CN111257688B - Method for evaluating electrical performance of electrified railway contact net - Google Patents

Abstract

The invention discloses an electric performance evaluation method for an electrified railway contact network, and belongs to the technical field of electrified railway power supply. The power supply arm is divided into a section 1 and a section 2; the upper contact line T1 has a self-impedance of Z_T1The self-impedance of the lower contact line T2 is Z_T2The mutual impedance of the complex line direct supply contact net is Z_TT(ii) a Synchronously measuring the head end voltage and the tail end voltage of an uplink contact line T1, the current of an uplink contact line T1, the head end voltage and the tail end voltage of a downlink contact line T2 and the current of a downlink contact line T2 of the section 1 when a train is at the head end of a power supply arm of the section 1; when the train is at the end of the power arm of section 1, the head end voltage, the current of the up contact line T1, the head end voltage, the end voltage, and the current of the down contact line T2, T2 of section 1 are measured simultaneously. The difference between the virtual impedance and the theoretical value of the virtual impedance can be used for recording and judging the change trend of the electrical performance of the contact network section.

Description

Method for evaluating electrical performance of electrified railway contact net

Technical Field

The invention relates to the technical field of traction power supply of electrified railways.

Background

Electric traction is adopted in high-speed railways in China without exception. With the increase of the mileage of the high-speed railway, the safe and good operation of the traction power supply system cannot be paid high attention.

The traction net is not standby and exposed in the nature, and the bow net is contacted at a high speed, so that the fault is easily caused, the power failure is caused, and the normal operation is influenced. The traction power supply system has a complex structure and severe working conditions. The contact network erected along the railway line has numerous parts, is widely distributed geographically, works in an open environment, needs to bear the high-speed impact of a locomotive pantograph, is not standby, and has the characteristic that the fault of a traction power supply system is easy to occur.

At present, a fault post-processing mode is generally adopted by a railway power supply system, the fault recovery speed is low, and huge economic loss and adverse social influence are easily caused. The current management mode of the traction power supply system has the following problems:

(1) the failure is treated only after the failure occurs. The daily running state of a traction power supply system is not known, the treatment is only carried out after the occurrence of the fault, the passive treatment mode is adopted, the on-site emergency repair mode brings huge working pressure to on-site emergency repair personnel, personal injury accidents are easily caused, and the requirement of a railway on the high accuracy of the state of a contact network is difficult to meet.

(2) The seek and recovery speed after a failure is slow. The existing fault diagnosis method has the advantages of low precision, large workload of searching and processing after the fault and long train outage time.

(3) There is a lack of effective failure prevention measures. The condition that probably takes place to the future of traction power supply system is estimated inadequately, lacks effective intervention measure.

The occurrence of equipment or system faults is the result of accumulation of a plurality of factors over time, the generation and development of the faults necessarily go through a time process, sometimes the faults seem to be accidental, the internal regularity also exists, and even sudden faults also exist in the induction and development period. If the running state of the traction power supply system can be accurately evaluated, the real-time working state of the system is mastered, the law of the evolution and development of the system state is summarized, the abnormality of the equipment or the system can be identified in advance according to the law, the equipment or the system is overhauled or replaced in advance, the probability of accidents of the traction power supply system can be reduced, and the occurrence of faults is avoided.

Disclosure of Invention

The invention aims to provide an electric performance evaluation method for an electrified railway contact net, which can effectively solve the technical problem of calculating the virtual impedance of a contact net section on line and comparing the virtual impedance with a theoretical calculation value in real time.

