SE536747C2 - Method and apparatus for determining the length of conductors - Google Patents

Description

The present invention relates to methods and apparatus for determining the physical length of connected conductors.

In a first aspect, the present description comprises a method in a network node for estimating at least a minimum physical length of at least one conductor in a conductor device connected to the network node, by detecting the conductor device comprising the at least one conductor with connectors arranged at both ends, one of which connector is connected to the node and the other is connected to another node. Furthermore, the method comprises the steps of determining a resonant frequency of the detected conductor device and estimating the minimum physical length of the at least one conductor based on at least the determined resonant frequency.

In a further aspect, the present description comprises a node in a network, which node comprises a detector arranged to detect a conductor device connected to the node, which conductor device comprises a conductor with connectors at each end, one of which connectors is connected to the node and the other is connected to another node. Furthermore, the node comprises a determining unit arranged to determine a resonant frequency of the detected conductor device, and an estimator arranged to estimate a minimum physical length of the connected conductor based on the comparison.

In another aspect, the present disclosure comprises a conductor device comprising at least one conductor with connectors in a network, suitable for use in a node according to the preceding aspect. In the conductor device, each connector comprises a resonant circuit with a predetermined characteristic resonant frequency.

Advantages of the present disclosure include prevention of overheating in electrical systems. BRIEF DESCRIPTION OF THE DRAWINGS The invention and further objects and advantages thereof are best understood by reference to the following description taken in conjunction with the accompanying drawings, in which: Figure 1 shows embodiments of a method according to the present description; Figure 2 shows embodiments according to the present description; Figure 3 shows further embodiments according to the present description; Figures 4a-d show circuit diagrams for further embodiments according to the present description; Figures 5a-5f show circuit diagrams used in assumptions relevant to the present description.

DETAILED DESCRIPTION As mentioned in the background part of this description, it is important to be able to monitor the power loss in conductors, especially in DC systems, where a high power loss results in a pronounced fire risk e.g. increased dissipation of heat in the system. In a recently presented DC system where nodes in the system are intelligent and communicate both DC voltage and information using e.g. optical / electrical cables or wires, this is even more important. In the event of excessive power loss, there is a risk of melting the optical conductor in the cable.

Two nodes in the system can be connected via a single conductor, or a conductor device that includes fl your series-connected conductors. After connecting the conductor, it is difficult to measure the physical length of each conductor or conductor device, which increases the risk of accidental overheating of some conductors due to too short a conductor length. It has therefore become important to be able to determine at least a minimum physical length of a conductor device, connected between two nodes in the system. The inventors have therefore realized the advantages of utilizing knowledge about the power supply in a conductor, and 10 15 20 25 30, 536 747 knowledge about natural quantities of the conductor, as well as predetermined qualities of known tagged conductors.

In this context, the term tagged conductor is used to denote a conductor or conductor device where the conductors have known resonant properties and thus support accurate estimation of the conductor properties such as length.

In this description, the inventors present a method for estimating at least a minimum physical length of a conductor device connected to a node, by measuring a resonant frequency of the conductor device. The conductors may include conductor pairs formed of electrical cables, optical / electrical cables, conductive rails, conductive plates, or other forms of conductors.

Referring to FIGURE 1, an embodiment of a method in a network node for estimating at least a minimum physical length of at least one conductor in a conductor device connected to the network node will be described.

At some point, a conductor device has been connected to a node in a system.

Initially, the presence of the conductor device is detected in step S10. The conductor device comprises at least one conductor with connectors arranged at both ends, one of which connectors is connected to said node and the other is connected to another node. Then, in step S20, a resonant frequency of the detected conductor device is determined. Finally, in step S50, a minimum physical length of the at least one conductor is estimated, based on the determined fCSOHanSffCkVCflSCn.

Furthermore, also with reference to Figure 1, another embodiment of a method in a network node for estimating at least a minimum physical length V of at least one conductor in a conductor device connected to the network node will be described. In order to estimate the minimum physical length of the conductor, the inventors have used known parameters for the conductor device e.g. by implementing predetermined conductor devices or conductors in 10 15 20 25 30 536 747 conductor devices. Thus, in step S30, a known resonant frequency dependent parameter is provided for the connected conductor device.

