FR3019643A1 - DEVICE AND METHOD FOR DETERMINING THE DIAMETER OF AN ORGAN - Google Patents

Abstract

The present invention relates to a device (1) provided with a base (10), a carriage (20) and a link (30) elongate. The device (1) has a measurement system (40) for determining a moving distance of said carriage (20). Said device (1) comprises a system for evaluating a mechanical tension for evaluating a mechanical tension exerted on said link (30) and a displacement means (25) for moving the carriage (20), said device (1) comprising a processing unit (60) connected to the mechanical tension evaluation system (50) and the measuring system (40), the processing unit (60) executing programmed instructions for storing position information provided by the measuring system when the voltage information supplied by the dynamometer reaches a threshold to determine and display said measured member diameter on said display means (65) in accordance with said stored position information.

Description

The present invention relates to a device and a method for determining the diameter of an organ, and in particular a section of an electrical harness. A system including an avionics system comprises a plurality of equipment interconnected by an electrical harness. The electrical harness then comprises a set of cables and / or wires. A beam is usually called "electrical harness". Nevertheless, the cables and wires of an electrical harness allow the circulation of electrical, electronic or even optical signals for example. Furthermore, an electrical harness may comprise a plurality of branches to join a plurality of separate devices. Each branch then has substantially circular sections. In addition, the electrical harness may comprise connectors connecting two branches together, for example, or still connecting a branch to an equipment. The electrical harness can undergo a protective hardening operation corresponding to a shield against electromagnetic interference. In particular but not exclusively, this protection is applied to electrical beams used in aeronautical and space applications.

A protective sheath can thus be arranged on one or more branches of a harness by applying a method of braiding or over-braiding. The method of braiding consists in putting on a sheath previously braided on a harness. On the other hand, the over-braiding method consists of braiding the sheath directly onto an electrical harness. We can refer to the document FR 2.871.286. These methods require to know precisely the diameter of each section of the electrical harness to be protected. Indeed, the diameter of a section of an electrical harness to protect conventionally represents an input parameter of a braiding or over-braiding system. A small error on the parameterized diameter can have adverse consequences on the performance of the obtained electrical harness. Such an error may, for example, affect the frequency band for which the electrical harness is protected against electromagnetic disturbances, or the tolerated disturbance levels.

The diameter of an electrical harness also affects the choice of certain components of the harness, for example in the choice of connectors. The determination of the diameter of a section of an electric harness may, however, be difficult.

Indeed, each section of a section has a plurality of cables and son arranged against each other. These cables and son may jointly have a certain flexibility making the diameter measurement difficult to reproduce.

Two different operators can then obtain two distinct values of a diameter, exerting different pressures on the section during the measurement. In addition, these cables and son themselves have different diameters. As a result, the arrangement of the cables and wires may differ between two different sections of a beam or depending on the pressure exerted during a diameter measurement. This characteristic of an electrical harness can have an influence on the measurements of the diameter of a section of a section of this electrical harness. As a result, accurate, reliable and repetitive measurement of the diameter of a wire harness is tricky with conventional measuring devices, such as calipers, for example.

Conventional devices do not respond to the need, because the measurement of the diameter of an electrical harness depends on the random arrangement of cables and wires constituting the electrical harness, the proper consistency of cables and wires, geometry taken by the measured section and the forces exerted on the electrical harness during the measurement. US 5,491,903 describes a tool provided with an envelope in which slides a graduated slide. In addition, the tool is provided with a rope extending from a first end connected to the slide to a second end connected to the slide or to the casing. From then on, the rope describes an open loop outside the envelope. The size of this loop varies depending on the position of the slider in the envelope.

In addition, a spring is arranged within the envelope. This spring is interposed between the bottom of the envelope crossed by the rope and the base of the slider connected to this rope. An operator then presses the slider to maximize the size of the open loop to insert the part to be measured. The spring then pushes the slider to tighten this rope around said piece. The graduations of the slide thus provide information relating to the dimension of the measured part.