The invention solves the technical problem, and adopts the technical scheme that: an electric performance evaluation method of an electrified railway contact network comprises the steps that an ascending contact line T1, a descending contact line T2, a steel rail R, an ascending contact line T1 and a descending contact line T2 at the head end of a contact network power supply arm are connected in parallel, an ascending contact line T1 and a descending contact line T2 at the tail end of the power supply arm are connected in parallel, and the power supply arm is divided into a section 1 and a section 2; the upper contact line T1 has a self-impedance of Z_T1The self-impedance of the lower contact line T2 is Z_T2The mutual impedance of the complex line direct supply contact net is Z_TT(ii) a Simultaneously measuring the head end voltage of the section 1 up line contact T1 when the train is at the head end of the section 1 power arm

Terminal voltage

Current at the upper contact line T1

Head end voltage of down contact line T2

Terminal voltage

Lower contact line T2 current

The head end voltage of the section 1 up line contact line T1 is measured simultaneously as the train is at the end of the section 1 power arm

Terminal voltage

Current at the upper contact line T1

Head end voltage of down contact line T2

Terminal voltage

Current at lower contact line T2

(1) When the train goes into the section 1 and the section 1 every time and the section 1 goes down without train, the virtual impedance Z of the contact line T1 is calculated by the formula (1)_T1(xn)Calculating the virtual impedance Z of the contact line T2 by using the formula (2)_T2(xn)。

Virtual impedance Z of contact line T1_T1(xn)Theoretical value of (Z)_T1(ll)The virtual impedance Z of the contact line T2 is obtained from the equation (3)_T2(xn)Theoretical value of (Z)_T2(ll)As is obtained from the formula (4),

Z_T1(ll)＝D(Z_T-Z_TT) (3)

Z_T2(ll)＝D(Z_T-Z_TT) (4)

in the formula: the unit of the length D is km, and the unit of each impedance Z is Ohm/km; head end voltage of each power supply arm

And terminal voltage

All units of (1) are V, each current

And

the unit of (A) is A;

(2) virtual impedance Z of segment 1 contact line T1_T1(xn)With its theoretical value Z_T1(ll)Substantially equal, segment 1 contact line T1 has no change in electrical properties; virtual impedance Z of segment 1 contact line T1_T1(xn)Greater than its theoretical value Z_T1(ll)Judging whether the contact line T1 of the section 1 has strand breakage, line breakage, increased abrasion or carrier cable line breakage;

(3) virtual impedance Z of segment 1 contact line T2_T2(xn)With its theoretical value Z_T2(ll)Substantially equal, segment 1 contact line T2 has no change in electrical properties; virtual impedance Z of segment 1 contact line T2_T2(xn)Greater than its theoretical value Z_T2(ll)Judging whether the contact line T2 of the section 1 has strand breakage, line breakage, increased abrasion or carrier cable line breakage;

(4) virtual impedance Z of segment 1 contact line T1_T1(xn)Less than its theoretical value Z_T1(ll)And the virtual impedance Z of segment 1 contact line T2_T2(xn)Less than its theoretical value Z_T2(ll)If yes, judging that the distance between the upper contact lines T1 and the lower contact lines T2 is shorter;

contact segment 1 with virtual impedance Z of line T1_T1(xn)Virtual impedance Z of contact line T2_T2(xn)And recording to form a historical database, generating a change trend, and when the change quantity of the change trend exceeds a set value, carrying out maintenance and repair on the section.

When the same electrified railway or a power supply arm is divided into a plurality of sections, the error between the virtual impedance of the contact line of each section and a theoretical value is basically close, and the section with larger difference is judged to have construction quality problems.

The working principle of the invention is as follows: electrical property of contact network of electrified railway adopting uplink and downlink parallel direct power supply mode of regional stationThe method comprises the steps that an electrified railway complex line direct supply uplink contact line T1, a downlink contact line T2, a steel rail R and a power supply arm are connected in parallel at the head ends T1 and T2 and at the tail ends T1 and T2, and the power supply arm is divided into a section 1 and a section 2; the upper contact line T1 has a self-impedance of Z_T1The self-impedance of the lower contact line T2 is Z_T2The mutual impedance of the uplink and downlink contact networks is Z_TT(ii) a Synchronously measuring the voltage at the head end of the upstream contact line T1 of the section 1 when the vehicle is at the head end of the section 1

And terminal voltage

Current at the upper contact line T1

Head end voltage of down contact line T2

And terminal voltage

Lower contact line T2 current

Synchronously measuring the voltage at the head end of the section 1 upstream contact line T1 when the vehicle is at the end of the section 1

