FR2956982A1 - Individual tensiometer for measuring tension of racket string, has deformable element deformable by rotation of gripping body, and potentiometer and actuating units' parts respectively integrated to gripping body and stressing unit - Google Patents

Abstract

The tensiometer has a deformable element deformable by rotation of a gripping body (10) around an axis transverse to a racket string (9) and parallel to a median plane passing between support elements of a racket string stressing unit (2) at an overlapping state of the support elements on the string. Measurement units measure relative rotation between the body and the stressing unit, and are formed by a potentiometer (5) and potentiometer actuating units having a gear (7). The potentiometer and parts of the actuating units are integrated to the body and the stressing unit, respectively. An independent claim is also included for a method for determining tension of a racket string using a tensiometer.

Description

The present invention generally relates to tension measuring apparatus for rope type elongate member.

The invention relates more particularly to an individual tensiometer for measuring the tension of a racket rope, said tensiometer comprising: - a so-called grasping body, - a member for biasing the rope by deformation of said rope, said biasing member comprising at least two support elements spaced from one another, such as studs or fingers, positionable on either side of an individual cord, - a deformable element connected to the gripping body and to the rope biasing member, said deformable member being, in the state straddling the rope of the two supporting elements of said biasing member, deformable by rotation of said grip body about an axis transverse to the rope and parallel to the median plane passing between said support elements straddling the rope, said tensiometer being equipped with means for measuring the relative rotation between the gripping body and the biasing member. The Applicant has previously developed a high-performance blood pressure monitor that can be used by both left-handed and right-handed users. This blood pressure monitor is described in French Patent Application No. 10/00919. However, this tensiometer comprises a flexible blade on which strain gauges 25 are glued in order to measure the bending of the blade in order to be able to convert this measurement into a rope tension value. Such a blood pressure monitor offers reliable measurements of high accuracy, but requires that the strain gauges on the flexible blade be implemented in a careful manner. The handling time required to bond the strain gauges to the flexible blade affects the cost of the tensiometer, which is intended for such professional use by such a blood pressure monitor.

An object of the present invention is to provide a simplified design sphygmomanometer, usable for both left-handed and right-handed.

Another object of the invention is to provide a tensiometer whose parts can be assembled quickly while providing an accurate and reliable voltage measurement.

For this purpose, the subject of the invention is an individual tensiometer for measuring the tension of a racket rope, said tensiometer comprising: a grasping body; a member for biasing the rope by deformation of said rope; said biasing member comprising at least two support elements spaced from each other, such as studs or fingers, positionable on either side of an individual cord, a deformable element connected to the body of grasping and the organ for stressing the rope, said deformable element being, in the state straddling the rope of the two supporting elements of said biasing member, deformable by rotation of said gripping body around a transverse axis at the rope and parallel to the median plane 20 passing between said support elements straddling the rope, said tensiometer being equipped with means for measuring the relative rotation between the gripping body and the biasing member, characterized in that said measuring means are formed by a potentiometer and means for actuating the potentiometer, said potentiometer and at least a part of said actuating means being integral, one of the input body and the other , of the solicitation organ.

For a given angle of rotation of the gripping body or the rotating member from an initial position of the two support elements against the rope, the relative rotation between the gripping body and the gripping member stress or bending deformation of the deformable element is a function of the internal or initial tension of the rope, that is to say the tension of the rope in the absence of stressing thereof. Indeed, the deformable element connects the gripping body to the biasing member so that said deformable element limits the relative rotation between the gripping body and biasing member by acting against this relative rotation. As a result, the measurement of said relative rotation corresponds to a measurement of the deformation of the deformable element which itself depends on the tension of the rope. Thus, the measurement of the relative rotation between the gripping body and the biasing member makes it possible to determine the tension of the rope.

Such a blood pressure monitor is easily manipulated for both left-handed and right-handed users. Indeed, the relative rotation between the gripping body and the biasing member, in one direction and in the other, permitted by the deformation of the deformable element, can be detected in both directions by means of the potentiometer whose value ohmic is modified when the input body 15 is rotated in one direction and the other.

