EP1719688A1 - Data communication system for railway vehicles - Google Patents

Abstract

The data communication system has input and output modules which are arranged in the vehicle or traction intelligent, which are connected by a modular or decentralized circuit with a vehicle or a traction bus system whereby a single or repeated redundancy of the system is formed.

Description

The invention relates to a data communication system for rail vehicles, which has one or more redundancies, in particular in the car or train, by a car or train bus and intelligent input and output modules. The data communication system according to the invention relates here to climate control and regulation systems in rail traffic, whereby a redundant system is created by a modular and decentralized circuit in conjunction with intelligent modules, whereby the system components are reduced. In this context, redundancy should be understood as the creation of additional, sometimes redundant, information or functions that are deliberately created for the purpose of fault tolerance. In case of failure of special components whose function is taken over by others, in the event of failure of which, in turn, possibly from others. The term "zero redundancy" means lack of redundancy.

• Wenn der Klimaregler defekt ist, fällt das gesamte Heizungs- und Klimasystem (HVAC) aus.
• Die Verkabelung einer solchen "sternförmigen" Schaltung zwingt zur Verlegung von Anschlüssen (DI, DO, AI ...) zwischen jeder Systemkomponente und dem Klimaregler CR. Bekanntermaßen hat ein Wagen im Allgemeinen eine durchschnittliche Länge von 15 bis 25 Metern. Daraus folgt, dass einige Kilometer Kabel verlegt werden
• müssen. Diese Verkabelung ist sehr anfällig auf elektromagnetische Störungen (PEM), die in einem Schienenfahrzeug häufig vorgefunden werden, wobei die Empfindlichkeit mit der Länge zunimmt. Die digitalen und analogen Informationen können somit leicht verfälscht werden, wenn keine Maßnahmen (CEM) gegen diese Störungen getroffen werden. Es ist selbstredend, dass diese Vorsichtsmaßnahmen entscheidende Mehrkosten in der Konzeption des elektrischen Systems und den Kabelbündeln mit sich bringen. Die Kosten für die Sternverkabelung (Material und Einbau) sind ebenso erheblich.

The current control concepts in rail transport with a system control on the car were based on a "centralized" circuit. All function-critical controllers of the heating and air conditioning system such as relays, contactors, sensors (TS), etc. are connected to a main climate controller to ensure data acquisition and system control (see Figure 1).
The circuit has a relatively simple and easy to implement concept. However, it has two serious weaknesses in redundancy and cabling:

• If the climate controller is faulty, the entire heating and air conditioning system (HVAC) fails.
• The wiring of such a "star-shaped" circuit forces the laying of terminals (DI, DO, AI ...) between each system component and the climate controller CR. As is known, a car generally has an average length of 15 to 25 meters. It follows that a few kilometers of cables are laid
• have to. This cabling is very susceptible to electromagnetic interference (PEM), which is common in rail vehicles, with sensitivity increasing with length. The digital and analog information can thus easily be falsified if no measures (CEM) are taken against these disturbances. It goes without saying that these precautionary measures entail significant additional costs in the design of the electrical system and the cable bundles. The costs for star wiring (material and installation) are also considerable.

In a system control on the train the climate controller (CR) - and information and diagnostic interfaces (LID) - circuit is usually "classical" constructed (see Figure 2).
Each HVAC is locally connected to a Train Information and Control System (TMS) via the LID connection (primarily to a CAN, MVB, LON, Ethernet ... fieldbus). This requires at least one LID connection per car and air conditioning system (more if the system is to be redundant). At the information, diagnostic and
Maintenance systems (TMS and CID) of the train, this known circuit for redundancy and cost described in Figure 2 also proves to be disadvantageous. Any malfunction or network interruption (TMS) involves the risk of an immediate loss of information between the different cars; with a zero redundancy the comfort behavior is disturbed. Each car must be equipped with an LID (MVB or LON port, for example), which greatly affects the overall cost of the system.

In the DE 4307 897 A1 a control and monitoring device is described in combined to form a train rail vehicles, being created by interconnection of control and diagnostic redundancy in the operation of additional on-board control units.

From the EP 1 010 601 B1 is a data communication system on the train, with a train bus for communication between vehicles of the train and each vehicle associated vehicle bus systems known, each via a gateway to the train bus are coupled, wherein at least one vehicle, a master function for control in the train is accepted. It is intended to protect the redundancy of a vehicle bus as a master vehicle bus, if at least one further vehicle bus is arranged as a master vehicle bus parallel to the master vehicle bus, which is exclusively coupled to system components with primary control value generating functions.

It is an object of the present invention to overcome the deficiencies of the currently known data communication systems for climate control systems such as lack of redundancy, sensitive cabling and high costs described in the previous paragraph.

1. 1. Die Verkabelung ist geringer, da sich jedes Modul physisch «so nah wie möglich» am Steuerungsbauteil befindet. Die Module sind untereinander nur mit einer 2adrigen lokalen CAN "Schleife" verbunden.
2. 2. Die Verringerung der Kabellänge hat deutlichen Einfluss auf eine verbesserte CEM an den Steuerbauteilen und dem lokalen Netz, das sozusagen unempfindlich auf Störungen (PEM) wird, da es sich um ein Netz kompletter Informationen (frames) handelt, einschließlich Kontrolle der Sendung, des Empfanges und der Integrität der Daten (trifft auf einen 2adrigen Ein-Aus-Anschluss zum Beispiel nicht zu).
3. 3. Bei Unterbrechung des lokalen CAN-Netzes oder einem versagenden MC verfügt jedes I/OModul über eigene "interne" Intelligenz, durch die die HVAC Hauptbauteile lokal in einem geschlossenen Ring kontrolliert werden können, um so ein zufriedenstellendes Komfortniveau zu erreichen. Das System ist insofern redundant, als dass eine Unterbrechung des CAN-Netzes oder ein MC-Ausfall keinen kompletten Systemausfall verursacht (es wird auf der Stufe "abgestuft" gearbeitet) (Fig. 3c).

