Classifications

• • A—HUMAN NECESSITIES
  • A63—SPORTS; GAMES; AMUSEMENTS
  • A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
  • A63B51/00—Stringing tennis, badminton or like rackets; Strings therefor; Maintenance of racket strings
  • A63B51/005—Devices for measuring the tension of strings
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01L—MEASURING FORCE, STRESS, TORQUE, WORK, MECHANICAL POWER, MECHANICAL EFFICIENCY, OR FLUID PRESSURE
  • G01L5/00—Apparatus for, or methods of, measuring force, work, mechanical power, or torque, specially adapted for specific purposes
  • G01L5/04—Apparatus for, or methods of, measuring force, work, mechanical power, or torque, specially adapted for specific purposes for measuring tension in flexible members, e.g. ropes, cables, wires, threads, belts or bands
  • G01L5/10—Apparatus for, or methods of, measuring force, work, mechanical power, or torque, specially adapted for specific purposes for measuring tension in flexible members, e.g. ropes, cables, wires, threads, belts or bands using electrical means
  • G01L5/102—Apparatus for, or methods of, measuring force, work, mechanical power, or torque, specially adapted for specific purposes for measuring tension in flexible members, e.g. ropes, cables, wires, threads, belts or bands using electrical means using sensors located at a non-interrupted part of the flexible member
• • A—HUMAN NECESSITIES
  • A63—SPORTS; GAMES; AMUSEMENTS
  • A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
  • A63B2220/00—Measuring of physical parameters relating to sporting activity
  • A63B2220/20—Distances or displacements
  • A63B2220/24—Angular displacement
• • A—HUMAN NECESSITIES
  • A63—SPORTS; GAMES; AMUSEMENTS
  • A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
  • A63B2220/00—Measuring of physical parameters relating to sporting activity
  • A63B2220/50—Force related parameters
  • A63B2220/54—Torque
• • A—HUMAN NECESSITIES
  • A63—SPORTS; GAMES; AMUSEMENTS
  • A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
  • A63B2220/00—Measuring of physical parameters relating to sporting activity
  • A63B2220/50—Force related parameters
  • A63B2220/58—Measurement of force related parameters by electric or magnetic means
• • A—HUMAN NECESSITIES
  • A63—SPORTS; GAMES; AMUSEMENTS
  • A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
  • A63B2220/00—Measuring of physical parameters relating to sporting activity
  • A63B2220/80—Special sensors, transducers or devices therefor
  • A63B2220/83—Special sensors, transducers or devices therefor characterised by the position of the sensor

Definitions

• the present invention generally relates to tension measuring apparatus for string-type elongated element.
• the invention more particularly relates to an individual tensiometer for measuring the tension of a racket rope, said tensiometer comprising:
• seizure body capable of being manually grasped
• said biasing member comprising at least two support elements spaced apart from one another, such as studs or fingers, positionable on either side of an individual rope,
• said gripping body and said biasing member being displaceable in each other substantially in a relative pivotal movement
• Said relative angle corresponds to an elongation of the helical spring biased in tension.
• the tensiometer described in US Pat. No. 5,481,926 operates only in a single direction of rotation of the gripping body corresponding to the direction in which the spring can be elongated. Such a solution thus poses problems for left-handed people when the tensiometer is designed for right-handed people and vice versa.
• the present invention aims to provide a tensiometer that is easily manipulated for both left-handed and right-handed.
• Another object of the present invention is to provide a solid tensiometer that provides reliable and accurate voltage measurement.
• Another object of the present invention is to provide a tensiometer for which the user can easily and quickly determine the tension of a rope.
• the subject of the invention is an individual tensiometer for measuring the tension of a racket rope, said tensiometer comprising: a body, called a seizure body, capable of being manually grasped,
• said biasing member comprising at least two support elements spaced apart from one another, such as studs or fingers, positionable on either side of an individual rope,
• said gripping body and said biasing member being displaceable in each other substantially in a relative pivotal movement
• the gripping body and the biasing member have relative to each other two possibilities of pivoting with respect to said neutral position, namely a first possibility of pivoting in a first direction and a second possibility pivoting in a second direction opposite to the first direction.
• the relative rotation between the gripping body and the biasing member or the deformation of said return means 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.
• the biasing means connect the gripping body to the biasing member so that said biasing means limit the relative rotation between the gripping body and the biasing member by acting against this relative rotation.
• the measurement of said relative rotation corresponds to a measurement of the deformation of the return means which itself depends on the tension of the rope. So, the measuring the relative rotation between the gripping body and the biasing member makes it possible to determine the tension of the rope.
• the tensiometer according to the invention Thanks to the possibility offered by the tensiometer according to the invention to rotate, by reference to a neutral position, the seizure body with respect to the biasing member in one direction and the other, said tensiometer is easily manipulated too good for a left-handed person than for a right-handed person. 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 return means, can be detected in both directions using the measuring means as detailed below.
• said magnitude representative of the relative rotation between the input body and the biasing member may be a characteristic of an electrical signal associated with at least one element or system called resistive and having a variable resistance. function of the relative rotation between the input body and the biasing member.
• resistive an element or system
• said electrical voltage varying as a function of the resistance value of said resistive element or system and therefore as a function of the relative rotation between the input body and the urging member.
• Said calculation means can then convert the measured voltage value into a string voltage value using a mathematical formula and / or charts.
• said measuring means comprise first means for measuring a magnitude representative of the relative rotation between the gripping body and the biasing member according to said first direction with respect to said neutral position, and second means for measuring a magnitude representative of the relative rotation between the gripping body and the biasing member along said second direction relative to said neutral position.
• said first and second measuring means are common.
• said biasing means have a first possibility of efo rm ation in any one corresponding to said first direction of pivoting of the gripping body with respect to the biasing member and a second possibility of deformation in one direction. corresponding to said second direction of pivoting of the gripping body with respect to the biasing member.
• the gripping body and the biasing member have, relative to each other, on each side of the neutral position, an angular displacement stroke of at least 10 °.
• said biasing means and the biasing member are arranged in such a way that that the median plane passing through the support members straddling the rope forms, in the neutral position, a plane of symmetry for said return means and / or a plane in which said return means extend.