The use of a potentiometer makes it possible to benefit from a solid sphygmomanometer of simplified design which offers a reliable and precise measurement of tension. The user can easily and quickly determine the tension of a rope. Advantageously, said potentiometer being of the rotary type, the control shaft of said potentiometer carries a gear, such as a meshing gear, adapted to mesh with meshing means forming said at least a portion of said actuating means of the actuator. potentiometer. The meshing mechanism between the rotary potentiometer and the gripping body, or the biasing member, depending on whether the potentiometer is carried by the biasing member or the gripping body, makes it possible in a simple and reliable manner to use the relative rotation between the input body and the biasing member to modify the resistance value of the potentiometer. This ohmic value can then be converted into a voltage value of the chord since said relative rotation is representative of the deformation of the deformable element, itself representative of the tension of the chord.

According to an advantageous characteristic of the invention, said potentiometer being integral with the biasing member, said meshing means comprise a toothed wheel integral with the gripping body. Preferably, said toothed wheel and the gripping body are formed in one piece.

The realization of the gripping body in the general form of a toothed wheel is very interesting since, said gripping body being intended to be rotated by the hand of the operator, said gripping body can directly mesh, via its toothed part, with the pinion carried by the control shaft of the potentiometer without the need to add additional meshing means.

According to an advantageous characteristic of the invention, said deformable element comprises a part connected to the gripping body at two opposite points with respect to the axis of rotation of said gripping body, and another part connected to the biasing member by two opposite points with respect to the axis of rotation of said input body.

The distribution on either side of the axis of rotation of the connection points between deformable element and gripping body and biasing member, provides a reliable and balanced deformation of the deformable element during the relative rotation between body of seizure and organ of solicitation.

Preferably, the deformable element has the general shape of a cross whose branch is coupled to or near its ends to the grasping body and whose other branch is coupled to or near its ends. to the solicitation organ.

Thus, the relative rotation between the gripping body and the biasing member results in the bending of one branch of the cross relative to the other branch. Such a design of the deformable element makes it possible to simplify its assembly for the manufacture of the tensiometer since said cross-deformable element can be mounted in different orientations because of its planes of symmetry and in sandwich between the gripping body and the body. biasing by being centered on the axis of rotation of the gripping body.

The means for connecting the deformable element to the gripping body and the connecting means of the deformable element to the biasing member are each formed by at least two sets of tenons and tenon insertion orifices, each play being disposed on either side of the axis of rotation of said tensiometer, in the assembled state of the tensiometer.

According to an advantageous characteristic of the invention, the deformable element is made of elastomer, preferably Styrene Ethylene Butylene Styrene (SEBS). The deformable element comprises at least one elongated part and the opposite ends of the elongated part of the deformable element are connected to two distinct points of the annular gripping body, preferably at two diametrically opposite points with respect to the axis of rotation. . According to an advantageous characteristic of the invention, the deformable element comprising at least one elongated part, the longitudinal axis of said elongated part of said deformable element is, in the absence of biasing the seizing body, substantially coplanar with the axis of rotation of the gripping body 25 defined by the axis which is comprised in the median plane passing between said support members intended to overlap the rope and which is perpendicular to the axis of the rope passage delimited between the two elements of 'support.

In other words, the deformable element is substantially centered on the axis of rotation of the gripper body of the tensiometer, which makes it possible to have a substantially identical behavior in deformation of the deformable element in one direction and in the other, and therefore to determine reliably and quickly the tension of a rope that is deformed in one direction or the other.

Such an arrangement of the deformable element with respect to the axis of rotation of the gripping body also simplifies the design and manufacture of the tensiometer while offering an accurate and reliable measurement of the rope tension from the deformation of the rope. deformable element in one direction or the other, corresponding to a rotation of the input body in one direction or the other depending on whether the user is right-handed or left-handed.

