CH709473A1 - An apparatus for measuring the resistance per unit length of a cable portion. - Google Patents

Abstract

The invention relates to an apparatus for measuring the linear resistance of a portion of electrical cable (1) of determined length (I), comprising: a frame (3); a first knife (5) for making electrical contact with a first end of said electric cable portion (1); a second knife (5) for making electrical contact with a second end of said electric cable portion (1); the two knives (5) being mounted on a ruler (6) movable relative to said frame (3), in particular from top to bottom, for contacting the cable under test. The length of the measured cable portion is thus, inter alia, better controlled.

Description

Technical area

The present invention relates to an apparatus for measuring the linear resistance of an electric cable of determined length.

State of the art

It is frequently necessary to measure the ohmic resistance of conductive electrical cables, for example during their design and during their manufacture. The measurements are for example carried out on a precise length of cable, usually one meter, by means of a Kelvin type measurement. The accuracy of the measurement depends on many factors, including the precise distance between the two electrical contact points, the quality of the contact at these two points, the temperature, the accuracy of the ohmmeter, and so on. The present invention aims in particular to improve the voltage tap and temperature on conductors of varying types and dimensions.

Electrical resistance measuring devices are for example described in FR B3 2 386 044. In this document, the ends of a section of wire to be measured are clamped between jaws and the wire is stretched by a electric motor operating one of the jaws. The realization of these jaws is complex, especially if they must be adapted to cables of variable sections.

[0004] EP B1 0 168 346 describes another apparatus for measuring the electrical resistance of insulated conductors or not, comprising a curved support for supporting a section of the conductor and pinching means for pinching the ends of this section and for the electrically connect to the measuring device. The V-bracket has a groove having a Y-shaped section for positioning the insulated conductor on the support without stretching it. The clamping means comprise a carriage provided with electric contact knives and movable in a direction substantially perpendicular to the section of the conductor.

In this solution, so that the cable rests on the groove and the driver is brought into contact with the knives, it is necessary that the stroke of the carriage is at least equal to the maximum thickness of insulating cables to measure. In the case of energy transport cables, this thickness of insulation can be considerable, for example of the order of 3 centimeters or more. However, it is difficult to guarantee a perfectly straight carriage displacement on such a long stroke; a game must be provided to allow the knife to go up or down. The point of contact between each knife and the conductor of the electrical cable to be measured is therefore not perfectly controlled, particularly in the case of cables having a large thickness of insulation, or non-circular section cables. The distance between the two measurement points is therefore variable, which introduces an inaccuracy in the resistance measurement.

Moreover, it frequently happens that the sections of cables to be measured are not straight. In the case of large diameter cables, it is almost impossible to straighten them. In this case, the two points to be contacted on the cable are not at the same height. This results in additional inaccuracy on the contact position, the distance between the two contact points, and the contact pressure at each point. Some devices also do not allow measurement on cables when the contact points are not in the same horizontal plane, or do not allow the connection of jaws or jaws on a cable end not aligned with the longitudinal axis provided .

Another apparatus for measuring the linear resistivity of stranded conductors is described in CH A5 693 830. This apparatus employs jaws capable of ensuring strong clamping with the electrical conductor to be measured, which is difficult to guarantee in the case of conductors of variable or non-circular section.

[0008] A similar solution is described in CH A2 704 816.

Different devices also require completely remove the insulation of the cable segment to be measured in order to put the driver on the support. In the case of thick insulation, this stripping operation is very difficult. In addition, the stranded internal conductors often tend to break when the insulation that holds them is removed. The measurement is then distorted when the different strands relax after removal of the insulation.

Brief summary of the invention

An object of the present invention is to provide an apparatus for measuring the linear resistance (that is to say the resistance per meter) of an electric cable length determined without the limitations of known devices.

Another object of the invention is to provide an apparatus in which the distance between the two points of electrical contact with the electrical conductor is better controlled than in the prior art.

Another object of the invention is to provide an apparatus in which the electrical conductor can be installed more easily than in the prior art.

Another object of the invention is to provide an apparatus that allows the measurement of non-circular section cables, for example sectoral cables.

Another object of the invention is to provide an apparatus in which the electrical conductor can be installed without removing the insulation around the section to be measured.

According to the invention, these objects are achieved in particular by means of an apparatus for measuring the linear resistance of a portion of electric cable of predetermined length, comprising a frame, a first knife intended to establish an electrical contact with a first end of said portion of electrical cable; a second knife for making electrical contact with a second end of said electric cable portion, the two knives being mounted on a movable ruler relative to the frame.

This solution has the advantage of maintaining a strictly constant distance between the two knives and therefore between the two points of contact with the electrical cable to be measured, regardless of the absolute position of these contact points along the cable, and whatever their height.

The knives are advantageously fixed with respect to the rule.