Because of the presence of the spring, the rope does not always exert the same effort on the piece to be measured, this effort varying according to the diameter of this piece. In addition, the loop described by the rope is open, which may lead to difficulties in terms of repeatability of the measurement. Indeed, this loop does not guarantee the proper arrangement of the cables and wires of the measured electrical harness. Finally, the piece to be measured must be inserted into the loop. This operation can be difficult to implement to measure the diameter of certain branches of an electrical harness, in particular a long-length electrical harness that also has many branches. However, the aircraft are usually equipped with such an electrical harness. The document FR 2.268.245 describes a tool for controlling the diameter of cigarette filters. This tooling uses a flexible blade screwed at one of its ends.

The use of a flexible blade can reduce the measuring range of the tooling. Indeed, if the diameter of the piece to be measured is very small, the blade may have folds or may break.

The document WO 2013/010 084 describes a tool for measuring the diameter of an airbag in order to better choose the means of closure which will keep it in a confined position. This tool comprises a support and a slide carriage relative to this support.

In addition, an elongated link extends between a fixed pin connected to the support and a movable pin of the carriage. The elongate link may describe a closed loop between the fixed and moving pieces. Furthermore, the carriage is secured to a fastener that can be fixed to a movable rod in translation. This fastener is attached to a first end of a spring, a second end of the spring being attached to a shaft articulated to a moving means. To measure the diameter of an airbag, an operator inserts the airbag in the loop formed by the link and then adjusts the position of the fastener on the rod by moving the carriage. This movement tends the link around the airbag. Therefore, this operator maneuver the moving means which tends to compress the spring. This spring then causes the movement of the fastener and therefore the carriage.

A device then measures the movement of the carriage to determine the diameter of the airbag. The use of this device involves a manual operation to position the fastener relative to the tooling rod which can induce measurement dispersions. In addition, the operation of the moving means may induce a displacement that may degrade the measured object if the adjustment is not correct. Transposing the teaching of this document to a beam of electricity by fragile essence can therefore be tricky. US 6,009,631 is far from the scope of the invention relating to a system for measuring a tree. This document US 6,009,631 is therefore cited for information. This document US 6,009,631 describes a tool permanently arranged on a shaft and provided with a strip subjected to a constant tension. It is therefore an object of the present invention to provide a device for repeatedly determining the diameter of a deformable member under pressure, including a section of an electrical harness. The invention therefore relates to a device for measuring a diameter of a section of a deformable member under pressure, this device being provided with a base and a carriage sliding along a rail of the base, the a device having an elongated link extending from a first end attached to the carriage to a second end attached to a base support, the device having a measuring system for determining a travel distance of the carriage, the elongate link forming a closed loop between its first end and its second end. The device comprises a system for evaluating a mechanical tension for evaluating a tension exerted on the link and a displacement means for moving the carriage, the device comprising a processing unit connected to the mechanical tension evaluation system. and the measurement system for respectively receiving voltage information relating to the link voltage and position information relating to the movement of the carriage, the processing unit being provided with a calculation means and a means for display and a storage system, a voltage threshold being stored in the storage system, the processing unit executing programmed instructions in the storage system for storing the position information when the voltage information reaches said threshold for determining and displaying said diameter on the display means according to the stored position information.

The voltage information may be a datum giving the mechanical tension exerted on the link, or a datum representative of this mechanical tension. The stored position information may be information giving the processing unit the distance traveled by the carriage, and thus by the link. However, this stored position information can also provide the processing unit with the position of the carriage when the tension exerted on the link reaches a threshold. The processing unit can then deduce the distance traveled by the carriage relative to a calibration position established elsewhere. Such a processing unit may comprise a calculating means of the processor or equivalent type. The storage system may comprise a non-volatile memory storing the instructions to be executed by the calculation means and a volatile memory temporarily storing the stored position information or even a calibration position if necessary. The processing unit may then comprise a microcontroller connected to the display means as well as the system 5 for evaluating a mechanical tension and the measurement system. Similarly, the measurement system may be a conventional system measuring a displacement and / or a position, such as for example a magnetic or optical system. A mechanical system provided with a rack and a coding wheel is also possible. The link is advantageously a filiform link. The measuring system can measure a displacement and / or a position of the carriage or of an element setting in motion this carriage for example. Thus, an operator installs the body to be measured on the support. When the carriage is close to the member to be measured, the link has a length sufficient to be surrounded around this member forming a closed loop. The first end of the link being secured to the carriage and the second end of the link being secured to the support, a displacement of the carriage tends to enlarge or shrink the closed loop formed by the link around the body to be measured. By tightening, this link constrains the measuring member to take a cylindrical shape at this link following the movement of the carriage. In addition, the device simultaneously evaluates the relative displacement of the carriage and the force exerted on the link.