According to an advantageous characteristic of the invention, there is provided means for calculating the tension of the rope from the measurement of the relative rotation between the gripping body and the biasing member. As a reminder, the relative rotation measurement between the gripping body and the biasing member amounts to measuring the deformation of the deformable element which itself depends on the tension of the rope.

The use of a potentiometer and actuating means arranged so as to modify the resistance value of the potentiometer as a function of the relative rotation between the input body and the biasing member, makes it possible to provide an electrical signal representative of the relative rotation between the input body and the biasing member which can be processed by electrical and / or computer calculation means to determine the corresponding voltage of the string. In particular, it is possible to filter and / or amplify the signal at the output of said potentiometer. In particular, said calculating means are connected to the potentiometer to acquire the value associated with the potentiometer and to convert it into a string voltage value.

The invention also relates to a method for determining the tension of a racket rope, using a tensiometer as described above, characterized in that said method comprises the following steps: positioning the member for biasing the tensiometer astride by its two support elements on an individual rope, - turning the gripping body of the tensiometer until obtaining a predefined orientation of the biasing member, or the gripping body, with respect to the rope, in which the two supporting elements of the biasing member exert a torque on the rope, - measuring the relative rotation between the gripping body and the biasing member, - calculating, from said measurement, the tension of the rope.

The invention will be better understood on reading the following description of exemplary embodiments, with reference to the appended drawings, in which: FIG. 1 is an exploded top view of the tensiometer according to the invention; FIG. 1A is an exploded bottom view of the tensiometer of FIG. 1; FIG. 2 is a top view of the tensiometer of FIG. 1 in the assembled state; FIG. 2A is an axial sectional view along section A-A of the tensiometer of FIG. 2; FIG. 2B is a side view of the tensiometer of FIG. 2; FIG. 3 is a view from above of the tensiometer according to the invention in the state of riding on a rope, before deformation of said rope, being positioned in order to apply a rotational movement to the seizure body in the clockwise, preferably for a right-handed person; FIG. 3A is a view from above of the tensiometer according to the invention, in the state straddling a rope according to the configuration of FIG. 3 and in the rotated state of the gripping body in the clockwise direction, the detection of the rope; FIG. 4 is a view from above of the tensiometer according to the invention in the state straddling a rope, before deformation of said rope, being positioned in order to apply a rotational movement to the gripping body in the direction counterclockwise, preferably for a left-handed person; FIG. 4A is a view from above of the tensiometer according to the invention, in the state straddling a rope according to the configuration of FIG. 4 and in the turned state of the gripping body in the counterclockwise direction, the detection of the rope.

With reference to the figures and as recalled above, the invention relates to an individual blood pressure meter 1 for measuring the tension of a racket rope 9.

Said sphygmomanometer 1 comprises a grasping body 10 intended to be grasped by a hand (left or right) of the operator, a biasing member 2 of the rope 9 by deformation of said rope, and a deformable element 3 connected to the body 10 and the biasing member 2 of the rope. In the example illustrated in the figures, said biasing member 2 forms a support for the deformable element 3 and the input body 10 as well as, as detailed below, the potentiometer 5 and the detection means 6 of the string.

Said biasing member 2 comprises at least two support elements 21, 22 spaced apart from one another, such as studs or fingers, positionable on either side of the rope 9. Said deformable element 3 is, in the state straddling the rope 9 of the two support elements 21, 22, deformable by rotation of said gripping body 10 about a transverse axis ROT1 to the rope and parallel to the median plane passing between said support elements 21, 22 overlapping the rope 9. In particular, said axis of rotation ROT1 passes through the median plane which separates the two bearing elements 21, 22 and is orthogonal to the axis of the rope passage delimited between the two elements of FIG. 21, 22. In other words, said deformable element is deformable by relative rotation of the gripping body relative to the tension member, in one direction or the other, about the axis of rotation ROT1. Said tensiometer 1 is equipped with means for measuring the relative rotation between the gripping body and the biasing member. In characteristic manner to the invention, said measuring means are formed by a potentiometer 5 and actuating means 7, 10 of the potentiometer. Said actuating means 30 make it possible to modify the ohmic value of the potentiometer 5 as a function of the relative rotation between the gripping body and the biasing member.