• the said return means present, in absolute value, a deformation stroke substantially identical to that they have when the gripping body pivots relative to the biasing member, said given angle relative to the neutral position, in the other direction.
• said measuring means comprise a linear potentiometer having a variable linear resistance and an adjusting member of said resistor, called a slider, said slider being movable along at least a part of said resistor.
• linear variable said variable linear resistance and said slider being coupled one to the input body and the other to the biasing member.
• Said measuring means comprise a linear potentiometer whose ohmic value is modified when the gripping body is rotated in one direction and in the other, which makes it possible to measure the relative rotation between the gripping body and the biasing member in both directions .
• a linear potentiometer makes it possible to benefit from a solid tensiometer of simplified design which offers a reliable and precise measurement of tension.
• Such a design of the tensiometer using a linear potentiometer makes it possible to imitate the thickness of the tensiometer.
• the slider has a reduced dimension that allows for a thin gauge tensiometer. Said thickness corresponds to the dimension of the tensiometer in a direction parallel to the axis of pivoting of the gripping body with respect to the biasing member.
• the use of a linear potentiometer makes it easy to vary the resistance as a function of the pivoting of the gripping body relative to the biasing member by coupling the slider and the linear resistance, one to the gripping body and the other to the biasing member.
• the modification of the ohmic value of the potentiometer as a function of the relative rotation between the input body and the biasing member makes it possible to supply the calculation means with a quantity representative of the relative rotation between the input body and the input. solicitation organ.
• Said magnitude may be an electrical voltage between a terminal corresponding to the ground of the potentiometer and u no terminal corresponding to cu rseu rdu potentiometer.
• Said magnitude can be processed by said calculating means to determine the corresponding voltage of the string. In particular, it is possible to filter and / or amplify the signal, corresponding to said quantity, acquired by the calculation means.
• said tensiometer comprises activation and deactivation means able to control the activation and deactivation of said calculating means as a function of the relative pivot angle between the input body and the solicitation organ.
• said biasing member comprises an arm pivotally mounted relative to the gripping body and said biasing means comprise two helical springs, for example of generally at least partially cylindrical and / or at least partially conical shape. , optionally formed in one piece, which extend on either side of the axis of the arm, preferably at or near the free end of said arm. Realisation of the return means in the form of helicoidal springs distributed on either side of the axis of the arm reliably removes the arm in said neutral position.
• said arm comprises means for coupling to the cursor of the potentiometer, said coupling means being configured so as to move the cursor in the direction of pivoting of the arm while leaving the cursor free to move. move on a given stroke along the axis of said arm.
• said measuring means comprise a rotary potentiometer which comprises a variable resistor and a rotary control shaft making it possible to vary the resistance value, said variable resistor and the control axis. being coupled, one to the biasing member and the other to the gripping body.
• led it control axis carries a gear, such as a meshing gear, adapted to mesh with a toothed wheel integral with the gripping body.
• a gear such as a meshing gear
• said toothed wheel and the gripping body are formed in one piece.
• 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 easy and reliable to use the relative rotation between the input body and the biasing member for modifying 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.
• the modification of the resistance value of the potentiometer as a function of the relative rotation between the gripping body and the biasing member makes it possible to provide the calculation means with a magnitude representative of the relative rotation between the gripping body and the biasing member.
• Said magnitude may be an electrical voltage between a terminal corresponding to the ground of the potentiometer and a terminal corresponding to the control axis of the potentiometer. Said magnitude can be processed by said calculating means to determine the corresponding voltage of the string. In particular, it is possible to filter and / or amplify the signal, corresponding to said quantity, acquired by the calculation means.
• said 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 portion, with the pinion carried by the control shaft of the potentiometer without the need to add additional meshing means.
• said biasing means comprise a part connected to the gripping body at two opposite points with respect to the axis of rotation corresponding to the pivoting mobility of the gripping body with respect to the gripping member. biasing, and another portion connected to the biasing member at two opposite points with respect to said axis of rotation.
• said biasing means affect the general shape of a cross whose branch is coupled to or near its ends to the gripping body and whose other branch is coupled to or near its ends to the organ of solicitation.
• the relative rotation between the gripping body and the biasing member is translated by bending 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 due to its planes of symmetry and sandwiched between the gripping body and the biasing member being centered on the axis of rotation of the gripping body.
• the connecting means of said biasing means to the gripping body and the connecting means of said biasing means to the biasing member are each formed by at least two sets of tenons and tenon insertion orifices, each set being disposed on either side of the axis of rotation of said tension meter, in the assembled state of the tensiometer.
• said return means are made of elastomer, preferably Styrene Ethylene Butylene Styrene (SEBS).
• SEBS Styrene Ethylene Butylene Styrene
• said biasing means comprise at least one elongate part and the opposite ends of the elongated part of the deformable element are connected to two points of the gripping body, preferably at two diametrically opposite points with respect to the axis of rotation corresponding to the pivotal mobility of the gripping body relative to the biasing member.
• said biasing means comprise at least one elongate part, the longitudinal axis of said elongated part of said deformable element is, in the absence of biasing the gripping body, substantially coplanar with the axis rotation of the gripping body defined by the axis which is included 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 support elements .
• said return means are substantially centered on the axis of rotation of the body of its isie of the tensiometer, which allows to have a substantially identical behavior in deformation of said biasing means 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 said biasing means with respect to the axis of rotation of the input body also simplifies the design and manufacture of the tensiometer while providing an accurate and reliable measurement of the tension of the rope 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.
• the modification of the resistance value of the potentiometer as a function of the relative rotation between the gripping body and the biasing member makes it possible to provide the calculation means with a quantity representative of the relative rotation between the gripping body and the body. solicitation which can be processed by said calculating means to determine the corresponding tension of the string.
• said biasing means comprise a flexible element, preferably a flexible blade
• said measuring means comprise at least one strain gauge positioned on said flexible element.
• Bending of the flexible element causes a stretch of the resistive son of the or each gauge, which modifies their resistance value and thus allows to deduce the flexion of the flexible element.
