,
FIG. 3 is a schematic elevation view illustrating another embodiment, and
FIG. 4 is a simplified electrical diagram of an optoelectronic displacement sensor usable with the probes according to FIGS. 1 to 3.

With reference to FIGS. 1 and 2, the dynamometric probe comprises a torsion wire I with a low torsional constant, fixed at its two ends to a frame 2, 3 so that the tension of the wire is adjustable. An arm
rigid 4 made of very light materials is attached to the middle of the torsion wire and perpendicular to it by a fixing device 5. The torsion wire I and the arm 4, located in the same plane, form an integral assembly whose arm 4 can perform a rotational movement around the axis defined by the twist wire 1. Two magnetized pads 6 and 7 of negligible weight are secured to the arm 4 and are arranged semitrically relative to the axis of rotation. distance between pads 6 and 7 can be provided adjustable in certain applications. In the case of simplified structure probes, a single pad 6 or 7 may be sufficient. Facing the magnetized pads 6, 7, is placed the ferromagnetic core S in the shape of a U of an electric coil 9. The coil 9 being supplied with alternating current, the polarity of the magnetized pads is oriented so that, when a pad undergoes an attractive force,
The other undergoes a force of repulsion. Thus, an alternating current of low maximum amplitude corresponds to an oscillatory movement of the arm 4 around its axis materialized by the twist wire 1.

At one end of the arm 4 is fixed interchangeably a pallet 10 of suitable shape, by means of a fixing system 11. On the other hand, at a fixed distance from the axis of rotation, on one or the other side of the arm 4 is fixed a strip 12 acting as an optical shutter. One of the edges of the strip 12, parallel to the arm 4, called the active edge 21, is aligned with the central axis of the arm 4, an axis which intersects the axis of rotation coincident with the twisted wire. A photo-emitter 13 and a photoreceptor 14, the spectrum sc of which preferably lies in the infrared, form a photocouple, and are arranged on either side of the shutter strip 12. The width of the strip 12 must be sufficient to completely block the light beam received by the photoreceptor 14. At rest, that is to say at zero current in the coil 9, the photocouple 13, 14 is positioned relative to the active edge 21 of the strip 12 so that the photoreceptor 14 receives exactly half of the total light flux received without shuttering. The photo-emitter 13 is supplied by a constant current source 15.

During the oscillatory movement of the arm 4, the strip 12 more or less blocks the emitted beam, which allows, for an intensity of the photo-emitter 13 assumed to be constant, to collect at the output of the photoreceptor 14 a current proportional to the angle of supposedly small deviation of the arm 4. The current of the photoreceptor 14 can be amplified directly by a current amplifier 17, in order to increase the reading sensitivity of the angle of deviation of the arm 4.

By introducing a load resistor 18 in series with the photoreceptor 14, it is then possible to collect at the terminals of the load a potential difference proportional to the current of the photoreceptor.

As this current is proportional to the angle of deflection of the arm 4, the same goes for the potential difference. In this case, to increase the reading sensitivity of the deflection angle, a voltage amplifier 19 is used. In current applications, the coil 9 is supplied by a source 16 of sinusoidal alternating current at fixed frequency, constant maximum amplitude. but adjustable.

From the above we deduce the functioning of the whole in the observation of physico-chemical or biochemical processes, in a liquid medium. Indeed, the pallet 10 plunges into the sample of the liquid to be studied 22. The arm 4, being subjected to a driving torque due to the sinusoidal forces of constant maximum amplitude which are exerted on the pellets 6 and 7, describes a movement oscillating around its axis of rotation materialized by the wire 1. By means of the pallet 10, the liquid medium 22 exerts a resistant torque which opposes the motor torque and thus limits the maximum amplitude of the angle of deflection of the arm 4. The maximum amplitude resulting from the movement depends on the physical structure or the chemical nature of the liquid medium studied 22 and therefore translates the relative physical or chemical state of the medium. The photocouple 13, 14 delivers an electrical signal whose l the maximum amplitude is directly proportional to the maximum amplitude of the oscillatory movement of the arm 4. Thus, any variation in the physical state of the medium 22 results in a variation in the maximum amplitude of the angle of rotation of the arm 4 andconsequently the maximum amplitude of the current of the photoreceptor 14 or the potential difference linked to the latter.

The structure of the probe described above corresponds to an optimal structure which provides it with maximum sensitivity and resolving power. Under these conditions we can hope, if we give enough care to its mechanical production, that it will be operational in media with very low viscosity and even to the limit usable in media in the state of vapor or gas of a certain density.

On the contrary, if one does not look for extreme sensitivities of the probe and a fortiori if one is dealing with very viscous liquid media, at the limit even with solids with sufficient elasticity, such as certain food products, meats for example, the structure previously described can be modified to a certain extent. Thus, the torsion wire I can be replaced by a rigid axis possibly provided with a spiral spring acting as a return spring, a system similar to the balance spring with a clock.

Similarly, the motor torque of the probe can be produced by a mobile frame device, similar to the mobile frame of a galsanometer and similarly secured to the twist wire I or to the rigid axis and the coil of which is supplied by an alternating motor current of sinusoidal form. The assembly then replaces the magnetized pads 6 and 7 as well as the coil 9 with its core 8.