Thereafter, the detected resonant frequency is compared with said provided known parameter in step S40, and said minimum physical length of the connected conductor is estimated in step S50 based at least on said comparison.

The step of determining S20 a resonant frequency of the connected conductor device can be performed according to your various embodiments, some of which will be described below. According to one embodiment, the step S20 comprises determining a resonant frequency of said detected conductor device to measure a differential impedance as a function of frequency of a known LC circuit of the detected conductor device.

According to a further embodiment, the step S20 comprises determining a resonant frequency of the detected conductor device to measure the resonant frequency of an LC circuit comprising capacitances arranged in the connectors of said conductor device together with the capacitance of the conductor itself and an external inductance L arranged at said node. In particular, the estimated minimum physical length q can be determined according to Equation 1 below: l l 1 l 1 1 E; zqi KLOCO) _ ä; , / (2L + L ,,) (2C + CO) _ 5; \ / (2xL0 + Ln) (2xCO + c ,,) (1) where q = x + Ax, Ax w å-glx lm, and where LO is the inductance for lm of conductor, CO 0 0 is the capacitance of 1 m of conductor, q is the estimated conductor length, x is the physical conductor length, Ax is the fault due to 'LnCn, and LnyCn are known natural conductor properties Ln <known components. According to a particular embodiment, each of the artificially placed known components fl comprises your components such that L = L1 + ... + LjOCh C = C1 + ... + Cj.

An important observation regarding estimation of the resonant frequency is the disturbing noise caused by other signaling within the system. The Q value of the resonance is disturbed by each applied load in the system. In order to achieve an accurate estimation of the resonant frequency, it is therefore preferred that all applications e.g. applied loads in the system are silent e.g. does not transmit or receive for a predetermined period of time, typically one millisecond.

The accuracy of the estimation is more important for short lead lengths than for long lead lengths. This is also the situation where the resonant frequency is highest and can be measured quickly and accurately. For a longer conductor length, the resonant frequency is lower and needs a longer measurement time to be accurate, so a limited measurement time limits the accuracy. Thus, an embodiment comprises a further step of determining the resonant frequency during a forced period of the non-activity in said node, and thus prevents other signaling in the system from interfering with the resonant frequency measurements.

According to a further embodiment, the method comprises controlling the power distributed in the system through the conductor device based on the estimated physical conductor length. If the estimated length is below a predetermined length, or within a predetermined length range, the power is reduced by a certain amount.

The procedure for estimating the minimum physical conductor length is applicable to any combination of fl your predetermined conductors e.g. tagged conductor with predetermined frequency to length characteristics. In this case, the estimated minimum physical lead length is equal to the actual physical lead length. If, on the other hand, one or more of your marked conductors are connected in series with unmarked conductors, the estimated minimum physical length is equal to or greater than the physical length of the marked conductor. In the case of unlabeled conductors, a length estimation according to the present description will result in a length estimation which is much smaller than the actual length, thus preventing an unintentional power overload in the conductor.

Referring to Figure 2, embodiments of a network node 1 for estimating at least a minimum physical length of at least one conductor in a conductor device connected to the network node will be described. Figure 2 shows a system comprising a node 1 according to the present description. The system comprises two conductor devices 2 which are connected to the node 1. A conductor device 2 comprises a single conductor or conductor pair 4 with connectors 3 at each end. The second conductor device 2 comprises two conductors 4 (or pairs of conductors) connected in series. Each of the conductors 4 is provided with connectors 3 at each end.

The embodiment of node 1 in Figure 2 comprises a conductor detector 10 arranged to detect a connected conductor device 2, which conductor device 2 comprises a conductor 4 with connectors 3 at each end, one of which connectors is connected to node 1 and the other is connected to another (similar or different) node. The node 1 further comprises a resonant frequency determining unit 20 arranged to determine a resonant frequency of the detected conductor device 2 and a conductor length estimator 50 arranged to estimate a minimum physical length of the connected conductors based on the comparison.