• the bending deformation of the flexible 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.
• the relative rotation between the gripping body and the biasing member, in one direction and in the other, causes a flexion of the flexible element which can be detected in both directions, for example with one and the same set of Onboard pressure gauge (s) on the blade.
• At least one strain gauge makes it possible to provide a magnitude representative of the flexion of the flexible element that can be processed by calculation means to determine the corresponding tension of the rope. More specifically, the modification of the ohmic value of said at least one strain gauge as a function of the relative rotation between the gripping body and the biasing member makes it possible to provide the calculation means with a magnitude representative of the relative rotation between the grasping body and the biasing member.
• Said magnitude may be an electrical voltage taken at said at least one strain gauge.
• Said magnitude can be processed by said calculating means to determine the corresponding voltage of the string. In particular, it is possible to filter and / or amplify the signal, corresponding to said quantity, acquired by the calculation means.
• the gripping body is an annular body, for example of ellipsoidal shape.
• the flexible element is an elongated element which extends inside the space delimited by said annular gripping body. In the unsolicited state, said flexible element is in the form of a plane blade.
• the opposite ends of the flexible element preferably the flexible blade, are connected to two distinct points of the gripping body, preferably at two diametrically opposite points.
• the biasing member is fixed on the flexible element, preferably the flexible blade, between and spaced from the two ends of the flexible element, preferably in the central zone of the length of said flexible element.
• the flexible element being an elongate element having a longitudinal axis orthogonal to its axis of flexion
• the measuring means are located at least partly between the biasing member and the end or the end. one of the ends of the flexible element connected to said gripping body, preferably in the middle of the length between the biasing member and said end of said flexible member.
• the flexible element being an elongated element
• the longitudinal axis of the flexible element is substantially coplanar with the axis of rotation of the gripping body defined by the axis which is included 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 support elements.
• the flexible element formed for example by a flexible beam or blade is substantially centered on the axis of rotation of the gripper body of the tensiometer, which allows to have a substantially identical behavior in flexion of the flexible element in one sense and in the other, and thus to determine reliably and quickly the tension of a rope that is deformed in one direction or the other.
• Such an arrangement of the flexible member with respect to the axis of rotation of the grasping body also simplifies the design and manufacture of the tensiometer while providing an effective measure of the tension of the rope from the bending of the element. flexible in one direction of bending or in the other, corresponding to a rotation of the body of its isie in one direction or the other depending on whether the user is right handed or left handed.
• the tensiometer is equipped with string detection means configured to transmit, when they are located at the right of said chord, a control signal for storing said quantity measured by said measuring means.
• 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:
• FIG. 1 is an exploded perspective view from below of a first embodiment of the tensiometer according to the invention
• FIG. 2 is an exploded perspective view from above of the tensiometer of FIG. figure 1 ;
• FIG. 3 is a view from below of the tensiometer of FIG. 1, for which a portion of the housing is not shown, in the straddling state, in the use configuration for a right-handed person, and before deformation said rope;
• FIG. 3A is a view from below of the tensiometer of FIG. 3, in the state straddling the rope and in the rotated state of the grasping body, until the desired orientation of said body with respect to the rope is obtained. ;
• FIG. 4 is a view from below of the tensiometer of FIG. 1, for which a portion of the housing is not shown, in the straddling state, in the configuration of use for a left-hander, and before deformation. said rope;
• FIG. 4A is a view from below of the tensiometer of FIG. 4, in the state straddling the rope and in the rotated state of the gripping body, until obtaining the desired orientation of said body relative to the rope;
• FIG. 5 is an exploded top view of a tensiometer according to a second embodiment of the invention.
• FIG. 5A is an exploded bottom view of the tensiometer of FIG. 5;
• FIG. 6 is a view from above of the tensiometer of FIG. 5 in the assembled state
• FIG. 6A is an axial sectional view of the tensiometer of FIG. 6 along the line A-A;
• Figure 6B is a side view of the tensiometer of Figure 6;
• FIG. 7 is a top view of the tensiometer of FIG. 6, in the state straddling 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. 7A is a top view of the tensiometer of FIG. 7, in the state straddling a rope in the configuration of FIG. 7 and in the turned state of the gripping body in the clockwise direction until detection of the rope;
• FIG. 8 is a view from above of the tensiometer of FIG. 6, in the state straddling a rope, before deformation of said rope, being positioned in order to apply a rotational movement to the seizure body in the meaning counterclockwise, preferably for a left-handed person;
• FIG. 8A is a top view of the tensiometer of FIG. 8, in the straddling state and in the rotated state of the gripping body in the counterclockwise direction until the rope is detected;
• FIG. 9 is a perspective view of a tensiometer according to a third embodiment of the invention.
• FIG. 9A is a bottom view of the tensiometer of FIG. 9;
• FIG. 9B is a side view of the tensiometer of FIG. 9;
• FIG. 10 is a view from above of the tensiometer of FIG. 9 in the state straddling a rope, before deformation of said rope;
• FIG. 10A is a side view of the tensiometer of FIG. 10, in the state straddling the rope, before deformation of said rope;
• FIG. 11 is a view from above of the tensiometer of FIG. 9, in the state straddling a rope and in the rotated state of the gripping body, until the desired orientation of said body with respect to the rope ;
• Figure 1 1 A is a side view of the tensiometer of Figure 1 1 in engagement with the rope.
• the invention relates to an individual blood pressure meter 1 for measuring the tension of a racket rope 9.
• Said rope whose voltage is to be measured is recessed at or near its ends on the racket frame (not shown).
• Said sphygmomanometer comprises a body, said input body 10, which can be grasped manually. Led it tensiometer also comprises a biasing member 2 of the rope 9 by elastic deformation of said rope.
• Said biasing member 2 comprises at least two support elements 21, 22 spaced from each other, such as studs or fingers, positioned on either side of an individual rope 9. The two support elements 21, 22 are called pins. Said pins are carried by a plate 20 of the biasing member.
• Said gripping body 10 and said biasing member 2 are movable in relation to each other in a relative rotational movement. Led it pivotal movement substantially corresponds to a pivot about the axis of rotation ROT1 orthogonal to the rope and in the median plane passing between said pins overlapping the rope.