Said potentiometer 5 and at least a portion 10 of said actuating means 7, 10 are integral, one of the gripping body 10 and the other of the biasing member 2.

Said potentiometer, also called variable resistor, is a rotary potentiometer. A rotary potentiometer is generally formed of one or more resistive elements whose ohmic value can be gradually modified, without having to open the circuit, by rotating a control axis connected to a cursor in contact with the element or elements. resistant.

In the example illustrated in the figures, said potentiometer 5 is integral with the biasing member 2. The control axis 57 of said potentiometer 5 carries a gear 7, such as a meshing pinion, capable of meshing with a 15 toothed wheel secured to the gripping body 10 and forming said at least a portion of said actuator means of the potentiometer, so as to modify the ohmic value of said potentiometer during the relative rotation between the gripping body and the biasing member.

Such a design of the tensiometer makes it possible, by applying a rotational force to the gripping body 10, to mesh the toothed wheel formed by said gripping body 10 with the pinion 7 of the potentiometer 5 on an angular sector, corresponding to the relative rotation. between input body 10 and biasing member 2, which is representative of the tension state of the rope. The rotation of the pinion 7 by meshing modifies the ohmic value of the potentiometer 5, which makes it possible to deduce the voltage value of the string. Preferentially, as detailed below, the potentiometer is equipped with calculation means, such as a microprocessor, which convert the measured ohmic value into a string voltage value. For this purpose, the calculation means comprise one or more curve (s) or table (s) of correspondence between the resistance values of the potentiometer and the voltage values of the string. Advantageously, said calculation means only take into account a resistance value measured beyond a certain threshold value to provide a sufficiently reliable measurement of rope tension. Preferably, said toothed wheel and the gripping body 10 are formed in one piece.

The gripping body 10 has the general shape of a toothed wheel provided on its so-called upper face, that is to say opposite the biasing member 2, of two gripping elements 11 opposite to the axis. of the toothed wheel, corresponding to the axis of rotation ROT1. Said gripping elements 11 allow the operator to apply a rotational force to the gripping body 10 in one direction and the other. The toothed wheel has a through axial orifice for the passage of a connecting member 12 for maintaining coupled the gripping body 10 to the biasing member 2, while allowing the rotation of said gripping body 10 with respect to the 2. Of course, the rotation of the gripping body 20 relative to the biasing member 2 is limited by the deformable element 3. Said connecting means are formed by a screw 12 whose thread cooperates with the threaded portion 27 formed in the biasing member 2. A washer 13 threaded onto the screw 12 is interposed between the screw head 12 and the gripping body 10 traversed by the screw 12 to allow the screw head 12 of 25 bear on the upper face of said input body10.

In general, a part 3A, 3B of the deformable element 3 is fixed to the gripping body 10 and another part 3C, 3D of the deformable element 3 is fixed to the biasing member 2. In particular, said deformable element 3 comprises a portion 3A, 3B connected to the gripping body 10 at two opposite points relative to the axis of rotation ROT1 of said gripping body, and another portion 3C, 3D connected to the biasing member 2 in two points opposed to the axis of rotation ROT1 of said input body. Said gripping body 10, the biasing member 2 and the deformable element 3 are coaxial, of parallel axis, preferably coinciding with the axis ROT1 about which a rotation is applied to the gripping body 10 of the tensiometer.

In the example illustrated in the figures, said deformable element 3 is in the form of a body with four lugs 3A, 3B, 3C, 3D arranged substantially at 90 ° to each other about the axis of rotation. of the input body. Said body of the deformable element 3 is hollowed out centrally to allow passage of the connecting means 12 of the gripping body 10 to the biasing member 2. Said ears 3A, 3B, 3C, 3D are pierced to define housing inserting tenons 14, 15, 23, 24 present, vis-à-vis the ears 3A, 3B, on the gripping body 10 and, vis-à-vis the ears 3C, 3D, on the biasing member 2. In particular, as illustrated in FIGS. 1 and 2, the tenons 14, 15 of the gripping body 10 are intended to engage in the openings of the lugs 3A, 3B and the lugs 23, 24 of the biasing member. 2 are intended to engage in the openings of the ears 3C, 3D.