And terminal voltage

Current at the upper contact line T1

Head end voltage of down contact line T2

And terminal voltage

Lower contact line T2 current

When the train goes into the section 1 and the section 1 every time and the section 1 goes down without train, the virtual impedance Z of the contact line T1 is calculated by the formula (1)_T(xn)Calculating the virtual impedance Z of the contact line T2 by using the formula (2)_F(xn). Virtual impedance Z of contact line T1_T1(xn)Theoretical value of (Z)_T1(ll)The virtual impedance Z of the contact line T2 is obtained from the formula (3)_T2(xn)Theoretical value of (Z)_T2(ll)Obtained from equation (4). The change trend of the electrical performance of the contact network section can be recorded and judged by utilizing the difference between the virtual impedance and the corresponding theoretical value of the virtual impedance, and when the change quantity of the change trend exceeds a set value, the section is overhauled and maintained, so that the occurrence of accidents is reduced.

Compared with the prior art, the technology of the invention has the beneficial effects that:

firstly, the virtual impedance of a contact net is calculated by utilizing the voltage and the current at two ends of a section where a train enters and leaves, and the broken strand, the broken line and the like of the contact net are identified.

And secondly, recording and judging the electrical performance change trend of the contact network section by utilizing the difference between the virtual impedance and the corresponding virtual impedance theoretical value, and when the change quantity of the contact network section exceeds a set value, overhauling and maintaining the section, thereby reducing the occurrence of accidents.

And thirdly, the universality is good, and the implementation is easy.

Drawings

FIG. 1 is a flow chart of the present invention.

Fig. 2 is a schematic view of the train of the present invention at the head end of section 1.

Figure 3 is a schematic representation of the train of the present invention at the end of zone 1.

Detailed Description

As shown in fig. 1, an embodiment of the present invention provides a method for evaluating electrical performance of a contact network of an electrified railway in a regional station, where after a train enters a section 1 and leaves the section 1 each time, a virtual impedance Z of an uplink contact line T1 is calculated by using a formula_T1(xn)Virtual impedance Z of lower contact line T2_T2(xn). Segment 1 contact line T1 virtual impedance Z_T1(xn)With its theoretical value Z_T1(ll)Substantially equal, segment 1 contact line T1 has no change in electrical properties; segment 1 contact line T1 virtual impedance Z_T1(xn)Greater than its theoretical value Z_T1(ll)At this time, there may be strand breaks, wire breaks, increased wear or carrier cable breaks in the segment 1 contact line T1. Segment 1 contact line T2 virtual impedance Z_T2(xn)With its theoretical value Z_T2(ll)Substantially equal, segment 1 contact line T2 has no change in electrical properties; segment 1 contact line T2 virtual impedance Z_T2(xn)Greater than its theoretical value Z_T2(ll)At this time, there may be strand breaks, wire breaks, increased wear or carrier cable breaks in the segment 1 contact line T2. Segment 1 contact line T1 virtual impedance Z_T1(xn)Less than its theoretical value Z_T1(ll)And segment 1 contact line T2 virtual impedance Z_T2(xn)Less than its theoretical value Z_T2(ll)It may be that the distance between the upper contact line T1 and the lower contact line T2 becomes shorter.

As shown in fig. 2, the electrified railway complex line direct supply uplink contact line T1, the downlink contact line T2, the steel rail R, the head end T1 and the T2 of the power supply arm are connected in parallel, the tail end T1 and the tail end T2 are connected in parallel, and the power supply arm is divided into a section 1 and a section 2; the upper contact line T1 has a self-impedance of Z_T1The self-impedance of the lower contact line T2 is Z_T2The mutual impedance of the uplink and downlink contact networks is Z_TT(ii) a Synchronously measuring the voltage at the head end of the upstream contact line T1 of the section 1 when the vehicle is at the head end of the section 1

And terminal voltage

Current at the upper contact line T1

Head end voltage of down contact line T2

And terminal voltage

Lower contact line T2 current

Synchronously measuring the voltage at the head end of the section 1 upstream contact line T1 when the vehicle is at the end of the section 1