• Said sphygmomanometer also comprises elastically deformable return means 3 connected to the gripping body 10 and to the biasing member 2 of the cord.
• Said return means 3 are configured to recall the input body 1 0 and the biasing member 2 relative to each other in a given angular position, said neutral position.
• Said neutral position corresponds to a configuration in which said gripping body 10 and the biasing member 2 are not solicited by the user, that is to say are not solicited, one with respect to the other, by no rotational force on the part of the user.
• Said resiliently deformable return means 3 can be fixed to the gripping body 10 and to the biasing member 2 or simply inserted between the gripping body 10 and the biasing member 2.
• Said tensiometer also comprises means for measuring a physical quantity representative of the relative rotation between the input body 10 and the biasing member 2 and means for calculating the tension of the string according to said measured quantity. Said measuring means and the corresponding measured quantity are detailed below.
• the blood pressure monitor comprises an electronic system and computer, such as a microprocessor which comprises said calculating means and which is connected to said measuring means for enabling acquisition of the quantity measured by said measuring means and calculation by said calculating means of the tension of the rope in function of said measured quantity.
• a microprocessor which comprises said calculating means and which is connected to said measuring means for enabling acquisition of the quantity measured by said measuring means and calculation by said calculating means of the tension of the rope in function of said measured quantity.
• Said calculation means may be implemented in the form of computer instructions implemented in said electronic and computer system.
• the gripping body 10 and the biasing member 2 have, relative to one another, two possibilities of pivoting with respect to said neutral position of return of the gripping body and the solicitation organ.
• the gripping body 10 and the biasing member 2 have a relative to a first possibility of pivoting in a first direction, adapted to a right-handed person, and a second possibility of pivoting in a second direction, adapted to a left-handed person, opposite in the first sense.
• said tensiometer can be used both by a left-handed person than by a right-handed person.
• the gripping body 10 and the biasing member 2 are able to pivot relative to each other, in one direction and the other with respect to said neutral position.
• the tensiometer comprises a physical pivot connection between said grasping body and said biasing member.
• the pivotal mobility of the gripping body with respect to the biasing member is formed in the positioned state of the pins. the biasing member on either side of the rope resting on the rope.
• the gripping body is pivotable with respect to the biasing member. taken with the rope, around said axis of rotation transverse to the rope and parallel to the median plane passing through said pins overlapping the rope.
• said neutral angular position corresponds to a configuration in which said gripping body 10 and the biasing member 2 are not biased relative to each other, no rotational force external to the tensiometer 'being applied to the biasing member or to the grasping body.
• said neutral position corresponds to an equilibrium configuration of the gripping body and the biasing member relative to each other.
• Said calculation means are configured to calculate the tension of the rope as a function of said quantity measured by said measurement means following pivoting in one direction or the other between the gripping body 10 and the biasing member 2 relative to at the neutral position of the gripping body 10 and the biasing member 2.
• the measurement means comprise a linear potentiometer 5.
• Said measuring means are also formed by the electronic and computer system which is configured to acquire a magnitude or signal, such as a voltage measured at the level of the potentiometer, whose value depends on the resistance of the potentiometer 5.
• Said measured quantity corresponds to the resistance of said linear potentiometer which varies as a function of the position of the cursor 51 along said linear resistance 50, said position of the slider 51 itself being a function of the relative rotation between the input body 10 and the biasing member 2.
• Said potentiometer 5 is connected to the electronic and computer system which acquires said quantity or signal whose value depends of the resistance value of the potentiometer.
• Said calculation means which are part of said electronic and computer system calculate the tension of the string corresponding to the measured quantity or signal whose value depends on the resistance of the linear potentiometer.
• the combination of said linear potentiometer and the electronic and computer system which comprises said calculating means makes it possible to measure the relative rotation between the gripping body and the biasing member and therefore the tension of the string.
• the measurement means comprise a rotary potentiometer 16.
• Said measuring means are also formed by the electronic and computer system which is configured to acquire a magnitude or signal, such as a voltage measured at the potentiometer, the value of which depends on the resistance value of the rotary potentiometer 16.
• Said measured quantity depends on the resistance of said rotary potentiometer which varies as a function of the angular position of the axis 57, said angular position of the control axis being itself a function of the relative rotation between the gripping body and the biasing member.
• Said rotary potentiometer 5 is connected to the electronic system and i nformatiq ue q u i acq u iert l ad ite size value associated with the potentiometer.
• the means of calculation which are part of the electronic and computer system calculate the tension of the string corresponding to the value of said measured quantity which depends on the resistance of the rotary potentiometer.
• the combination of said rotary potentiometer and the electronic and computer system which comprises said calculating means makes it possible to measure the relative rotation between the gripping body and the biasing member and thus the tension of the string.
• said measurement means comprise at least one strain gauge 35.
• Said measuring means are also formed by the electronic and computer system which is configured to acquire a quantity or signal, such as an electrical voltage measured at said at least one strain gauge, the value of which depends on the resistance value of said at least one strain gauge 35.
• Said measured quantity depends on the resistance of the resistive wires that make up the or each strain gauge, said resistance varying as a function of the stretching of said gauge, which is itself a function of the bending of the blade and therefore of the relative rotation between the gripping body and the biasing member.
• Said or each strain gauge is connected to the electronic and computer system which acquires said quantity which depends on said resistance value of the or each strain gauge.
• Said calculation means which are part of said electronic and computer system calculate the tension of the string corresponding to said measured quantity whose value depends on the resistance value of the or each strain gauge.
• the combination of the or each strain gauge and the electronic and computer system which comprises said calculating means makes it possible to measure the relative rotation between the gripping body and the biasing member and thus the tension of the string.
• Said elastically deformable return means 3 are, in the state astride the cord of two elements of a solenoid or urging device, deformable by rotation of said gripping body about an axis transverse to the rope and in the median plane passing through said support members straddling the rope.
• the gripping body 10, the biasing member 2, the return means 3 and said measuring means are configured to allow the gripping body 10 and the biasing member 2 to pivot relative to each other, in one direction and the other with respect to said neutral position.