The device then automatically stores a measurement relating to the movement of the carriage when the tension exerted on the link reaches the predetermined threshold. This measurement is then used automatically to determine the diameter formed by the body to be measured, this diameter then being displayed on the display means. Just reset the device to perform a new measurement. This device makes it possible to measure the diameter of a relatively soft member 10, and in particular of a section of an electric harness. Moreover, this measurement can be performed identically and repeatedly. Indeed, this measurement is by nature performed under predetermined conditions by the effort threshold. In addition, the device allows measurements to be made at any position along a beam, provided there is sufficient space to arrange the beam on the support. In particular for a long beam, the device does not involve routing a tool around the beam from a connector to the section to be measured. It will be seen later that the device can be arranged directly at this section to be measured. Therefore, this device is a relatively simple device for accurately measuring the diameter of a beam in a non-random manner. This device may further comprise one or more of the following features.

Thus, the device may include an alert means for signaling to an operator that the threshold is reached. This warning means may include a visual, sound or tactile means for example.

The greater the tension exerted on the link, the more precise the action taken. However, too high a voltage is likely to degrade the measured organ. In the case of a harness, too high a voltage may cut a cable or wire.

A manufacturer can then size the voltage threshold to be applied taking into consideration these two aspects. In addition, the alert means to visualize whether the threshold is reached to prevent the operator exerts too much tension may hurt the body to be measured.

For example, the warning means may comprise a lamp arranged on a housing carrying said display means. A "lamp" is a device generating a light signal visible by an operator, such as a light-emitting diode in particular.

In addition, the device may comprise a fuse mechanical means which breaks from a predefined force limit. This limit may be greater than the threshold used for taking the measurement. In the event of a malfunction of an alert means, where appropriate, or even of a human error, the mechanical means breaks from said limit to prevent degradation of the organ to be measured.

Optionally, the mechanical fusible means is provided with a weakened section of a gripping means secured to the carriage for the manual movement of the carriage. This gripping means then breaks from said limit of effort.

According to a first variant, the displacement means comprises in fact a gripping means secured to the carriage for the manual movement of the carriage. According to a second variant, the displacement means comprises a motor connected to the carriage for the automatic movement of the carriage. This motor can be a rotary motor connected to the carriage by a worm for example. The motor can also be a linear motor. The processing unit is connected to the motor to require the carriage to move and to stop the movement of the carriage when said threshold is reached. For example, the processing unit places the carriage in a position maximizing the diameter of the loop formed by the link before any measurement and at the end of any measurement. When the operator requires the operation of the device, the processing unit then translates the carriage, and stops this translation when the threshold is reached. The measurement system can further measure a displacement and / or a position of the carriage or a moving part of the engine. The system for evaluating a mechanical tension may comprise a measurement unit measuring the electric current consumed by said motor. This electric current is proportional to the torque generated by the motor, and in fact to the tension exerted on the link. Whatever the variant, the evaluation system of a mechanical tension may comprise a dynamometer carried by the carriage. This dynamometer is eventually connected to the first end of the link to measure a mechanical tension exerted on this link. Furthermore, the support may comprise a vertical wall and a horizontal wall on which rests the organ to be measured, the vertical wall having a guide slot through which said elongated link. When moving the carriage, the body to be measured is then pressed against the vertical and horizontal walls to optimize the measurement. These walls force the organ to be measured to remain perpendicular to the measuring device carried by the carriage so that the loop of the link is more like a circle than a spiral. The guide slot further guides the link to the organ to be measured. In addition, the support optionally comprises a fixed spout provided with a groove, the second end of the link being able to pass through the groove and comprising a stop means that can be reversibly wedged in this fixed spout, the link slender can be extracted manually from the fixed spout. In order to facilitate beam measurements between two leads or having large diameter connectors, the elongated link is a retractable cable at at least one of its ends.