In other words, the deformable element 3 has the general shape of a cross 20 of which one branch 3A, 3B is attached to or near its ends to the gripping body 10 and whose other branch 3C, 3D is fixed at or near its ends at the biasing member 2.

The deformable element is made of elastomer, preferably Styrene Ethylene Butylene Styrene (SEBS).

The branches 3A, 3B and 3C, 3D are centered on the axis of rotation ROT1.

The potentiometer forms a means for converting the relative rotation between the gripping body and the biasing member into electrical signals or else the deformation undergone by the deformable element. In particular, the rotational movement of the pinion 7 imposed by the toothed wheel 10 during the rotation of the gripping body with respect to the biasing member is representative of the bending deformation of the branch 3A, 3B of the element 3 deformable, itself representative of the tension of the rope. The axis of flexion of the branch 3A, 3B of the deformable element 3 is parallel to the axis of rotation ROT1, that is to say orthogonal to the mean plane of the rope.

The tensiometer comprises electronic and computer means (not shown), such as a microprocessor, for calculating the tension of the rope 9 from the measurement of the deformation of the deformable element 3. The term "tension" means the initial tension or at rest of the rope, that is to say in the unsolicited state of the rope by the biasing member.

In particular, said potentiometer 5 transmits to the calculation means, in the form of an electrical signal, an ohmic value which is a function of the relative rotation between the gripping body and the biasing member (in other words, a function of the deformation of the branch 3A, 3B of element 3). Said calculation means can be positioned in or on the body of the biasing member 2 which carries the potentiometer. The computer and electronic computing means determine from said received resistance value and using calculation function (s), correspondence table (s), or chart (s) stored in said calculation means, the corresponding voltage. of the rope, which can directly mean to the user the determined voltage, for example by displaying the determined value on a screen fitted to the blood pressure monitor.

The tensiometer is also equipped with detection means 6 of the rope whose voltage value is to be measured. Said detection means 6 are configured to emit a signal when they are located at the right of said chord, preferably a control signal for storing the ohmic value of the potentiometer 5.

In the example illustrated in the figures, said detection means 6 are formed by a device comprising two detection cells, for example optical. Said detection means 6 are configured to control the storage by the calculation means of the resistance value of the potentiometer when the beams of the cells are cut by the cord, that is to say when the detection means 6 are at the right of the rope.

It can then be provided that the cells and the calculation means are configured so that when the cells of the detection means detect the presence of the cord, said detection means 6 emit a signal intended for the calculation means so that these they memorize the resistance value of the resistance corresponding to the relative rotation between the input body and the biasing member at the moment of the detection of the string. The calculation means can then, from this stored value, accurately and reliably calculate the corresponding rope tension value, without the operator needing to keep the gripping body in equilibrium in this stress configuration. rope. Indeed, the operator does not have to worry about the accuracy of the rotation applied to the input body. During the rotation of the gripping body and at the time of the passage of the detection means 6 above the string these will detect its presence and send a signal to the calculation means which will memorize, at this moment, the value of resistance of the potentiometer to convert it into a string tension value, regardless of the subsequent movement of the tensiometer.

Each detection cell may be an optical or sound-wave cell such as ultrasound. Alternatively, it can be provided that said signal emitted by the detection means 6 is an optical or visual signal indicating the operator to stop turning the input body to read the voltage value calculated by the calculation means.

The method of measuring the tension of a rope with the aid of such a blood pressure monitor comprises the following steps: positioning the urging member 2 of the horse tensiometer by its two support elements 21, 22 on a rope 9 individual, - turn the gripping body 10 of the tensiometer to obtain a predefined orientation of the gripping body 10 with respect to the rope 9, in which the two support elements 21, 22 of the biasing member exert a pair on the rope 9, - measuring the relative rotation between the gripping body and the biasing member, - calculating, from said measurement, the tension of the rope.

