KR20120125445A - A helically-wound electric cable - Google Patents

Abstract

PURPOSE: An electric cable is provided to control a control signal by connecting a measuring unit of a center line to a controlling unit. CONSTITUTION: Two or more groups(P1,P2) are wound in order to form a group helix(1). Each group includes twisted conductor wires(FC11,FC12,FC21,FC22). Pitches (L1,L2,L3) of the group helix are varied according to the electric cable. The cable includes at least one additional group helix. The group helix is varied according to a periodic function.

Description

Spiral wound electric cable {A HELICALLY-WOUND ELECTRIC CABLE}

The present invention relates to a spirally wound electrical cable.

The electrical cable includes one or more twisted conductor wire groups. In general, one group consists of two twisted together conductor wires, in which case it is called a "pair". However, it may also include two or more twisted conductor wires.

The spirally wound electrical cable includes a number of groups wound together to form a helix.

The term "cross-talk" refers to electromagnetic interference between groups belonging to a given electrical cable. Crosstalk often causes problems with data transfer.

In order to reduce crosstalk, a method of twisting conductor wires in helix at different pitches per group is known to prevent conductor wires of a given group from intervening between conductor wires of different groups.

U.S. Pat. 6 318 062 describes a method for varying the twist pitch within a pair. The method also prevents conductor wires of a given group from interleaving between conductor wires of another group, thereby preventing the conductor wires from becoming nearly parallel to each other along the cable.

EP-A-1 174 886 also describes a spirally wound electrical cable comprising at least two groups wound together to form a group helix, each group comprising at least two twisted conductor wires, the pitch of the group helix being A spirally wound electrical cable is disclosed that varies along the cable.

However, today it is necessary to further reduce crosstalk as the frequencies delivered by spirally wound electrical cables increase.

The present invention provides at least two groups wound together to form a group helix, each group providing a spirally wound electrical cable comprising at least two twisted conductor wires. According to the invention, the pitch of the group helix varies along an electric cable spirally wound between two limiting values with the same sign.

In terms of crosstalk, the main coupling mechanism between the two pairs is mutual inductance, which is a periodic function of the pair pitch and the cable pitch that varies along the cable. As a result, increased mutual interference may occur between the signal carried by the transmitting pair and the crosstalk signal propagating in the opposite direction in the receiving pair; This phenomenon occurs at frequencies that are arithmetic with the period and propagation velocity of the periodic function. Certain peaks in the crosstalk graph measured as a function of frequency have their origin in this mechanism, and the more uniform and repetitive the structure of the cable over a given cable length, the larger the magnitude and width of the peak. The magnitude of these peaks can be reduced by changing the shape of the cable, and in the present invention this object is achieved by varying the cable-wound pitch with application of any or any function.

The pitch change of the group helix minimizes the parallelism between the conductor wires and thus reduces crosstalk.

The spirally wound electrical cable of the present invention may comprise at least one additional group helix. Optionally, the spirally wound electrical cable of the present invention may comprise a single group helix.

Each group helix may contain more than one group.

For example, a spirally wound electrical cable may include a group helix made up of about ten together wound groups. Optionally, the group helix can contain exactly two groups.

The spirally wound electrical cable of the present invention may comprise a plurality of group helixes, each group helix having a different number of groups, or in fact the same number of groups.

A group of conductor wires twisted together may comprise two or more conductor wires.

Alternatively, each group of conductor wires may contain exactly two conductor wires: this is known as a "twisted pair".

The conductor wires can be twisted together in a helical or other manner known as the "SZ" manner.

The groups may all have the same number of conductor wires, or the number of conductor wires may vary from group to group.

Preferably, the pitch of the group helix can vary with the application of a periodic function, such as a sine function.

Of course, this feature is not limiting, and the pitch of the helix may change in any manner, for example.

The invention also provides a method of making the spirally wound electrical cable of the invention. The method includes winding two groups together to form a group helix. According to the invention, these groups are wound together so that the pitch of the group helix varies along the cable between two limiting values with the same sign, at a rate varying between two limiting speeds with the same sign.

The speed varying between the two speed limits can be an angular velocity at which the two groups are wound around the center line, and the center line translates at a constant linear speed.