• Said measuring means are able to measure a magnitude representative of the relative rotation between the gripping body 10 and the biasing member 2 in one direction and the other with respect to said neutral position.
• said measurement means comprise a linear potentiometer 5
• the slider 51 of the linear tensiometer, in the neutral position of the input body 1 0 and of the biasing member 2 is located substantially at the end of neck of the linear resistance.
• the control axis 57 of the rotational tensiometer, in the neutral position of the gripping body 10 and the actuator member. 2 is located substantially in the middle of the angular sector defined between the extreme angular positions that can take said control axis of the potentiometer in one direction and in the other of rotation relative to said neutral position of return.
• the or each strain gauge in the neutral position of the gripping body 10 and the organ 2, is not subject to any strain constraint.
• the or each strain gauge can follow the flexion of the flexible element in one direction and in the other, so as to deform in one direction of flexion of the flexible element and in the other to follow the flexion of said element flexible.
• Said return means 3 have a first possibility of deformation in a direction corresponding to said first pivoting direction of the gripping body 10 with respect to the biasing member 2 and a second possibility of deformation in a direction corresponding to said second direction of pivoting of the grasping body 10 with respect to the biasing member 2.
• said return means 3 are able to be deformed in one direction and in the other with respect to said neutral position of the gripping body 10 and of the biasing member 2.
• the deformation of the return means is representative of the relative rotation between the gripping body and the biasing member.
• the gripping body 10 and the biasing member 2 have relative to each other, on each side of the neutral position, a stroke, or range, of angular displacement at least equal to 10 °.
• Said return means 3 are able to deform on this stroke and the measuring means are also able to measure the rope tension corresponding to a deformation of said return means 3 on such a stroke.
• said return means 3 and the biasing member 2 are arranged such that the median plane passing through said pins 21, 22 straddling the rope, form, in the neutral position, a plane of symmetry for the said return means 3, as in the two embodiments of embodiments illustrated in FIGS. 1 to 8 and / or a plane in which extend said return means 3, as in the embodiment illustrated in Figures 9 to 1 1 for which said biasing means are formed by a flexible blade.
• said return means 3 and the biasing member 2 are arranged, dimensioned and / or oriented so that the median plane passing through said pins 21, 22 straddling the rope, forms, in the neutral position, a plane of symmetry for said return means 3 and / or a plane in which said return means 3 extend.
• the biasing means When the gripping body 10 pivots relative to the biasing member 2, in one direction, by a given angle with respect to the neutral position, said biasing means have, in absolute value, a deformation stroke substantially identical to that they present when the gripping body 10 pivots relative to the biasing member 2, said given angle relative to the neutral position, in the other direction.
• the calculation means can determining the tension of the string, from said quantity measured by the measurement means, with substantially similar calculation functions, possibly to the nearest sign.
• the calculation means make it possible to convert the measured quantity which depends on the resistance value of the resistive system used, for example a linear potentiometer, a rotary potentiometer, or at least one gauge. constraint, according to the embodiment implemented, in rope tension value.
• the calculation means comprise one or more calculation formulas and / or one or more curve (s) or table (s) of correspondence between the measured magnitude values and the voltage values of the string.
• 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.
• said calculation means only take into account a measured quantity value beyond a certain threshold value to provide a sufficiently reliable measurement of rope tension.
• the calculation means determine from said received magnitude 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 rope tension, 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.
• said detection means 6 are formed by a device comprising two detection cells, for example optical.
• the average 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 string, that is to say when the means of detection 6 are located at the right of the rope.
• 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.
• the gripping 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 the magnitude, such as an electrical voltage, associated with the resistive element or system used, for example a potentiometer or at least one strain gauge, for the purpose of reducing the voltage, regardless of subsequent movement of the sphygmomanometer.
• the value of the magnitude such as an electrical voltage, associated with the resistive element or system used, for example a potentiometer or at least one strain gauge, for the purpose of reducing the voltage, regardless of subsequent movement of the sphygmomanometer.
• Each detection cell may be an optical or sound-wave cell such as ultrasound.
• 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 rope tension value calculated by the calculation means .
• the method of measuring the tension of a rope using such a blood pressure monitor comprises the following steps:
• Said gripping body 10, or said biasing member 2 (via said gripping body and return means), is intended to be rotated about said axis of rotation ROT1 until the body 2, or said input body 10, has a given predetermined orientation with respect to the rope, said biasing orientation, for which the rope is biased by deformation.
• the relative rotation between the gripping body 10 and the biasing member 2 is measured once the gripping body 10, or the biasing member 2, has the desired orientation by
• 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 rope 9. Said points of the biasing member 2 serving reference, for alignment with the rope
• Said biasing orientation can also correspond to a given angle of rotation of the gripping body 10 or the biasing member 2 by relation to a configuration in support of support elements 21, 22 against the rope 9.
• 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.
• 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 with respect to the rope, in particular until a positioning of the rope detection means 6 to the right of the rope.
• 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 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 movement. manipulation of the blood pressure monitor.
• 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.
• 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.
• said measuring means comprise a linear potentiometer 5 having a variable linear resistance 50 and an adjusting member 51 of said resistor, called a slider, said slider being movable along at least a part of said variable linear resistor 50.
• Said variable linear resistor 50 and said slider 51 are coupled one to the input body 10 and the other to the biasing member 2.
• the resistance value of the potentiometer corresponds to the position of the slider along the variable resistor.
• Said sphygmomanometer comprises activation and deactivation means 27, 72 able to control the activation and deactivation of said calculating means by function of the relative pivot angle between the gripping body 10 and the biasing member 2.
• Said activation and deactivation means 27, 72 are configured to deactivate the calculation means, in particular the supply 40 of the calculation means, in unsolicited configuration of the gripping body with respect to the biasing member, and vice versa. . Beyond a given relative pivoting stroke of the input body 1 0 with respect to the biasing member 2, and vice versa, in one direction or the other, said activation and deactivation means are configured to activate the calculation means, in particular the supply of the calculation means.