In particular, the link may be retractable at its second end attached to the support. Thus, this second end may comprise an outgrow forming a stop means. The link can then penetrate into the fixed spout, the stop means abutting against the fixed spout following a traction resulting from a movement of the carriage. This characteristic makes it possible to directly position the device at the location of the measurement. The link then has one of its free ends. This link can therefore be guided to describe a closed loop around the organ to be measured before being reconnected to the fixed spout. The first end may also be retractable or non-removably attached. In particular, the first end may be secured to the carriage, for example by a securely closed loop of the link. Moreover, the link optionally comprises a flexible and non-extensible material. In particular, the link may include a portion of parachute hangers. 20 Too thin a link may hurt a cable or wire during a measurement. In addition, the link must not be extensible so as not to distort the measure. A parachute hanger has physical characteristics surprisingly meeting the needs. Furthermore, the processing unit may comprise means for adjusting said threshold.

This threshold may vary depending on the nature of the organ to be measured, and / or depending on the diameter to be measured. The greater the pressure on the link, the more accurate the measurement will be. However, the greater the pressure exerted on the link 5, the greater the risks of damaging the organ to be measured. A threshold of 10 Newtons seems well adapted for an application to the measurement of electric beams of rotorcraft for example. However, another threshold may be of interest for other applications. Thus, the adjustment means can be used to adjust the threshold. For example, the storage unit has a plurality of stored thresholds, the setting means for choosing the appropriate threshold. In addition, the device may comprise a gauge having known geometrical characteristics, said processing unit determining and memorizing a calibration position in which the carriage is located when said threshold is reached following the introduction of the gauge in said long line. , said measuring system determining the distance of displacement of the carriage relative to said calibration position following the establishment of the body to be measured in said link. The geometric characteristics of the caliber are known and are stored in the processing unit. For example, the gauge is a metal cylinder having a known circumference.

During the calibration, the processing unit stores the position of the carriage obtained by inserting the template in the link. This position is called "calibration position" for convenience. Therefore, the operator inserts the object to be measured in the link and stores the position reached by the carriage called "measuring position" for convenience. The processing unit derives the distance traveled by the carriage between the calibration position and the measurement position. As a result, the processing unit can determine the diameter "D" of the object to be measured from the circumference of the caliber and this distance traveled by the following relation: C + LD = where "L" represents said distance traveled by the carriage between the calibration position and the measuring position "C" represents the stored circumference of the caliber, "n-" represents the number Pi, "+" represents the sign of the addition. Depending on the direction of movement of the carriage relative to the calibration position, the sign of the addition may be replaced by the sign of the subtraction.

The device then makes the measurement of a relative displacement with respect to a calibrated value by using a rigid cylinder whose diameter is strictly known, in place of the object to be measured.

