WO2010012517A1

WO2010012517A1 - Catenary system

Info

Publication number: WO2010012517A1
Application number: PCT/EP2009/055799
Authority: WO
Inventors: Andre DÖLLING; Axel Schmieder
Original assignee: Siemens Aktiengesellschaft
Priority date: 2008-07-30
Filing date: 2009-05-14
Publication date: 2010-02-04
Also published as: DE102008035541A1; EP2307228A1

Abstract

The invention relates to a catenary system having at least one line which, in particular, is the contact wire or the carrying cable. In this case, there is a maximum permissible mechanical tensile stress in the line which depends by a factor, which is lower at a higher temperature, on the maximum permissible temperature of the line. The invention provides for the maximum permissible temperature to be greater than 100°C, and for the factor by which the maximum permissible mechanical tensile stress depends on the maximum permissible temperature to be a continuous function of temperature and time which is determined in a preliminary test.

Description

description

OberIeitungsanläge

The invention relates to a trolley system with at least one line, which is in particular the contact wire or the supporting cable, wherein a maximum allowable mechanical tension is present in the line, by a factor which is lower at a higher temperature, from the maximum permissible temperature of the line depends.

The permissible mechanical tensile stress or tensile load of a contact wire and, correspondingly, of a supporting cable may be determined from section 5.2.4 entitled "contact wires" from DIN EN 50119 of January 2002, pages 16 to 18. The permissible mechanical tensile stress σ is a product of tensile strength with new contact wire and several factors, of which one factor (K _te mp) describes the influence of temperature on tensile stress. Table 2 on page 17 shows the value of the factor K _te mp at certain temperatures Contact wire material and certain highest operating temperature assumes the factor K _te mp is therefore initially kept constant and only gradually changed.

The contact wire is heated by the electric current flowing in it and also by the environmental influences. So far, therefore, a maximum allowable temperature of 80 ⁰ C was usually allowed for the contact wire. Only certain materials could also be allowed 100 ⁰ C. It was therefore previously necessary at a higher current intensity to choose an enlarged cable cross-section for the contact wire in order to avoid an unacceptably high temperature. However, a larger cable cross-section leads to a higher weight of the contact wire and the entire overhead line and consequently to more complex supports (bases). A temperature above 100 ^° C. has hitherto also been disregarded because the usual material, namely copper or copper alloy, when it is exposed to higher temperatures than usual for longer periods of time. exposed to mechanical stress, mechanical strength loses and thus only withstand a lower mechanical tensile stress. Finally, a high temperature caused by the thermal expansion of the contact wire to lead to the maximum allowable lateral deflection of the contact wire is exceeded due to crosswinds, so that the pantograph of a vehicle with the contact wire is no longer in contact, so "derailed".

It has been found that an increased allowable temperature of the conduit, which is for example the trolley wire or the support cable, is desired. The higher the ambient temperature, the lower the load capacity of the overhead contact line, since the temperature range still remaining until the permissible temperature is reached, which determines the maximum possible current intensity in the overhead line, decreases. If z. B. maximum ambient temperatures of 35 ° C, remains at a maximum operating temperature of 80 ⁰ C only too low a temperature difference of 45 ° C, which may be caused by the flow of current in the line and from the line in the pantograph of a vehicle.

The invention is therefore based on the object to provide a trolley line, which permanently allows a maximum allowable temperature of the line, which is above 100 ⁰ C and z. B. may be up to 150 ⁰ C.

The object is achieved according to the invention in that the maximum allowable temperature is greater than 100 ⁰ C and that the factor by which the maximum allowable mechanical stress depends on the maximum allowable temperature, determined in a preliminary test continuous function of the temperature and the Time is.

An essential difference to the known is that the factor called K _te mp is not simply taken from a table, but is determined by a previously determined function. Thus, the advantage is achieved that the maximum allowable mechanical stress better than it was previously possible to determine, so that an oversized line, the z. B. is a contact wire is no longer necessary and that nevertheless a limitation of the mechanical strength of the line, which could cause damage, is not to be feared.

Although the maximum permissible temperature is greater than 100 ^° C., a high strength of the line and a high current carrying capacity are achieved, without the line having to have an oversized cross section. You can do with less material than before, so that the overhead line system is cost-effective.

For example, a continuous function for each line material is determined in each case in preliminary experiments or derived by analogies from preliminary tests. Thus, the advantage is achieved that a catenary system that is reliable and stable at a high temperature and still requires little material, if necessary, can be constructed of different materials.

For example, the maximum allowable mechanical tension in the line takes into account the wear of the line. This provides the additional advantage that the tensile stress can be adapted to the actually existing cable cross-section. There are thus advantageously saved material and costs.