• said activation and deactivation means are formed by a push-button 72 connected to the power supply of the heat sink means.
• the push-button 72 deactivates the power supply in the opposite of its depressed position in which it activates the power supply means.
• Said pusher 72 is returned to the extended position.
• Said activation and deactivation means are also formed by a portion of the biasing member 2 which presses the pushbutton 72 for a relative pivoting stroke between the gripping body 10 and the biasing member 2 greater than a given value. and which allows the button to return to the extended position for less pivotal travel.
• Said biasing member 2 comprises an arm 24 pivotally mounted relative to the gripping body and said biasing means 3 comprise two helical springs 31, 32, possibly formed in one piece, which extend on either side of the axis of the arm 24, preferably at or near the free end 23 of said arm 24.
• Said springs which form said biasing means are preferably compression springs.
• Said arm 24 is pivotally mounted relative to the gripping body at or near its end 200 opposite said free end 23 in contact with the return means 3.
• Said end 200 has a male part forming in cooperation with a part corresponding female 121 of the seizure body a pivot connection. Alternatively, the male part could be arranged on the gripping body and the female part on the biasing member.
• Said return means 3 extend on either side of the longitudinal axis of the arm 24 to allow said return means to exert a return force on the arm 24 in the neutral position whatever the direction in which the grasping body 10 is pivoted with respect to the biasing member 2.
• one of the springs has an end adapted to be applied on one side of the free end 23 of the arm 24, the other spring having an end adapted to be applied on the opposite side of the end.
• free 23 of the arm 24 relative to the longitudinal axis of said arm.
• the opposite end of each spring is applied or bonded to a part of the gripping body 1 0.
• the free end 23 of the arm 24 has on each side intended to receive an end of a spring, centering means of said spring for allow a good maintenance and good guidance of the spring during the relative rotation between arm 24 and gripping body 10.
• Said return means 3 are arranged in a housing 30 which has at least one guiding wall, preferably two opposite guiding walls, for guiding the deformation of the return means during the pivoting of the gripping body 10 relative to to the biasing member 2, in one direction and the other.
• Said or each guide wall extends along a center circle arc corresponding to the pivot connection between the gripping body 10 and the biasing member 2. Said or each guide wall thus makes it possible to guide the deformation of the return means during their deformation in compression and / or in tension when they are biased by the rotation of the gripping body 10 pivoted relative to the biasing member 2 in one direction and the other.
• Said tensiometer also comprises abutment means 36 for abutting each spring 31, 32 or each spring portion capable of being applied on one side of the free end 23 of the arm 24.
• Said means for setting stop 36 allow to retain one of the spring or one of the spring portions when the other spring or the other spring portion is compressed (e) by the arm 24, which provides a reliable measurement of the magnitude representative of the relative rotation between the gripping member and the basic body.
• said abutment means 36 comprise a lug formed on one or each of the walls for guiding the deformation of the springs or springs.
• Said or each lug is centered on the displacement stroke of the arm, so that in equilibrium position of the arm 24, the or each lug is substantially in alignment with the arm 24 without hindering its pivotal movement in one direction or in the other.
• said abutment means 36, the spring or springs 31, 32 and the arm 24 are arranged in such a way as to limit or even eliminate, in equilibrium position, the clearance between the spring or springs and the end 23 of the arm 24.
• Said abutment means 36 make it possible to preload the springs or spring portions located on either side of the end 23 of the arm 24, in the neutral position of the arm 24, which allows, during the rotation of the gripping body 10, measuring a magnitude corresponding to the relative rotation between the gripping body 10 and the biasing member 2, accurately and reliably from the first degree of relative rotation.
• each spring 31, 32 or spring portion can be prestressed (e) by means of abutment 36 of a value corresponding to a given string tension, for example of the order of 10 kg, since the measured cord tension values are generally greater than 10 kg.
• the deformation of a spring or part of the spring corresponds to a torque applied to the rope due to the rotation of the gripping body.
• each spring 31, 32 or each part of the spring facing the free end 23 of the arm 24 the operator benefits from the length of the arm to compress said spring 31, 32 or said spring portion, this allows it to apply a large torque to the rope and thus easily and reliably measure important rope tension values.
• the linear resistor 50 is integral with the input body 1 0.
• Said arm comprises coupling means 25 to the slider 51 of the potentiometer.
• Said coupling means are configured so as to move the slider 51 in the direction of pivoting of the arm, that is to say in a direction transverse to the arm, while leaving the cursor 51 free to move on a stroke given along the axis of said arm.
• the slider 51 is situated substantially in the center of the possible displacement stroke of said slider on along the linear resistance 50.
• the arm 24 which forms a biasing element is in a neutral position substantially at the center of the angular sector which it is able to traverse relative to the gripping body.
• the axis of the arm 24 is in a neutral position substantially parallel to the longitudinal axis of the gripping body 10 which has a generally rectangular shape.
• Said input body 10 is present in the form of a housing formed of two half-shells intended to be fixed to each other preferably by screwing and inside which is intended to accommodate the arm 24.
• Said housing also houses the other elements tensiometer such as the return means 3, the measuring means and the calculation means.
• One of the half-shells of the housing has a through opening 120 to allow the two support members 21, 22 of the arm 2 to extend projecting from the housing.
• Said coupling means 25 are formed by an orifice, for example an oblong hole, preferably a through hole, formed in the arm and inside which the cursor 51 of the potentiometer 5 is housed.
• Said orifice 25 is configured; that is, dimensioned with respect to the slider 51 so as, on the one hand, to cause the slider 51 to move in a direction transverse to the arm, during the relative pivoting between the gripping body 10 and the biasing member 2, and, secondly, allow said cursor 51 to move a given distance along the longitudinal axis of the arm 2 to allow the cursor 51 to follow the rectilinear race path defined by the linear resistance 50.
• the dimension of the orifice 25 in the direction orthogonal to the axis of the arm is chosen so as to obtain a reduced or even substantially zero clearance with said cursor to enable the cursor 51 to be driven without delay along the resistance.
• Said housing comprises a display screen 42 connected to the calculation means housed inside the housing.