The processing unit may display an error message if no calibration measurement is stored. In addition to a device, the invention provides a method for measuring a diameter of a section of a pressure-deformable measuring member using this device. Thus, during a measurement phase: - a closed loop is formed around the body to be measured using the elongated link, - the carriage is moved to exert a force on the longiline link in order to impose a cylindrical shape to the member to be measured, - the position information relative to the displacement of the carriage is memorized when the tension of the elongate link reaches a predetermined threshold, - the diameter of said cylindrical shape is determined and displayed as a function of said position information. This method may further include one or more of the following features. As a result, it can be pointed out to an operator that said threshold is reached by means of an alerting means. In addition, it is possible to provide a calibration phase during which: - a closed loop is formed around a gauge having known geometric characteristics with the aid of the elongated link, - the carriage is moved to exert a force on the longiligne link in order to impose a cylindrical shape to the body to be measured, - the position information relative to a position known as "calibration position" reached by the carriage is stored when the tension of the longiligne link reaches a predetermined threshold, during and during the measurement phase: - a closed loop is formed around the organ to be measured with the aid of the elongated link, - the carriage is moved to exert a force on the long line in order to impose a cylindrical shape to the member to be measured, - the position information relative to a position known as the "measurement position" of the carriage is stored when the tension of the elongated link reaches a predetermined threshold, the distance separating the measuring position from the calibration position is measured, the diameter of the element to be measured is determined by means of said known geometrical characteristics and of said distance, and said diameter is displayed. The invention and its advantages will appear in more detail in the following description with examples given by way of illustration with reference to the appended figures which represent: FIG. 1, a perspective view showing a device according to a first variant of the invention, - Figure 2, a view having a gripping means provided with a fuse mechanical means, - Figure 3, a schematic view explaining the operation of a retractable link and the method according to the invention, - Figures 4 and 5, views explaining a method using a template, and - Figure 6, a view showing a second variant of the invention. The elements present in several separate figures are assigned a single reference. FIG. 1 shows a device 1 according to a first variant which is intended to measure the diameter of a deformable member under the so-called "measuring body" pressure. In particular, this device 1 applies the method according to the invention to determine the diameter of an electric beam. Independently of the variant, this device 1 is provided with a base 10. This base comprises in particular a base 11 in the form of a flat plate carrying a rail 15. Any type of rail 15 may be used. In addition, the base 10 may comprise at least one side wall 12, or removable faces not shown forming a parallelepiped for example.

In addition, the base 10 is provided with a support 16 for carrying the body to be measured. Such a support may be provided with a vertical wall 17 and a horizontal wall 18 forming a square. Thus, the vertical wall 17 can be fixed to the base 11 and to the horizontal wall 12. This vertical wall 17 is moreover favorably provided with a vertical slot 19. This slot 19 opens onto an internal space 300 of the bracket adapted to welcome the organ to measure. The horizontal wall 18 is then secured to the vertical wall 17, and a foot 301 connected to the base 11. This support 16 optionally carries a means for attaching a link such as a spout 75. The spout 75 has the shape of an L provided with a groove 76. The groove is then present in alignment with the slot 19 of the vertical wall 17.

Furthermore, the device 1 comprises a carriage 20 sliding on the rail 15 of the base 10. The term "mobile" qualifies movable elements in translation with the carriage. Conversely, the term "fixed" qualifies elements that are not mobile with the carriage, and in particular integral elements of the base 10 such as the spout 75. To operate the carriage, the device 1 comprises a moving means manual or automatic. According to the first variant of Figure 1, the moving means comprises a gripping means 25 integral with the carriage. Such a gripping means may comprise a rod 28 extending in a direction substantially orthogonal to the direction of translation of the carriage. This rod can project from a light of a side wall of the base which is not shown in Figures 1 for convenience. Such a partition may be substantially parallel to the side wall 12 of Figure 1, being connected to it by the base 11 or by a not shown upper wall. With reference to FIG. 2, the device 1 may comprise a fusible mechanical means 26 that breaks from a predefined force limit. Therefore, this fusible mechanical means 26 is optionally provided with a weakened section 27 of the gripping means 25. This weakened section may consist of a local narrowing of the section of the gripping means.

According to the second variant of FIG. 6, the displacement means comprises a motor 80 connected to the carriage 20. For example, this motor is a rotary electric motor connected by an endless screw 81 to the carriage 20. The motor can also be a motor linear electric or any other type of motor.

Furthermore and with reference to FIG. 1, the device 1 comprises an elongated link 30 intended to extend between the carriage 20 and the support 10 whatever the variant. Such a long line is more simply called "link". This link 30 is for example obtained from a rope, and in particular a parachute hanger. The link 30 then extends from a first end 31 to a second end 32. The first end is intended to be secured to the carriage by a first attachment means. The first end is then referred to as the first movable end. Conversely, the second end is intended to be secured to the support by a second attachment means. The second end is then called a second fixed end.