Preferably, the rate of change in the two speed limits is the linear speed of the translational movement of the center line, the two groups being wound around the center line at a constant angular velocity. In this way it is possible to prevent the angular velocity of the winding from changing, which can be advantageous especially when the inertia of the winding device is relatively high.

The method of the invention can also be practiced without a physical centerline, thereby producing a spirally wound electric cable without a centerline of variable speed. The variable speed is the angular velocity of the winding or the linear velocity of the translational movement.

More generally, the present invention is not limited to the manner in which the present production method is performed.

The present invention also provides an apparatus for producing a spirally wound electric cable by practicing the method of the present invention. The apparatus includes means for winding two groups to form a group helix. According to the invention, the apparatus further comprises means for changing the pitch of the group helix between two limiting values with the same sign. Means to change the pitch of group helix are:

Two accumulators located upstream and downstream of the winding means, each having a moving drum capable of maintaining a varying length of the centerline; And

Control means for controlling the position of each moving drum;

The invention is not limited by the nature of the means for changing the pitch of the group helix.

Preferably, the manufacturing apparatus of the present invention comprises means for measuring the stiffness of the center line at the inlet of the winding means, the stiffness measuring means being connected to the control means. The stiffness measuring means makes it possible to better control the group helix pitch value, but the invention is not limited in any way.

The winding means preferably is:

Two reels, each feeding one of the group of twisted conductor wires;

Rotational drive means for causing the reel to rotate about a longitudinal axis;

A distribution plate having two edge openings each receiving one of the group of twisted conductor wires and a central opening receiving the centerline; And

A die disposed at the outlet of the distribution plate;

The invention is of course not limited by the features of the winding means.

Preferably, the manufacturing apparatus further comprises means for applying a binder at the exit of the die, ie two caterpillar-type pullers. This feature is not limiting.

The spirally wound electric cable according to the present invention configured as described above has an advantage of further reducing crosstalk.

1 illustrates a helically wound electrical cable in accordance with one embodiment of the present invention; And
2 is a view showing a manufacturing apparatus according to a preferred embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to preferred embodiments with reference to the accompanying drawings.

The spirally wound electrical cable shown in FIG. 1 comprises four groups P1, P2, P3, P4 wound together to form a group helix 1. Each group Pi (i represents 1 to 4) comprises two twisted conductor wires FCi1 and FCi2 and is therefore referred to as "pair".

For each pair Pi, the conductor wires FCi1 and FCi2 are twisted together in a spiral, but their pitches differ from pair to pair. That is, the pitch of the first pair P1 is shorter than the pitch of the second pair P2.

The spirally wound electrical cable may also include an outer layer (not shown) that protects the group helix 1.

The pitch of the group helix 1 varies along an electric cable spirally wound between the two limits. In the sinusoidal fragment of the electrical cable shown in FIG. 1, the pitch of the group helix is shown as the first value L1, the second value L2 and the third value L3.

Thus, the conductor wires of the pairs P1, P2, P3, P4 are hardly parallel to each other, but only parallel for a relatively short distance.

2 shows an example of an apparatus for manufacturing such a cable. This manufacturing apparatus 11 comprises winding means 6 for winding two groups 18a and 18b around the centerline 9. The center line 9 translates between the inlet caterpillar 2 and the outlet caterpillar 3.

Each group 18a, 18b comprises a plurality of twisted conductor wires, for example copper wire.

In this embodiment, the winding means 6 has reels 21a, 21b. Each reel 21a, 21b serves to supply one of the groups 18a, 18b. Rotational drive means (not shown) cause the reels 21a and 21b to rotate around the centerline 9. Thus, the two groups 18a and 18b are wound to form a group helix 20.

The winding means 6 also comprises a distribution plate 5 with two edge openings 23a and 23b and a central opening 24. Each edge opening 23a, 23b receives one of the groups 21a, 21b, respectively. The center opening 24 receives the center line 9. The winding means may also comprise a die 4 at the outlet of the distribution plate 5.

At the outlet of the die 4, a binder is applied to fix the group in which the binder applying means 3 is wound in place.