According to the invention, this object is solved by the features of claim 1. Advantageous developments of the invention are contained in the accompanying claims.
The invention accordingly includes a data communication system for climate control and regulation systems in rail vehicles, wherein in the car or train intelligent input and output modules (IO) are arranged by a modular and decentralized circuit with a car and / or train bus system (CAN, TMS) connected, creating a redundancy of the system.
The advantages of the invention will be described in more detail with reference to the drawings and the following embodiments.
The circuits shown in FIGS. 3a and 3b are modular and decentralized and relate to the system control on the car.
Each module (IO) and each sensor is connected via a local CAN network (control area network) to a central controller (master controller MC) (FIG. 3a) or directly to the train network (TMS) if both networks are compatible with each other (FIG. 3b).
The advantage of this solution is in three points:

1. 1. The wiring is lower because each module is physically "as close as possible" to the control component. The modules are interconnected only with a 2-wire local CAN "loop".
2. 2. The reduction in cable length has a significant impact on improved CEM on the control components and the local area network, which is virtually immune to interference (PEM), as it is a network of complete information (frames), including control of the broadcast, the Reception and integrity of the data (does not apply to a 2-wire on-off connection, for example).
3. 3. In case of interruption of the local CAN network or a failing MC, each I / O module has its own "internal" intelligence, which allows the HVAC main components to be controlled locally in a closed loop to achieve a satisfactory level of comfort. The system is redundant in that interrupting the CAN network or failing MC does not cause a complete system failure (it is done at the "staged" level) (Figure 3c).

The circuit according to the invention according to FIG. 4a expands the previous concept not only on the individual wagon but also on the entire train, the aim being to ensure a redundancy of the exchange of information via TMS and to reduce the number of LIDs and possibly MC interfaces.

Figure 4a shows a system for reducing the LID to two units on the entire train. Each car has a local climate controller (CR). If one CR fails, the control can be taken over by another CR according to FIG. 4b.
If all CRs fail, the central train computer can take control (see FIG. 4c), or the situation described in the above-mentioned section occurs according to FIG. 3c. In the event of failure of the CAN network, the situation described in the above-mentioned section according to FIG. 3c occurs: -> two-fold redundancy.

In the case of a TMS failure, the CAN network "takes over" the exchange of information. In the case of a MC failure, another controller "takes over" the information exchange.
Double redundancy of the train information system: The information is available via TMS and the CAN network: The control and information functions are protected.
Figure 4d also shows a system for reducing the number of LIDs, but without local climate controls. The control / control system of each car is double-protected by the two MCs for the entire train. As soon as one MC fails, the second secures the functions. That means redundancy. If the TMS fails, the CAN network "takes over" the exchange of information. - Redundancy of the HVAC information system, (see Figure 4e).
If one MC fails, the other controller takes over the exchange of information via the TMS and CAN network (see FIG. 4f).
Double redundancy of the train information system: The information is available via TMS and the CAN network: The control and information functions are guaranteed:.

CC:

Kontrolle/Steuerung

LID:

Informations- und Diagnoseschnittstelle

TMS:

Zugüberwachungssystem - Zuginformations- und Kontrollsystem (im allgemeinen "Zugnetz" genannt)

HVAC:

Heizungs- und Klimaanlage

CR:

Klimaregler

DI:

digitaler Ausgang: 2-Leiter-Ausgang Ein-Aus

DO:

digitaler Eingang: 2-Leiter-Eingang Ein-Aus

Al:

analoger Eingang: Eingang analoges Signal

EV:

Magnetventil

PEM:

elektromagnetische Störungen

CEM:

elektromagnetische Kompatibilität

IO:

digitales Eingangs-/Ausgangsmodul

MC:

Zentraler Regler

TS

Temperatursensor

List of reference numbers used:

CC:

Control / Control

LID:

Information and diagnostic interface

TMS:

Train monitoring system - train information and control system (commonly called "train network")

HVAC:

Heating and air conditioning

CR:

air regulator

DI:

digital output: 2-wire output on-off

DO:

digital input: 2-wire input on-off

al:

analog input: input analog signal

EV:

magnetic valve

PEM:

electromagnetic interference

CEM:

electromagnetic compatibility

IO:

digital input / output module

MC:

Central controller

TS

temperature sensor

Claims (5)

Data communication system for Klimasteuerungs- and control systems in rail vehicles, characterized in that in the car or train intelligent input and output modules (IO) are arranged, which are connected by a modular and decentralized circuit with a car or train bus system (CAN, TMS), whereby a single or multiple redundancy of the system is bildbar. Data communication system according to claim 1, characterized in that the car or train is equipped with only one air conditioning controller (HVAC-CR). Data communication system according to claim 2, characterized in that the intelligent input and output modules (IO) and arranged in the car sensors (TS) via a local area network (CAN) to the central air conditioning controller (HVAC-CR) are connected. Data communication system according to claim 1, characterized in that the train has fewer air conditioning computers than cars or air conditioners connected to the train network (TMS) and the local area network (CAN). Data communication system according to one of the above claims, characterized in that each intelligent input and output modules (IO) has its own internal intelligence, through which the components of the heating and air conditioning are locally controllable.

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