The first attachment means and / or the second attachment means may be reversible attachment means to facilitate the arrangement of the link around the organ to be measured. In particular, the second attachment means may comprise the spout 75 and a stop means secured to the second end of the link 30. Furthermore, the device 1 comprises a mechanical tension evaluation system for evaluating directly or indirectly, a mechanical tension exerted on the link 30. According to the first variant of Figure 1, the carriage 20 carries a dynamometer 50 of the evaluation system of a mechanical tension. This dynamometer is then optionally attached to the first end 31 of the link 30, reversibly or non-reversibly. For example, the first end describes a closed loop passing through a hole of the dynamometer. According to this variant, only the second end of the link is removable relative to the associated fastening means. The dynamometer then makes it possible to generate an output 20 comprising a voltage information relating to the tension exerted on the link 30 during the displacement of the carriage. According to the second variant of FIG. 6, the system for evaluating a mechanical tension comprises a measurement unit 90 measuring the electrical current consumed by an electric type motor 80. The first end of the link 30 is then attached to the carriage for example. This measurement unit 90 generates an output comprising voltage information relating to the voltage exerted on the link 30 by means of the electric current consumed by the motor. Indeed, this consumed electric current is representative of the torque exerted by the motor and therefore of the force exerted on the link 30. Reference will be made to the literature to obtain information relating to such a measurement unit 90. Alternatively, the device may comprise an engine and a dynamometer. Furthermore and with reference to Figure 1, the device 1 comprises a measuring system 40 which measures the movement of the carriage, regardless of the variant of the invention. For example, the measuring system 40 comprises a measuring cell 41 resting on a seat of the carriage and a magnetic tape 42 arranged on the side wall 42. The measuring cell then determines the position of the carriage with respect to the magnetic tape 42. Other measurement systems are possible. Thus, the measurement system generates an output comprising position information relative to the displacement of the carriage, through a position measurement for example.

In addition, a dynamometer 50 may optionally be arranged on the measuring cell 41. In addition, the device 1 comprises a processing unit 60 connected to the evaluation system of a mechanical tension to receive the voltage information, and the measurement system for receiving the position information. According to the first variant, the processing unit is thus connected to the dynamometer and to the measurement system. According to FIG. 6, the processing unit is connected to the motor, to the measuring system and to the measuring unit 90 measuring the electric current consumed by said motor. This processing unit therefore comprises interface means connected to the evaluation system of a mechanical voltage, to the measurement system or to the displacement means. In addition, this processing unit comprises a housing 68 accommodating a computing means 61, such as a processor or equivalent. The processing unit furthermore has a storage system 62 connected to the interface means and to the calculation means 61. Thus, the storage system may have a non-volatile memory 63 and a volatile memory 64. The processor, the Interfaces means and the storage system may jointly form a microcontroller. In addition, the processing unit comprises a display means 65, such as a digital display means connected to the calculation means 61. In addition, the processing unit may comprise button-type control means 66. , 67 to require the operation of the device 1. Finally, the device 1 shown in FIG. 1 is provided with an alerting means 70 for signaling to an operator that a threshold voltage of the link 30 is reached. This warning means 70 has for example a lamp 71 carried by the housing and connected to the calculation means 61. FIG. 3 explains the method according to the invention for measuring the diameter of a member 5 to be measured.

An operator moves the device 1 to reach the area of the organ 5 to be measured. Therefore, the operator disposes this member 5 in the internal space 300 delimited by the support 16.

As a result, the operator maneuvers the link 30 to make it pass through the slot 19 of the vertical wall 17. The operator then forms a closed loop 33 around the member to be measured in the internal space 300, then maneuver the first end of the link to make it pass through the groove 76 of the spout. Therefore, the stop means 34 of the link can abut against the fixed spout 75. When the link is in place, the operator moves the carriage 20 along the arrow 200 away from the member 5 to be measured , manually or, where appropriate, using a motor 80.

The link 30 is tightened by tightening the loop 33 on the body to be measured. This measuring member then takes a substantially circular shape with a diameter 100. In addition, the member to be measured is pressed against the vertical wall 17 and the horizontal wall 18.

When the voltage information transmitted to the processing unit signals a voltage equal to a voltage threshold stored in the storage system, the processing unit stores the position information from the measurement system.

This memorization of the position information is done "on the fly", namely automatically when moving the carriage.