According to a further embodiment, still with reference to Figure 2, the node 1 comprises a provider 30 arranged to provide a known resonant frequency dependent pairing network for the detected conductor device 2, and a comparator 40 arranged to compare the determined resonant frequency with the provided known resonant frequency dependent parameter. The provider 30 and the comparator 40 are preferably included in the resonant frequency determining unit 20, but may as well be implemented as separate units in the node 1. In addition to the estimator 50, the estimator 50 is further arranged to estimate the minimum physical length of the detected conductor based on the comparison.

According to a further embodiment, the node 1 comprises e.g. the resonant frequency determining unit 20 an optional resonant unit arranged to form an LC circuit together with the at least one connected conductor device 2. The resonant unit may comprise a C-component in each of said at least one connector and the capacitance of the conductor between the connector, and an L-component in said node 1 or connected between said node 1 and said detected at least one conductor device 2.

As previously mentioned, it may be advantageous to include a power control unit 60 in said node 1, designed to control a power distributed in said conductor device based on said estimated minimum physical length.

The embodiments described above rely on the presence of at least one so-called tagged conductor in the conductor device to be estimated. An embodiment of such a conductor will be described below with reference to Figure 2 and Figure 3. A conductor device 2 thus comprises at least one conductor 4 with connectors 3, each connector 3 comprising a resonant circuit 5 or mark (eng. "Tag") with a predetermined relationship between conductor length and resonant frequency. The mark (eng. "Tag") may comprise a resonant circuit e.g. LC circuit, or a capacitance which forms an LC circuit together with an external measuring circuit L arranged in or at the node 1 to which the conductor device 2 is connected.

The conductors or pairs of conductors described above may comprise an electrical cable or combined electro-optical cable, or conductive rail or the like.

To facilitate an in-depth understanding of assumptions related to the present disclosure, some examples of equivalent circuit diagrams will be described with reference to Figures 4A-4D and Figures 5A-10, 15 536 747 57, as well as some numerical examples. Although the examples are described with reference to pairs of conductors represented by cables or wires, the same reasoning can be applied to other conductors such as conductive rails or plates.

Figure 4A is a circuit diagram of a small segment of a natural wire e.g. unmarked cable length.

Figure 4B is a circuit diagram of a segment of a wire with tags at both ends.

Figure 4C is a circuit diagram of a series circuit with two marked wires.

Figure 4D is a circuit diagram of a series circuit with a labeled and an unlabeled natural wire.

In the present description, the resonance is calculated using a chain matrix method where chain-linked circuits are represented by matrix multiplication and natural circuit parameters Ln and Cn are less than the tag (L) parameters of the tag (L).

Below is a step-by-step circuit analysis based on Figures 5A-5F.

The matrix AL in Equation 2 is a matrix representation of a simple inductor L, as illustrated in Figure 5A.

The matrix AC in Equation 3 is a matrix representation of a parallel capacitance C, as illustrated in Figure 5B. Both Figure 5A and Figure 5B illustrate various so-called artificial elements that can be added to a conductor and the natural elements that occur when a resonant frequency is calculated for such an artificial element.

The matrix AL-Aci Equation 4 is a matrix representation of an LC element, as illustrated in Figure 5C. The circuit in Figure SC illustrates the combination of elements in Figure 5A and Figure 5B. l + zv2LC -zUL AfAczl -zvC l Jm) The matrix AT in Equation 5 is a matrix representation of an LC element where half L has fl been transferred to the ground trees (allowed for resonance calculations), as illustrated by Figure 5D. This is a cable equivalent to Figure 5C. l + ZLC -wL AT = AL-AC-AL ~ A,; AC = w <5) 5 5 ~ ZUC l One way to utilize the circuits and matrices described above is to consider all circuits as consisting of infinitesimally thin plates in the conductive system , whereby it is possible to represent the conductors with chain or series connection of the circuits in Figure 5C and Figure 5D.