Said gripping body 10 of said tensiometer is intended to be rotated about said axis of rotation ROT1 until the biasing member 2 has a given predefined orientation with respect to the rope, said biasing direction, for which the rope is solicited by deformation. Thus, for measuring the tension of the racket rope, the relative rotation between the gripping body 10 and the biasing member 2 is measured via the potentiometer once the gripping body 10 has been rotated about the axis of rotation ROT1 until to obtain the desired orientation of said biasing member 2 with respect to the rope 9. Alternatively, it could be provided to turn the gripping body 10 to a predefined orientation of the gripping body. It can then be provided in this case that the detection means 6 of the rope are integral with the gripping body 10.

Said biasing orientation may correspond to the superposition of the straight line passing through two distinct points of the biasing member 2 or of the gripping body 10, with the straight line passing through the cord 9. In the example illustrated in the figures, said points of the biasing member 2 serving as a reference, for alignment with the rope 9, are the two opposite zones of the biasing member 2 which respectively carry the potentiometer 5 and the detection cells 6. Said biasing orientation can also correspond to a given angle of rotation of the gripping body 10 or of the biasing member 2 with respect to a bearing configuration of the bearing elements 21, 22 against the rope 9.

When the sphygmomanometer is equipped with means for detecting the cord 6, said biasing orientation corresponds simply to the orientation of the grasping body 10 or of the biasing member 2 for which the detection means 6 detect the cord. that is to say lie at the right of the rope.

As illustrated in FIGS. 3 and 3A, for a right-handed person, the tensiometer is positioned astride by its pads 21, 22 so that the grasping body 10 can be turned clockwise until the desired orientation of the biasing member 2 relative to the rope, in particular until a positioning of the rope detecting means 6 to the rope. Similarly for a left-handed person and as illustrated in FIGS. 4 and 4A, it is sufficient to position the saddle member 21 by its studs 21, 22 so that the gripping body 10 can be turned counterclockwise.

During the rotation of the gripping body 10, the two bearing elements 21, 22 exert a torque on the rope 9 which more or less deforms the rope as a function of its initial tension, that is to say in the absence of solicitation.

The more the rope is stretched, the more the relative rotation between the gripping body 10 and the biasing member 2 will be important to bring the biasing member 2 or the gripping body 10 in the desired orientation with respect to the string, while that the more the rope is relaxed plus the biasing member and the deformable member 3 will naturally follow the rotational movement of the gripping body 10 and less the relative rotation between gripping body 10 and biasing member 2 will be important. This relative rotation between the gripping body and the biasing member corresponds to the angle of rotation of the pinion 7 of the potentiometer 5 resulting from the engagement between toothed wheel 10 and pinion 7 following the rotational movement applied by the operator to the gripping body. 10. The axis of rotation ROT1 is orthogonal to the plane of the strings which makes it possible to easily apply a torque via the biasing member 2 to a rope 9 inside the racket frame with great freedom and ease of handling. tensiometer.

The choice of such an axis of rotation ROT1 of the base body, orthogonal to the plane of the strings, to deform the rope, allows to design the biasing member 2 in the form of two studs 21, 22, of generally cylindrical shape, spaced apart from each other and connected by a support or plate 20, it is sufficient to position directly straddling a rope 9. The pads 21, 22 project from the plate 20 being spaced apart. one of the other following a direction orthogonal to their direction of projection so as to be mounted astride a rope. In the state positioned astride the biasing member on the rope, the plate 20 which connects the two studs extends on one side of the frame of the racket, which facilitates the positioning of the two studs 21, 22 on either side of the rope 9 and thus the manipulation of the tensiometer. In particular, the user can easily turn the input body along the desired axis without being disturbed by the strings.