In parallel, the warning means indicates if the threshold is reached. For example, the lamp 71 turns on when the threshold is reached. The operator can then release the force exerted on the gripping means, the required measurement being made. If necessary, an engine stop command can be considered when the threshold is reached. The calculating means then executes instructions stored in the storage system to determine the diameter 100 of the organ to be measured using the received position information and stored relationships. The calculating means finally transmits information to the display means to display the determined diameter 100. The voltage threshold used may be a single threshold stored in the non-volatile memory of the storage system, or may be set using a means for adjusting the processing unit. For example, the processing unit may comprise a plurality of stored thresholds, buttons 67 of the processing unit for selecting the appropriate threshold. With reference to FIG. 4, the device 4 may comprise a gauge 80 to facilitate the determination of the diameter of a member to be measured. This caliber 80 has known geometric characteristics. For example, this caliber 80 is a metal cylinder with a circular base. Therefore, the diameter of the cylinder and / or its circumference can be stored in the processing unit. Therefore, the device 1 may require the implementation of the caliber during a calibration phase prior to any measurement.

Thus, the operator detaches the second end 32 of the link 30 of the spout 75 to surround the link around the caliber 80. The operator then again attaches the second end 32 of the link to the spout 75.

Therefore, the operator moves the carriage to stretch the link around the gauge 80 away from the member 5 to be measured, manually or, if necessary, with the aid of a motor 80. When the tension exerted on the link reaches the predetermined threshold, the measuring system transmits the position of the carriage. The processing unit then stores the position reached called "calibration position POS1". The operator then moves the carriage of the caliber to relax the link 30 and separate it from the spout 75. For example, a motor places the carriage in a stored initial position.

This operator then removes the gauge from the device 1 and places the member 5 to be measured on the support in accordance with FIG. 5. The operator then winds the link around the member 5 and then connects the second end 32 of the link to the spout. 75.

Therefore, the operator moves the carriage to stretch the link around the member 5 to be measured away from the member 5 to be measured, manually or possibly with the aid of a motor 80. When the As the tension exerted on the link reaches the predetermined threshold, the measuring system transmits the position of the carriage. The processing unit finally memorizes the position reached called "measuring position POS2".

The calculating means of the processing unit determines the distance 400 separating the calibration position POS 1 and the measuring position POS2. This calculation means deduces the diameter 100 of the member 5 from a stored relationship as a function of this distance 400 and the stored geometric characteristics of the caliber 80. The determined diameter is then displayed on the display means. Naturally, the present invention is subject to many variations as to its implementation. Although several embodiments have been described, it is well understood that it is not conceivable to exhaustively identify all the possible modes. It is of course conceivable to replace a means described by equivalent means without departing from the scope of the present invention.

Claims (20)