The matrix A1 in Equation 6 is a matrix representation of the series connection of a labeled LC element and an LnCn natural wire segment, simplified to the conductive order of L and C, as illustrated by Figure 5E. Mark (eng. "Tag") The LC element is represented by the inductance L1 and the capacitance C1, and the natural wire segment is represented by an inductance Ln divided into Lgn on the ground wire and Lpn on the power wire e.g. 48 thread. 10 10 15 536 747 Alwßnwïc) -w (L + Ln) z -w (C + Cn) 1 6 (1 + w2LC) (1 + w2LnCn) + w2LCn -wL- (n-wïincnyv-Ln U -wC (1 + w2LnCn) i-wzLnc The matrix A2 in Equation 7 is a matrix representation of the series connection of a tag, a natural thread segment and another tag (tagged threads are tagged at both ends), as illustrated by Figure 5F. The two labeled LC elements are represented by the inductances Lg1, L12 and the capacitors C11, C12, and the natural wire segment is represented by an inductance Ln divided into Lgn on the ground wire and Lpn on the power wire eg the 48V wire (1 + 4w2LC) - w (2L + L ”) (7) -zv (2C + Cn) 1 The same reasoning can be used to form a corresponding matrix representation for a series of artificial LC elements connected at even or uneven distances.

According to the above, the resonant frequency ffesß fi can be estimated based on Equation 8 below. f _, z__1_.n ___} __? 27: (2L + L ,,) (2C + Cn) _1fi_ 1 _ 1 1: ff 2111101 UW <2L + L1> <2C + C1> 1 1 1 1) __._____: _. 3 211 zq LOCO 271 \ / (2xLO + L ,,) (2xCO + Cn) (q = x + Ax, Ax w L ”C"> <lmeter LOCO 11 lO 15 20 25 30 536 747 where the LO rated inductor for lm conductor eg cable, CO is the rated capacitance of lm conductors, q is the estimated conductor length, x is the physical conductor length, and Ax is the fault caused by natural LHC ”.

The consequence of the above is that x is the conductor length resonance created by the added marks, Ax contains all contributions from natural conductors and added unmarked conductors, q contains the marked and additional contributions. For series-connected conductors, the maximum allowable power Pmax on the entire transmission line is represented by Equation 9 below P HIÜX ï pHIÛXpEW fi 'x where Pmax is the maximum allowable power, pmapem is the maximum allowable power per meter of conductor, and x is the conductor length. This makes it possible to control the effect in the system by requiring that various applications in the system be shut down when Equation 10 below is met.

'PHIBÛVI 2 -plïí fl xpß flfl. q A numerical example gives: In a known way, the resonant frequency of an LC circuit according to Equation 1 1 is determined below.

L = 1 mH, c = 1oo nF emiss ks L = 2 mH, c = 2oonF + w = 7y97 kHz L = 1omH, c = 1tiF eaprsgs kHz Natural parameters: Ln = 0.56nH / m, Cn = 52.4 pF / m Assume that 100 m unmarked conductor added to ch marked conductor. 12 10 15 20 536 747 Ln = 56nH (95% LO), Cn = 5nF (è5% CO) -) causes 5% error in the resonant frequency estimated length 1.05 m The different embodiments according to the present description are applicable not only to special labeled conductors , but also on combinations of series-labeled conductors and conventional conductors.

Advantages of the present disclosure include improved security in electrical networks, and improved power control in such networks utilizing labeled conductors and conductor devices.

The above embodiments are to be construed as illustrative examples of the present invention. Those skilled in the art will appreciate that various modifications, combinations, and changes may be made in the embodiments without departing from the scope of the present invention. In particular, different sub-solutions in the different embodiments can be combined into other configurations when technically possible. The scope of the present invention is defined by the appended claims. 13

Claims (19)