The rule and the knives are arranged to move down to contact the cable under test.

The ruler can be maintained above the portion of the electrical cable to be measured by means of a holding device.

The holding device can be arranged to allow to move away or to bring the ruler and the knives of the electric cable portion to be measured.

The holding device may be arranged to allow a displacement of said rule in a vertical plane, or substantially vertical, above said portion of electrical cable to be measured.

The holding device may be arranged to allow limited rotation of the rule in the vertical plane.

In one embodiment, the holding device may comprise two vertical bars connected to said frame, and at least one integral guide of the rule and sliding around each bar.

A game between each bar and the guide allows to tilt the ruler relative to the horizontal direction. In this way, it is possible to establish two reliable points of contact with a non-horizontal or even straight electric cable.

The rule and the guides can be arranged to slide along the bars under the action of gravity, until the knives rest against the electric cable. The contact pressure thus depends essentially on the weight of the rule, and remains substantially constant regardless of the type of cable to be tested.

The knives may comprise a concave contact surface with said electric cable, for example a surface arcuate or V. This allows them to establish a quality contact with cables of different diameters and different sections.

Retention elements may be provided to prevent the guides from descending along the bars. It is thus possible to keep the ruler in a high position, for example during the introduction or withdrawal of the cable.

The rule may include a "U" profile returned. Electric wires can connect the knives to an external measuring device or in the frame, passing between the branches of the U.

The rule may include a knife fixing block at each of its ends. The blocks are housed at least partially between the branches of said "U". A knife can be mounted projecting downward in each fixing block. These blocks allow a rigid and precise assembly of the knives on the ruler.

The cable segment to be measured can be suspended above the frame and below the movable rule by means of jaws. As the cable does not rest on a support, it is not necessary to strip it completely, except at the points of contact with the knives. However, a support can be provided under the cable to prevent the bending of smaller diameter cables.

Brief description of the figures

Examples of implementation of the invention are indicated in the description illustrated by the appended figures in which: <tb> Fig. 1 <SEP> illustrates an apparatus according to the invention, without the rule and without the cable to be measured. <tb> Fig. 2 <SEP> illustrates an apparatus according to the invention, with the rule and the cable to be measured. <tb> Fig. 3 <SEP> illustrates a perspective view of the ruler with knives and guides. <tb> Fig. 4 <SEP> shows a top view of the ruler with the guides.

Example (s) of embodiment of the invention

An example of apparatus 1 according to the invention is illustrated in FIGS. 1 to 2, Figs. 3 and 4 showing details of the rule.

The illustrated apparatus comprises a frame 3 on which two jaws 4 are fixed for holding in suspension a cable portion of which it is desired to measure the resistance. The jaws also make it possible to inject the measurement current for a measurement of the Kelvin type. The spacing between the jaws is greater than the normalized length I of conductor whose resistance is to be measured. In a typical embodiment, the length I is equal to 1 meter and the jaws are for example spaced from 120 to 150 cm. The jaws may include clamping means for securely holding the cable, for example, screw locks, powered by an electric motor, or hydraulic. The cable can be held above the frame 3 without touching it. It is possible in one embodiment to add a support to support the cable between the two jaws, for example in the case of flexible cables. This support can be removable.

The electronic resistance measuring device is advantageously housed in the chassis. It comprises for example an ohmmeter known per se and a display device 30 of the measured value. Its horizontal position can preferably be adjusted according to the diameter of the cable, so as to move away from the cable in case of large diameter cable. In another embodiment, this device can be housed outside the chassis, and connected to the device 1 by cables, for example by means of standardized connectors.

As seen in FIG. 2, the measuring device 1 further comprises a rule 6 carrying knives 5 intended to establish electrical contact with the electrical conductor 21 of the cable 2 to be tested, in order to measure the difference in voltage between these two points. Only the portion 21 of the cable under the knives and to the two ends of the cable portion 2 must be stripped; the portion of cable between the two knives can retain its insulation 20, which keeps the strands of the cable together by preventing it from being dislocated. This facilitates the test of the cable 2 which only the ends must be stripped.

The rule is constituted by a metal part, preferably rectilinear, and of precise length. The term rule must be understood in a broad interpretation and does not imply a graduation. In one embodiment, the rule comprises a U-shaped metal tube returned; a portion of electrical wires connected to the knives 5 can pass inside the tube. A hood not shown can close the bottom of the rule to prevent access to the son.

The weight of the ruler is preferably relatively large, for example greater than 1kg, to ensure a quality electrical contact between the knives 5 and the contact points on the conductor 21 under the effect of the weight of the rule. No spring and no actuator is required to support the knives on the cable.