The optoelectronic displacement sensor described above can be replaced by another type of optoelectronic sensor, illustrated in FIG. 4, also of great sensitivity. The latter comprises an optoelectronic generator 23 of signals, for example sawtooth 24, where the photoreceptor 14 is an integral part of the generator used.

A variation in the light flux received by the photoreceptor 14, due to the movement of the strip 12, causes a variation in the frequency of the signal from the generator 23. Here the result of the reading of the displacement is presented directly in digital form, the benefit of which is , in many applications, is crcrain.

As for the structure of the signal generator, it corresponds to the general simplified diagram of FIG. 4 for the sawtooth signals.

The operating principle is based on the charging or discharging of a capacitor through a photoreceptor. Considering the scher, ka, it can be seen that the capacitance 27 is charged through the photoreceptor 14 with a charge speed which is directly proportional to the light flux received. A threshold comparator 29 detects the maximum voltage allowed at the terminals of the capacitor 27 and commands the closing of a switch 28 through which the capacitor 27 discharges, after which the cycle begins again. It is understood that the frequency of the signal delivered 24 depends on the illumination received by the photoreceptor. For certain applications, the use of a PIN type photoreceptor may prove useful.

The measurement of the maximum angle of deflection of the arm 4 can be carried out by other means and in particular by means of a potentiometer secured to the rotating mechanical part, thus replacing the photocouple 13, 14 and the strip 12 The latter solution may be advantageous in the case where we are dealing with very viscous media, even elastic solid media, and where the twist wire I is replaced by a rigid axis integral with the potentiometer. This structure ensures great compactness for the entire probe.

The rigid arm 4 consists of two integral branches, of comparable or non-comparable lengths, located on either side of the torsion wire I or of the rigid axis. The shutter 12 can be arranged on the same side of the arm as the pallet 10 or on the other side depending on whether the arms of the arm are of comparable length or not. FIG. 3 illustrates an embodiment in which the asymmetry in length of the arms 4 ′ arms confers less volume on the assembly. In this case the two branches, of unequal lengths, are balanced in mass by a counterweight 20 located on the end of the shortest branch.

For most applications, the shape of the motor current flowing through the coil 9 is sinusoidal. However, a periodic current of rectangular shape or a step of current may be more suitable in certain applications such as studying or measuring the viscosity of particular media. Likewise, a current with linear growth over time may prove useful in studying the response of a medium. A person skilled in the art can foresee many other modifications and variants with respect to the examples mentioned above, without going beyond the ambit of the present invention.

Claims (9)

Claims 1. Dynamometric probe intended for the detection, the observation and the measurement of the variations of physical, chemical, biochemical or biological parameters of a medium to be studied, characterized in that it comprises - an oscillating element (4, 4>) carried by an axial support (1) defining  a pivot axis of this element, - an electromagnetic motor device (6 to 9) arranged to apply  to the oscillating element a determined torque to rotate it  around its axis, - a braking member (10) in the form of a pallet or  a rod, integral with the oscillating element and which plunges into said  medium (22), - and a displacement sensor (12 to 19) measuring the amplitude  maximum angular movement of the oscillating element in  delivering a corresponding electrical signal. 2. Probe according to claim 1, characterized in that the axial support comprises a twist wire (1) which is fixed at its two ends and which defines the pivot axis of the oscillating element. 3. Probe according to claim 1 or 2, characterized in that the oscillating element is a rigid arm (4, 4 ') arranged perpendicular to its pivot axis, the displacement sensor being disposed near one end of this arms. 4. Probe according to claim 3, characterized in that the center of gravity of the swinging arm (4, 4 ') and the motor device are located near the pivot axis (1), and in that the member brake (10) is disposed near one end of the arm. 5. Probe according to one of claims 1 to 4, characterized in that the motor device comprises a fixed stator (8, 9) and a mobile magnetic assembly (6, 7) fixed to the oscillating element in a symmetrical arrangement by relative to the pivot axis. 6. Probe according to one of claims 1 to 4, characterized in that the motor device comprises an electric coil in the form of a movable frame, integral with the oscillating element and which is in a magnetic field at the intensity of l constant magnetic induction. 7. Probe according to one of the preceding claims, characterized in that the braking member in the form of a cylindrical rod or a pallet (10) is arranged vertically in the medium of the liquid to be studied (22) and of so as to offer maximum resistance to the movement of the oscillating element (4, 4 '). 8. Probe according to one of the preceding claims, characterized in that the displacement sensor is an optoelectronic sensor including a photo-emitter (13) delivering a constant light flux, a photoreceptor (14) arranged to receive the light flux from the photo-emitter and to deliver an electrical signal whose amplitude is a direct function of the light flux received, and a shutter strip (12) which is integral with the oscillating element (4, 4 ') and which has the role of shut off, as a function of the angular position of the oscillating element, the light flux picked up by the photoreceptor (14). 9. Probe according to claim 8, characterized in that the photoreceptor (14) is part of an optoelectronic generator of periodic signals (23), intended to deliver an electrical output signal (24) whose frequency is a direct function of the luminous flux received by the photoreceptor.