For example, the maximum permissible temperature for contact wire and suspension cable is different. Thus, the advantage is achieved that the current carrying capacity of contact wire and suspension rope can be fully utilized despite different inductively related power distribution. For example, there is a maximum permissible change in length of the line, which depends on the mechanical tensile stress in the line, the thermal expansion of the line and on the creep strain of the line determined in a preliminary test.

The advantage is achieved that this consideration of an additional influencing variable, namely the creep, the total change in length, which then consists of the creep, caused by the mechanical tension change in length and the temperature-induced change in length, is more accurate than previously recorded. Thus, conditions are avoidable that lead to derailment of the pantograph due to excessive pivoting of the boom.

For example, with a larger maximum allowable change in length of the line, the lateral position of the laid in zig-zag line smaller. As a result, in the case of elongation, it can not happen that the line is displaced laterally so far that a current collector derails or no longer makes contact. The lateral posture, also called B dimension, is the maximum lateral distance of a zigzag-threaded lead from an imaginary axis.

For example, with a larger maximum allowable change in length of the line, the line-carrying boom longer. As a result, swing the boom and with them the line less in the lateral direction. The contact wire remains in the area of the pantograph.

For example, the lateral position of a laid in zig-zag line from a fixed point starting to a Nachspanneinrichtung is made smaller. As a result, the boom swing less.

For example, the line-carrying boom starting from a fixed point to the Nachspanneinrichtung are each longer than the previous boom. This pivots the boom and thus the line even with the greatest temperature-induced change in length less in the lateral direction and the line remains in the range of a pantograph of a vehicle, although a temperature above 100 ⁰ C is allowed.

For example, the line carrying boom are not pivotable. As a result, unwanted lateral movements of the line can be avoided.

To detect a change in length of the line, for example, at least one sensor is present, which is connected to an evaluation unit for detecting a deviation from a nominal change in length.

With the help of such sensors an excessive load on a line can be detected in good time. For example, if too much mechanical tension is detected, a weight stone may be removed from the tensioner to reduce the tension.

For example, in the case of deviation from the nominal value by the evaluation unit, the alarm can be triggered or a train slowed or stopped.

With the described additional monitoring of the change in length of the line and the resulting measures, the reliability of the overhead line system is further increased.

With the overhead contact line system according to the invention, in particular the advantage is achieved that with constant or even reduced material use and with sufficient strength, a maximum allowable temperature above 100 ⁰ C is possible. Such a trolley system is particularly important for countries with very high ambient temperature of great importance. The overhead contact line system according to the invention advantageously makes it possible, in spite of increased temperature of the line, in particular of the contact wire, and despite increased elongation of the line, to prevent a derailment of a current collector by reducing the lateral pivoting of the contact wire at least in critical sections.

Claims

claims

1. Catenary system with at least one cable, which is in particular the contact wire or the supporting cable, with a maximum allowable mechanical tension in the line is present, by a factor which is lower at higher temperature, from the maximum permissible temperature of the line depends, characterized in that the maximum allowable temperature is greater than 100 ⁰ C and that the factor by which the maximum allowable mechanical stress depends on the maximum allowable temperature, a predetermined in a preliminary experiment is a continuous function of temperature and time.

2. Catenary system according to claim 1, characterized in that each determines a continuous function for each line material in preliminary tests or derived by analogies from preliminary tests carried out.

3. overhead line system according to one of claims 1 or 2, characterized in that the maximum allowable temperature for contact wire and suspension cable is different.

4. overhead line system according to one of claims 1 to 3, character- ized in that a maximum allowable change in length of the line is present, the mechanical tensile stress in the line, the thermal expansion of the line and of the determined in a preliminary test creep of the line depends.

5. Catenary system according to claim 4, characterized in that at greater maximum permissible change in length of the line, the lateral position of the laid in zig-zag line is smaller.

6. overhead line installation according to one of claims 4 or 5, characterized in that at larger maximum allowable Length change of the line, the line-carrying boom are longer.

7. overhead line installation according to one of claims 1 to 6, character- ized in that the lateral position of a laid in zig-zag line from a fixed point starting to a Nachspanneinrichtung is made smaller.

8. Catenary system according to claim 7, characterized marked, that the line carrying boom starting from a fixed point to the Nachspanneinrichtung are each longer than the previous boom.

9. overhead line system according to one of claims 1 to 8, character- ized in that the line carrying boom are not pivotable.

10. overhead line system according to one of claims 1 to 9, characterized in that for detecting a change in length of the line at least one sensor is present, which is connected to an evaluation unit for detecting a deviating from a desired value change in length.

11. Catenary system according to claim 10, marked thereby, that is triggered by the deviation from the setpoint change in length by the evaluation alarm or slow down or stop a train.