REVENDICATIONS1. Device (1) for measuring a diameter (100) of a section of a member (5) deformable under pressure, this device (1) being provided with a base (10) and a sliding carriage (20) along a rail (15) of said base (10), said device (1) having an elongate link (30) extending from a first end (31) attached to the carriage (20) to a second end ( 32) attached to a support (16) of said base (10), said device (1) having a measuring system (40) for determining a moving distance of said carriage (20), said elongate link (30) forming a loop (33) closed between its first end (31) and its second end (32), characterized in that said device (1) comprises a mechanical tension evaluation system (50, 90) for evaluating a mechanical tension exerted on said link (30) and a moving means (25, 80) for moving the carriage (20), said device (1) comprising a processing unit ent (60) connected to the evaluation system of a mechanical tension (50, 90) and to the measuring system (40) for respectively receiving voltage information relating to the tension of said link and position information relating to the movement of the trolley (20), said processing unit (60) being provided with a calculating means (61) as well as a display means (65) and a storage system (62), a voltage threshold being stored in said storage system (62), the processing unit (60) executing programmed instructions in the storage system (62) for storing the position information when the voltage information reaches said threshold to determine and displaying said diameter on said display means (65) according to said stored position information. 2. Device according to claim 1, characterized in that said moving means comprises a gripping means (25) integral with the carriage for the manual movement of the carriage (20). 3. Device according to any one of claims 1 to 2 characterized in that said moving means comprises a motor (80) connected to the carriage for the automatic movement of the carriage (20). 4. Device according to claim 3, characterized in that the processing unit (60) is connected to the motor (80) to require the movement of the carriage and stop the movement of the carriage when said threshold is reached. 5. Device according to claim 3, characterized in that said system for evaluating a mechanical tension comprises a measuring unit (90) measuring the electric current consumed by said motor. 6. Device according to any one of claims 1 to 4, characterized in that said system for evaluating a mechanical tension comprises a dynamometer (50) carried by said carriage (20) and connected to said first end (31). ) for measuring a mechanical tension exerted on said link (30). 7. Device according to any one of claims 1 to 6, characterized in that said device (1) comprises an alert means (70) for signaling to an operator that said threshold is reached. 8. Device according to claim 7, characterized in that said alerting means (70) comprises a lamp (71) arranged on a housing (68) carrying said display means (65). 9. Device according to claim 1, characterized in that said device (1) comprises a fuse mechanical means (26) which breaks from a predefined stress limit. 10. Device according to claim 9, characterized in that said fusible mechanical means (26) is provided with a weakened section (27) of a gripping means (25) integral with the carriage for the manual movement of the carriage (20). . 11. Device according to any one of claims 1 to 10, characterized in that said support (16) comprises a vertical wall (17) and a horizontal wall (18) on which rests the member (5) to be measured, said vertical wall (17) having a slot (19) for guiding through said link (30) elongate. 12. Device according to any one of claims 1 to 11, characterized in that said support (16) has a spout (75) fixed with a groove (76), said second end (32) can pass through. the groove (76) and comprising a stop means (34) capable of being reversibly wedged in said fixed spout (75), said elongate link (30) being manually extractable from said fixed spout (75). 13. Device according to any one of claims 1 to 12, characterized in that said link (30) comprises a flexible material and not expandable. 14. Device according to any one of claims 1 to 13, characterized in that said link (30) comprises a portion of parachute hanger. 15. Device according to claim 6, characterized in that said first end (31) is secured to the dynamometer (50). 16. Device according to any one of claims 1 to 15, characterized in that said processing unit (60) comprises a means (67) for adjusting said threshold. 17. Device according to any one of claims 1 to 16, characterized in that said device (1) comprises a gauge (80) having known geometric characteristics, said processing unit (60) determining and storing a calibration position ( POS1) in which there is the carriage (20) reached when said threshold is reached following the introduction of the gauge (80) in said elongate link (30), said measuring system (40) determining the distance of the displacement of the carriage (20) relative to said calibration position (POS1) following the introduction of the member (5) to be measured in said link (30). 18. A method of measuring a diameter of a section of a deformable member under pressure with the aid of a device according to any one of claims 1 to 17, characterized in that during a measurement phase: a closed loop (33) is formed around the member (5) to be measured by means of the elongate link (30), the carriage (20) is moved to exert a force on the elongate link (30) in order to to impose a cylindrical shape on the member (5) to be measured, - the position information relative to the displacement of the carriage (20) is stored when the tension of the elongate link reaches a predetermined threshold, - the diameter (100) of said cylindrical shape according to said position information. 19. The method of claim 18, characterized in that it signals to an operator that said threshold is reached by means of a warning means (70). 20. Process according to any one of claims 18 to 19, characterized in that during a calibration phase, a closed loop (33) is formed around a caliber (80) having known geometric characteristics using the link (30) elongate, - the carriage (20) is moved to exert a force on the link (30) elongate around a caliber (80), - the position information is stored relative to a position called "position of calibration »reached by the carriage (20) when the tension of the elongated link reaches a predetermined threshold, and in that during the measurement phase: - a closed loop (33) is formed around the member (5) to be measured with the help of the link (30) elongated, - the carriage (20) is moved to exert a force on the link (30) elongate in order to impose a cylindrical shape to the member (5) to be measured - it memorizes the position information relating to a position called "measuring position" of the carriage (20) when the tens ion of the longiline link reaches a predetermined threshold, - the distance separating the measurement position from the calibration position is determined, - the diameter (100) of the member (5) to be measured is determined using said known geometrical characteristics. and said distance, and - said diameter (100) is displayed.