• Said screen is located on the half-shell opposite to that through which project the two support elements 21, 22 of the arm 24.
• Said screen can display information such as the tension state of a rope.
• the linear resistor is housed in a slotted parallelepipedal body to allow passage of the slider and define the displacement path of said slider along the linear resistance through the slit.
• the gripping body 10, in particular the one 10A of the two half-shells 10A, 10B comprises two stops 13 of end of pivoting stroke of the gripping body 10 with respect to the biasing member 2, in one direction and in the other. Said stops are positioned relative to the linear resistance so that, at the end of the pivoting stroke of the gripping body 10 with respect to the biasing member 2, the slider 51 remains spaced from the ends of the linear resistance in such a way that do not damage the linear potentiometer 5.
• said measuring means comprise a rotary potentiometer 16.
• said biasing member 2 forms a support for return means 3 and the input body. 10 as well as, as detailed below, the potentiometer 16 and the detection means 6 of the rope.
• said return means 3 are formed by a resiliently deformable member 3.
• 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 1 0 about an axis ROT1 transverse to the rope and in the plane median passing through said support elements 21, 22 straddling the rope 9.
• said deformable element is deformable by relative rotation of the gripping body by relative to the tension member, in one direction or the other, around the axis of rotation ROT1.
• Said tensiometer 1 comprises actuating means 7, 17 of the potentiometer 16. Said actuating means make it possible to modify the ohmic value of the potentiometer 16 as a function of the relative rotation between the gripping body and the biasing member.
• Said potentiometer 16 and at least a part 17 of said actuating means 7, 17 are integral, one of the biasing member 2 and the other of the gripping body 10.
• Said potentiometer 16 also called variable resistor, is a rotary potentiometer.
• a rotary potentiometer is generally formed of one or more resistive elements whose velocity can be modified progressively, without having to open the circuit, by rotating a control pin connected to a slider in contact with the resistant element or elements.
• said potentiometer 16 is integral with the biasing member 2.
• the control axis 57 of said potentiometer 16 carries a gear 7, such as a meshing pinion, capable of meshing with a toothed wheel 17 integral with the gripping body 10 and forming said at least a part 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 organ solicitation.
• Such a design of the tensiometer allows, by applying a rotational force to the gripping body 10, to mesh the toothed wheel 17 formed by said gripping body 1 0 with the pinion 7 of the potentiometer 16 on an angular sector, corresponding to the rotation relative between input body 1 0 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 16, which makes it possible to deduce the tension value of the string.
• the relative rotation between the gripping body and the biasing member corresponds to the rotational angle of the potentiometer 16 resulting from the meshing between the toothed wheel 17 and the pinion 7 following the rotation movement applied by the operator to the gripping body 10 .
• control axis of the rotary sphygmomanometer is located substantially at the angle of the angular sector defined between the extreme angular positions that the potentiometer can take in one direction and the other of rotation with respect to said neutral position of return.
• said toothed wheel 17 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 to the biasing member 2, of two gripping elements 1 1 opposite to the axis of the toothed wheel, corresponding to the axis of rotation ROT1.
• the input elements 11 allow the operator to apply a rotational force to the input body 10 in one direction and the other.
• the toothed wheel has an axial through hole 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 relative to the 2.
• Said connecting means are formed by a screw 12 whose thread cooperates with the part tapped 28 formed in the biasing member 2.
• a washer 18 threaded on the screw 12 is interposed between the screw head 1 2 and the gripping body 10 traversed by the screw 12 to allow the screw head 12 to take support on the upper face of said body of Saisiel O.
• 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.
• said deformable element 3 comprises a portion 3A, 3B reliée to the gripping body 1 0 at two points opposite to the axis of rotation ROT1 said gripping body, and another portion 3C, 3D connected to the biasing member 2 in two points opposite 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.
• deformable element 3 is in the form of a body with four lugs 3A, 3B, 3C, 3D arranged substantially at 90 ° to each other around the l axis of rotation of the gripping body.
• Said body of the deformable element 3 is hollowed out centrally to allow the passage of the connecting means 12 of the input body 1 0 to the biasing member 2.
• Said ears 3A, 3B, 3C, 3D are drilled to define housing insertion of lugs 14, 15, 33, 34 present, with respect to the lugs 3A, 3B, on the gripping body 10 and, with respect to the lugs 3C, 3D, on the biasing member 2.
• the tenons 14, 1 5 of the gripping body 10 are intended to engage in the openings of the lugs 3A, 3B and the tenons 33, 34 of the biasing member 2 are intended to engage in the openings of the ears 3C, 3D.
• the deformable element 3 has the general shape of a cross whose branch 3A, 3B is attached to or near its ends to the gripping body 10 and whose other branch 3C, 3D is attached to , or in the vicinity of, its ends to the biasing member 2.
• the deformable element is made of elastomer, preferably Styrene Ethylene Butylene Styrene (SEBS).
• SEBS Styrene Ethylene Butylene Styrene
• the branches 3A, 3B and 3C, 3D are centered on the axis of rotation ROT1.
• the potentiometer forms a means for converting electrical signals of the relative rotation between the input body and the biasing member or the deformation undergone by the deformable element.
• the rotational movement of the pinion 7 imposed by the toothed wheel 17 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. In the embodiment illustrated in FIGS.
• said return means 3 are formed by a flexible element.
• Said flexible element 3 is a flexible blade.
• the mean plane of the flexible blade 3, in the unsolicited state, is parallel to the axis of rotation ROT1 of the gripping body.
• said measuring means comprise at least one strain gauge 35.
• Said seizure body of said tensiometer is intended to be rotated about said axis of rotation ROT1 until said seizure body has a given predetermined orientation with respect to the rope, of said biasing orientation, for which the rope is urged by deformation.
• the bending of the flexible element is measured once the gripping body 10 is rotated about the axis of rotation ROT1 until the desired orientation of said gripping body 10 is obtained.
• Said biasing orientation may correspond to the superposition of the straight line passing through two distinct points of the gripping body 10, with the straight line passing through the rope 9.
• Said points of the gripping body 10 serving as reference, for the alignment with the rope 9, are the two opposite connection zones of the flexible element 3 to the gripping body 10.