The two support elements 21, 22 of the biasing member 2 extend substantially parallel to each other and orthogonally to the mean plane of said gripping body 10 or to the middle plane of the plate 20.

The present invention is in no way limited to the embodiments described and shown, but the person skilled in the art will be able to make any variant of it in accordance with his spirit.

Claims (10)

REVENDICATIONS1. A sphygmomanometer (1) for measuring the tension of a racket rope (9), said tension meter (1) comprising: - a so-called grasping body (10), - a stressing member (2) for the rope (9) ) by deformation of said rope, said biasing member (2) comprising at least two support elements (21, 22) spaced apart from each other, such as studs or fingers, positionable on either side of an individual rope (9), - a deformable element (3) connected to the gripping body (10) and to the biasing member (2) of the rope, said deformable element (3) being, in the state straddling the rope (9) of the two support elements of said biasing member (2), deformable by rotation of said gripping body (10) about a transverse axis (ROT1) to the rope and parallel to the median plane 15 passing between said support elements (21, 22) straddling the rope (9), said tension meter (1) being equipped with means for measuring the relative rotation between the body of grasping and the biasing member, characterized in that said measuring means are formed by a potentiometer (5) and actuating means (7, 10) of the potentiometer, said potentiometer (5) and at least a part ( 10) said actuating means being integral, one of the gripping body (10) and the other of the biasing member (2). 25 2. A blood pressure monitor according to claim 1, characterized in that said potentiometer (5) being of the rotary type, the control shaft (57) of said potentiometer (5) carries a gear (7), such as a meshing gear , capable of meshing with meshing means (10) forming said at least a part of said actuator means (10) of the potentiometer. 30 3. A blood pressure monitor according to claim 2, characterized in that, said potentiometer (5) being integral with the biasing member (2), said meshing means comprise a toothed wheel integral with the gripping body (10). 4. The blood pressure monitor according to claim 3, characterized in that said toothed wheel and the gripping body (10) are formed in one piece. 5. Tensiometer according to one of the preceding claims, characterized in that said deformable element (3) comprises a portion (3A, 3B) connected to the gripping body (10) at two points opposite to the axis of rotation ( ROT1) of said gripping body, and another connected part (3C, 3D) to the biasing member (2) at two points opposite to the axis of rotation (ROT1) of said gripping body. 6. Tensiometer according to one of the preceding claims, characterized in that the deformable element (3) has the general shape of a cross whose branch (3A, 3B) is coupled to or near its ends the gripping body (10) and the other branch (3C, 3D) is coupled to or near its ends to the biasing member (2). 7. Tensiometer according to one of the preceding claims, characterized in that the deformable element is made of elastomer, preferably Styrene Ethylene Butylene Styrene (SEBS). 8. Tensiometer according to one of the preceding claims, characterized in that, the deformable element (3) comprising at least one elongated portion (3A, 3B), the longitudinal axis of said elongated portion (3A, 3B) of said deformable element (3) is, in the absence of biasing the gripping body (10), substantially coplanar with the axis of rotation (ROT1) of the gripping body (10) defined by the axis which is included in the plane median passing between said support members (21,22) for overlapping the rope (9) and which is perpendicular to the axis of the rope passage delimited between the two support members (21,22). 9. Tensiometer according to one of the preceding claims, characterized in that it comprises means for calculating the tension of the rope (9) from the measurement of the relative rotation between the gripping body and the biasing member. . 10. A method for determining the tension of a racket rope (9) with the aid of a tensiometer (1) according to one of the preceding claims, characterized in that said method comprises the following steps: positioning the urging member (2) of the horse-drawn sphygmomanometer by its two support elements (21, 22) on an individual rope (9), - turning the tensioning device (10) of the tensiometer until an orientation is obtained predefined lo of the biasing member (2), or the gripping body (10), with respect to the rope (9), in which the two supporting elements (21, 22) of the biasing member exert a pair on the rope (9), - measuring the relative rotation between the gripping body and the biasing member, - calculating, from said measurement, the tension of the rope (9). 15