536 747 PATENT REQUIREMENTS A method in a network node for estimating at least a minimum physical length of at least one conductor in a conductor device connected to said network node, characterized by the steps of: - detecting (S10) said conductor device comprising said at least one conductor with connectors arranged at both ends, one of which connectors is connected to said node and the other is connected to another node; determining (S20) a resonant frequency of said detected conductor device; estimating (S50) said minimum physical length of said at least one conductor based on at least said determined resonant frequency, and - controlling a power (S60) distributed by said conductor device based on said estimated minimum physical length. The method according to claim 1, characterized by: - providing (S30) a known resonant frequency dependent parameter for said connected conductor device; - comparing (S40) said detected resonant frequency with said provided parameter; and estimating (S50) said minimum physical length of said connected conductor based at least on said comparison. The method of claim 1 or 2, characterized in that said step of determining (S20) a resonant frequency of said detected conductor device comprises the step of: measuring a differential impedance as a function of frequency of an LC circuit in said detected conductor device to determine the resonant frequency for the detected cable device. The method of claim 1 or 2, characterized in that said step of determining (S20) a resonant frequency of said detected conductor device comprises the step of: measuring the resonant frequency of an LC circuit comprising capacitances arranged in the conductors of said conductor device together with the capacitance for the conductor itself and an external inductance arranged at said node. The method according to any one of claims 1-4, wherein said estimated minimum conductor length q is determined according to the expression: 1 ll 1 1 1 zf: za / (Locofz fl ./(2L+L,)(2c+c,)_2 fl Jpxronn fl zxc fi cn) LC . .. where q = x + Ax, Ax z _ "-”> <lm, where LO is the measured inductance for lm of the 0 0 conductor, Co is the measured capacitance of 1 m of the conductor, q is the estimated conductor length, x is the physical length of the conductor device, Ax is the fault caused by LnCn, and Ln, Cn are known natural conductor properties Ln < The method of claim 5, wherein said articulated known components L and C each comprise a plurality of articulated known components, wherein L = L1 + .. + Lj and C = C1 + ... Cj, and Ln = Lpn + Lgm where Ln is divided and represented by Lpn on power trees and Lgn on earth trees. The method of claim 1, wherein the step of determining a resonant frequency is performed during a forced period of inactivity in said node, during which period no other signaling occurs in the system. The method of any of claims 1-7, wherein said conductor comprises a pair of conductors. A node (1) in a network, characterized by: a detector (10) arranged to detect a conductor device (2) connected to said node (1), said conductor device (2) comprising a conductor with connectors in each end, one of which connectors is connected to said node and the other is connected to another node; a determining unit (20) arranged to determine a resonant frequency of said detected conductor device (2); an estimator (50) arranged to estimate a minimum physical length of said connected conductor based on said resonant frequency, and a control unit (60) arranged to control a power distributed by said conductor device based on said estimated minimum physical length. The node according to claim 9, comprising: - a provider (30) arranged to provide a known resonant frequency dependent parameter of said detected conductor device (2): a comparator (40) arranged to compare said determined resonant frequency with said provided known pair nets, and wherein - said estimator (50) is further arranged to estimate said minimum physical length of said detected conductor based on said comparison. The node according to claim 9, comprising a resonant unit arranged to form an LC circuit together with said at least one connected cable (2). The node according to claim 11, wherein said resonant unit comprises a C component in each said at least one conductor and the capacitance of the conductor between the connectors and an L component in said node (1) or connected between said node (1) and said detected at least one conductor device (2). The node according to any of claims 9-12, wherein said estimator is arranged to estimate a minimum physical length of a connected conductor comprising a pair of conductors. The node according to any one of claims 9 to 12, wherein said connector (3) each comprises a resonant circuit (5) having a predetermined characteristic resonant frequency. The node of claim 14, wherein said resonant circuit (5) comprises a predetermined LC circuit. The node according to claim 14, wherein said resonant circuit (5) comprises a capacitance (C) and is arranged to form an LC circuit together with an external measuring unit (L) arranged at a node (1) to which the cable device (2) can be connected. 17. l7. The node according to any of claims 14-16, wherein said conductor (4) comprises a pair of conductors. The node according to any of claims 14-17, wherein said conductor (4) comprises an electric cable or a combined electro-optical cable. The node of any of claims 14-17, wherein said conductor (4) comprises at least one conductive rail. 17