The knives 5 are electrically conductive material. They are mounted in certain places under the rule. In an advantageous embodiment, these knives are screwed by means of fixed fastening blocks, for example screwed, riveted or welded, between the U-shaped legs of the rule, for example at both ends. The blocks are advantageously made of insulating material to prevent electrical contact between the knives and the metal body of the rule. The distance between the two blocks and between the two knives 5 is fixed and precisely controlled, for example by one meter exactly. The knives protrude under the rule so as to contact the conductor 21 on each side of the insulated portion 20. The term "knife" conventionally refers to any part capable of establishing a good electrical contact with the conductor 21 and does not necessarily imply the presence of a cutting edge. In an advantageous embodiment, the knives comprise a contact surface 50 with the concave conductor 21, for example in a circular arc or inverted V.

The rule 6 can slide in a vertical plane by means of guides 70 sliding along vertical bars 72 connected to the frame 3. The guides are related to the rule. They comprise an opening through which the bar 72 passes. As can be seen in FIGS. 3 and 4, the width of this opening, in the direction parallel to the longitudinal axis X of the cable, is greater than the width of the bars in this direction. The guides can therefore pivot slightly relative to the bars, which allows to tilt the ruler 6 relative to the horizontal axis and to contact non-rectilinear cables 2 or that would not be strictly horizontal. The points of contact with the driver 21 may therefore be at slightly different heights. Pins 71 may be provided in the openings to limit the maximum amplitude of this inclination while promoting sliding.

The guides can be maintained in the raised position above the cable 2. For this purpose, in the illustrated embodiment, the bars 72 are provided with spring screws collaborating with holes not shown in the guides 70 in order to retain these guides in one or more predefined raised positions. The introduction and extraction of the cable is thus facilitated. Furthermore, a cap or a projection to limit the stroke of the guides along the bars 72, and prevent the extraction of the rule.

The element 8 indicates a temperature sensor mounted under the rule and for measuring the temperature of the conductor 21.

Reference numbers used in the figures

[0042] <Tb> 1 <September> Apparatus <tb> 2 <SEP> Cable to be measured <Tb> 20 <September> Insulation <tb> 21 <SEP> Electric conductor <Tb> 3 <September> Chassis <tb> 30 <SEP> Measuring device <tb> 4 <SEP> Jaws for cable retention and power injection <Tb> 5 <September> Knives <tb> 50 <SEP> Contact area <Tb> 6 <September> Rule <tb> 7 <SEP> Rule Holder <tb> 70 <SEP> Rule Guide <Tb> 71 <September> Clips <Tb> 72 <September> Barre <tb> 73 <SEP> Spring Ball <tb> 8 <SEP> Temperature probe <Tb> I <September> Length

Claims (14)

Apparatus for measuring the linear resistance of a portion of electric cable (1) of determined length (I), comprising: a frame (3); a first knife (5) for making electrical contact with a first end of said electric cable portion (1); a second knife (5) for making electrical contact with a second end of said electric cable portion (1); characterized by: both said knives (5) are mounted on a rule (6) movable relative to said frame (3). 2. Apparatus according to claim 1, comprising a holding device (7) for holding said rule (6) above the portion of electric cable (1) to be measured. 3. Apparatus according to claim 2, said holding device (7) being arranged to allow to move away or bring the rule (6) and the knives of the electric cable portion (1) to be measured. 4. Apparatus according to one of claims 2 or 3, said holding device (6) being arranged to allow a displacement of said rule (6) in a vertical plane above said portion of electric cable (1) to be measured . 5. Apparatus according to claim 4, said holding device (6) being arranged to allow limited rotation of said rule (6) in said vertical plane. 6. Apparatus according to one of claims 2 to 5, said holding device (7) comprising two vertical bars (72) connected to said frame, and at least one guide (70) sliding around each bar (72), said guides (70) being integral with the rule (6). 7. Apparatus according to claim 6, a clearance being provided between each bar (72) and the corresponding guide (70), so as to allow to tilt the rule (6) relative to the horizontal direction. 8. Apparatus according to one of claims 6 or 7, the rule (6) and the guides (70) being arranged to slide along the bars (72) under the action of gravity, until the knives (5) bear against said electric cable. Apparatus according to claim 8, said bars (7) having retention members (73) for preventing said guides (70) from descending along said bars (72). 10. Apparatus according to one of claims 1 to 9, said knives (5) being fixed relative to the rule (6). 11. Apparatus according to one of claims 1 to 10, said knives (5) having a contact surface with said concave electric cable (1) (50). 12. Apparatus according to one of claims 1 to 11, said rule (6) having a profile "U" returned, electrical son connecting said knives (5) to a measuring device (30) passing between the branches of said U . 13. Apparatus according to claim 12, said rule (6) comprising a knife attachment block at each of its ends, said blocks being housed at least partially between the branches of said "U", a knife (5) being mounted protruding down in each said fixing block. 14. Apparatus according to one of claims 1 to 13, comprising jaws (4) arranged to hold said electric cable (1) suspended above the frame 0).