And terminal voltage

Current at the upper contact line T1

Head end voltage of down contact line T2

And terminal voltage

Lower contact line T2 current

Calculating the virtual impedance Z of the contact line T1 by formula each time the train enters the section 1 and exits the section 1 and the section 1 does not run simultaneously_T(xn)Virtual impedance Z of contact line T2_F(xn). The change trend of the electrical performance of the contact network section can be recorded and judged by utilizing the difference between the virtual impedance and the corresponding theoretical value of the virtual impedance, and when the change quantity of the change trend exceeds a set value, the section is overhauled and maintained, so that the occurrence of accidents is reduced.

Claims (1)

1. An electric performance evaluation method of an electrified railway contact network comprises the steps that an ascending contact line T1, a descending contact line T2, a steel rail R, an ascending contact line T1 and a descending contact line T2 at the head end of a contact network power supply arm are connected in parallel, an ascending contact line T1 and a descending contact line T2 at the tail end of the power supply arm are connected in parallel, and the power supply arm is divided into a section 1 and a section 2; the upper contact line T1 has a self-impedance of Z_T1The self-impedance of the lower contact line T2 is Z_T2，The mutual impedance of the complex line direct supply contact net is Z_TT(ii) a Simultaneously measuring the head end voltage of the section 1 up line contact T1 when the train is at the head end of the section 1 power arm

Terminal voltage

Current at the upper contact line T1

Head end voltage of down contact line T2

Terminal voltage

Lower contact line T2 current

The head end voltage of the section 1 up line contact line T1 is measured simultaneously as the train is at the end of the section 1 power arm

Terminal voltage

Current at the upper contact line T1

Head end voltage of down contact line T2

Terminal voltage

Current at lower contact line T2

The method is characterized in that:

(1) when the train goes into the section 1 and the section 1 every time and the section 1 goes down without train, the virtual impedance Z of the contact line T1 is calculated by the formula (1)_T1(xn)Calculating the virtual impedance Z of the contact line T2 by using the formula (2)_T2(xn)：

Virtual impedance Z of contact line T1_T1(xn)Theoretical value of (Z)_T1(11)The virtual impedance Z of the contact line T2 is obtained from the equation (3)_T2(xn)Theoretical value of (Z)_T2(11)As is obtained from the formula (4),

Z_T1(11)＝D(Z_T-Z_TT) (3)

Z_T2(11)＝D(Z_T-Z_TT) (4)

in the formula: the unit of the length D is km, and the unit of each impedance Z is Ohm/km; head end voltage of each power supply arm

And terminal voltage

All units of (1) are V, each current

And

the unit of (A) is A;

(2) virtual impedance Z of segment 1 contact line T1_T1(xn)With its theoretical value Z_T1(11)Substantially equal, segment 1 contact line T1 has no change in electrical properties; virtual impedance Z of segment 1 contact line T1_T1(xn)Greater than its theoretical value Z_T1(11)Judging whether the contact line T1 of the section 1 has strand breakage, line breakage, increased abrasion or carrier cable line breakage;

(3) virtual impedance Z of segment 1 contact line T2_T2(xn)With its theoretical value Z_T2(11)Substantially equal, segment 1 contact line T2 has no change in electrical properties; virtual impedance Z of segment 1 contact line T2_T2(xn)Greater than its theoretical value Z_T2(11)Judging whether the contact line T2 of the section 1 has strand breakage, line breakage, increased abrasion or carrier cable line breakage;

(4) virtual impedance Z of segment 1 contact line T1_T1(xn)Less than its theoretical value Z_T1(11)And the virtual impedance Z of segment 1 contact line T2_T2(xn)Less than its theoretical value Z_T2(11)If yes, judging that the distance between the upper contact lines T1 and the lower contact lines T2 is shorter;

contact segment 1 with virtual impedance Z of line T1_T1(xn)Virtual impedance Z of contact line T2_T2(xn)And recording to form a historical database, generating a change trend, and when the change quantity of the change trend exceeds a set value, carrying out maintenance and repair on the section.

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