The groups 18a, 18b are wound around the center line 9 at a substantially constant angular velocity, for example 50 revolutions per minute (rpm). In contrast, the linear velocity of the centerline 9 changes with time at least in the winding means 6, so that the group helix 20 exhibits a pitch that varies along the spiral wound electrical cable thus produced.

The linear velocity of the center line 9 is almost constant over time upstream of the manufacturing apparatus 11 and downstream of the manufacturing apparatus 11, for example 0.1 m / s per second. The linear velocity of the center line 9 changes as it passes through the winding means 6.

The manufacturing apparatus 11 comprises means for changing the pitch of the group helix, which means comprises two accumulators 2, 8 arranged upstream and downstream of the winding means 6, respectively. Each accumulator 2, 8 includes moving drums 16, 17 that can maintain the varying length of the centerline 9. The linear velocity of the center line 9 changes each time the position of one or the other of the moving drums 16, 17 changes.

The manufacturing apparatus 11 also includes control means 10 for controlling the position of each moving drum 16, 17. The control means 10 are connected to accumulators 2, 8. The position of each moving drum 16, 17 is a function of the voltage magnitude of the corresponding control signals S1, S2 generated by the control means 10.

For example, when the first control signal S1 is nearly zero, the corresponding first moving drum 16 is at half the height of the first accumulator 8. When the first control signal S1 has a positive magnitude, the first moving drum 16 lies at the height of the upper half 25 of the first accumulator 8. When the first control signal S1 has a negative magnitude, the first moving drum 16 is placed at the height of the lower half 26 of the first accumulator 8.

The position of the second moving drum 17 in the second accumulator 2 moves in the same way according to the magnitude of the second control signal S2.

The first and second signals S1 and S2 can always be generated opposite in value. Thus, the positions of the first and second moving drums 16, 17 with respect to the midline at the intermediate height of each accumulator 2, 8 are opposite to each other.

As the moving drums 16 and 17 move, the linear velocity of the centerline through the winding means 6 changes.

Thus, the linear velocity of the centerline 9 passing through the winding means 6 is approximately equal to the linear velocity of the centerline upstream of the manufacturing apparatus 11 increased by the variation term. The change period is almost proportional to the first result of the first control signal. Thus the change period can be positive, negative or zero over time.

In order for the group helix 20 to be defined between two limiting values with the same sign, the control signals S1, S2 should not change too quickly. For example, the linear velocity of the centerline 9 can vary between about 0.075 kPa and 0.12 kPa. At this limiting linear velocity and angular velocity of about 50 rpm, the spiral pitch of the group varies between about 0.9 m and about 0.14 m. Of course these values are given by way of example only.

The pitch of the group helix 20 can be varied, for example, by the application of a sine function: in this case, the control signals S1, S2 are similarly sinusoidally changing.

The manufacturing apparatus 11 may also comprise means 7 for measuring the stiffness of the centerline 9. The stiffness measuring means 7 is connected to the control means 10 to control the control signal so that the center line linear velocity at the inlet of the winding means 6 is approximately equal to the center line linear velocity at the outlet of the winding means 6. I can regulate it.

Claims (6)

Spirally wound including at least two twisted conductor wires FC11, FC12, FC21 and FC22, each of which comprises at least two groups P1 and P2 wound together to form a group helix 1; In the electric cable,
Wherein the pitch (L1, L2, L3) of the group helix varies along the spirally wound electrical cable between two limiting values with the same sign. The method of claim 1,
A spirally wound electrical cable comprising at least one additional group helix. The method according to claim 1 or 2,
Wherein said group helix varies with a periodic function. The spirally wound electric according to any one of claims 1 to 3 comprising winding together two groups 18a and 18b, each comprising two twisted conductor wires to form a group helix 20. In the cable manufacturing method,
And the group is wound together such that the pitch of the group helix varies along the cable between two limiting values with the same sign, at a rate varying between two limiting speeds with the same sign. 5. The method of claim 4,
A speed varying between the two speed limits is an angular speed at which the two groups are wound around a center line, and the center line translates at a constant linear speed. 5. The method of claim 4,
The speed of change in the two speed limits is the linear speed of the translational movement of the center line (9), wherein the two groups (18a, 18b) are wound around the center line at a constant angular velocity.

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