• Said biasing orientation can also correspond to a given angle of rotation of the gripping body with respect to a configuration in support of the support elements 21, 22 against the rope 9.
• the rotation of the gripping body 10 about an axis ROT1 orthogonal to the string 9 and in the median plane passing through the support elements 21, 22 of the biasing member generates, on the one hand, a pair of the biasing member on the rope by bearing in the opposite direction of the two support elements 21, 22 on the rope, and, on the other hand, a bending deformation of the flexible element 3 to follow the rotation of the body of grasping 10 while the biasing member 2 is engaged with the rope.
• the two bearing elements 21, 22 exert a torque on the rope 9 which deforms more or less the rope according to its initial tension, that is to say in the absence of solicitation.
• the flexible element 3, which connects the gripping body 10 to the biasing member 2 in engagement with the rope 9, will all the more flex around its axis of flexion parallel to the axis of rotation ROT1, for follow the rotation movement of the input 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 rimet frame with great freedom and ease of handling of the rope. sphygmomanometer.
• the flexible blade 3 is then arranged so that its bending axis is parallel to the axis of rotation ROT1, that is to say orthogonal to the mean plane of the rope.
• the plate 20 which relays the two studs extends on one side of the frame of the racket, which facilitates the positioning of the two studs 21 , 22 on both sides of the rope 9 and therefore the manipulation of the tensiometer.
• 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 ladite at least one strain gauge is positioned on one face of the flexible blade 3. may provide to distribute at least one strain gauge on each of the faces of the flexible blade 3.
• said at least one strain gauge is positioned in the median zone of the portion of the flexible blade 3 located between the biasing member 2 and one of the 3B of the two ends 3A, 3B of the blade 3 connected to the input body 10 as detailed below. Indeed, it is in this area that bending deformation is the most important.
• said measuring means can be distributed over each of the two portions of the flexible blade 3 defined between the biasing member 2 and a flexible blade end connected to the gripping body 10.
• Said at least one strain gauge is also called the strain gauge.
• the or each strain gauge forms a means for converting the bending deformation undergone by the blade, and thus the relative rotation between the gripping body and the biasing member, into electrical signals that can be acquired by the calculation means.
• said calculating means connected to said at least one strain gauge acquires a variable resistance value as a function of the bending deformation of the blade.
• Said calculation means can be positioned in or on the input body.
• the body of its axis is a body, such as an ellipsoidal shape.
• the axis of rotation ROT1 of the input body is orthogonal to the mean plane of said input body.
• the flexible element 3 extends inside the space delimited by said annular gripping body.
• the opposite ends 3A, 3B of the flexible element 3 are connected to two distinct points of the annular gripping body 10, preferably at two diametrically opposite points.
• the biasing member 2 is fixed on the flexible element 3 between and spaced apart from the two ends 3A, 3B of the flexible element 3, preferably in the middle zone of the length of said flexible element 3.
• the flexible element 3 has a longitudinal axis A3 orthogonal to its axis of bending.
• Said measuring means are located, in the example illustrated in FIGS. 9 to 11, between the biasing member 2 and the one 3B of the ends 3A, 3B of the flexible element connected to said gripping body, preferably the middle of the length between the biasing member 2 and said end 3B of said flexible member 3.
• the flexible element 3 carries the biasing member 2 between its two ends 3A, 3B, preferably at half the length of said flexible element 3.
• the opposite ends of the flexible element 3 are connected to the gripping body 1 0 at points or opposite areas of the input body.
• At least one, preferably each, end 3A, 3B of the flexible elongated element, spaced apart from the biasing member 2 is coupled to the gripping body 10 so as to leave said flexible element 3 axial clearance with respect to said gripping body 10 (that is to say along the longitudinal axis of the flexible element in the undeflected state of said element) to absorb the variations in distance between the two ends 3A, 3B of the flexible element 3 during its bending, and, secondly, to prevent the displacement of said at least one end 3A, 3B along a direction transverse to the axis dud it flexible element 3. Said ite transverse direction to the axis is taken in the unsolicited state dud it flexible element 3, to allow said element to flex when the gripping body 10 is rotated by
• one of the ends 3A, 3B or each end 3A, 3B of the flexible element is housed in a slot, formed in the gripping body, whose sides sandwich the side portions of the portion end portion 3A, 3B of the flexible member accommodated in said slot, while said end portion 3A, 3B of the flexible element is able to sink more or less inside the slot according to its bending deformation.
• the longitudinal axis A3 of the flexible blade 3 is substantially coplanar with the axis of rotation ROT1 of the gripping body 10 defined by the axis which is included in the median plane passing through said bearing elements 21, 22 intended to overlap the rope 9 and which is perpendicular to the axis of the rope passage defined between the two bearing elements 21, 22.
• the longitudinal axis A3 of the blade extends substantially orthogonal to the axis of rotation ROT1 of the body of grasping or biasing member 2.
• the average plane of the blade is substantially coincident with the mean plane passing through the longitudinal axes of the two studs 21, 22.
• said tensiometer comprises means for initializing the calculation means.

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• Analytical Chemistry (AREA)
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• Health & Medical Sciences (AREA)
• General Health & Medical Sciences (AREA)
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• Physics & Mathematics (AREA)
• General Physics & Mathematics (AREA)
• Measurement Of The Respiration, Hearing Ability, Form, And Blood Characteristics Of Living Organisms (AREA)
• Devices For Conveying Motion By Means Of Endless Flexible Members (AREA)
• Force Measurement Appropriate To Specific Purposes (AREA)
• Measuring Pulse, Heart Rate, Blood Pressure Or Blood Flow (AREA)

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• 2011
  • 2011-03-03 WO PCT/FR2011/050449 patent/WO2011110777A2/fr active Application Filing
  • 2011-03-03 FR FR1151730A patent/FR2956983B1/fr active Active
  • 2011-03-03 US US13/578,692 patent/US8955398B2/en not_active Expired - Fee Related
  • 2011-03-03 EP EP11713847A patent/EP2544779A2/de not_active Withdrawn

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