DE102022001818A1 - Method for reducing the transmission resistance on contacts in bidirectional bus systems - Google Patents

Abstract

Method and circuit arrangement for reducing the transmission resistance on contacts in bidirectional bus systems by fritting, whereby: data from one participant is transmitted via the separable contacts at the line ends to another participant that can be disconnected and/or coupled, regardless of the interconnection of the contacts of the connected ones Participants always have a frit voltage generated by the voltage source provided in each participant present at these contacts and a current flow of the frit current is ensured at the contacts at the line ends of a participant and the voltage sources are designed and each loaded with a series resistance in such a way that when the contacts are joined together Add voltages through bidirectional power transfer.

Description

The invention relates to a method for reducing the transmission resistance on separable contacts on lines in bidirectional bus systems by fritting, with data from one participant being transmitted via the separable contacts at the line ends to another participant that can be disconnected and/or coupled.

Frit voltage is an electrical voltage that breaks through a foreign layer resistance. The current that flows is called the frit current. Foreign layers can e.g. B. represent electrically non-conductive oxides, corrosion, contamination, etc. on electrical contacts or cable connection points. Eg is from the DE-PS 24 44 238 a method for reducing the transmission resistances on contacts of lines by fritting (also referred to as fritting) is known, with data from a first participant being fed to a second participant via the line using a transmitter and a transmission signal.

Bus systems such as Ethernet or Single Pair Ethernet allow, in addition to data transmission, also the transmission of power. In this case we speak of Power over DataLine (PoOL). However, this power transmission is always unidirectional, i.e. H. one physical node serves as a power source (power supply) and the other as a power sink (load).

For the vast majority of applications, this type of power transmission is completely sufficient, especially since a “slave” is normally supplied with electrical energy by a “master”. However, there are areas of application in which bidirectional power transmission is advantageous. With a view to modernizing freight wagons in the railway sector, the aim is to develop and standardize a digital automatic coupling (DAK). In addition to a mechanical coupling, the cars are also electrically coupled to each other, so that in addition to a power connection from the locomotive to the last car, there is also a data connection. In the case of such a separate data line, the problem is that, due to wear, contamination, etc., the contact surfaces quickly corrode or other contact resistance arises. In order to avoid or at least reduce this corrosion effect, the so-called fritting described above is also used.

In the railway sector in question, the problem arises that the railway carriages can be coupled to one another in both directions, as in 1 is shown. Two freight wagons are shown schematically here as an example, as well as four pairs of contacts, which are designed twice for redundancy in this example. How out 1 It can also be seen that each freight car has, in addition to the 2 physical nodes (Phy) and a switch, a power source and a power sink, as is the case, for example. B. is specified in the IEEE 802.3.cg standard for SPE. As can be seen from this illustration, power can be transferred from car 1 to car 2 without any problems.

However, the situation is different if the rail cars are coupled in such a way that power supply is connected to power supply or load is connected to load. In these cases, no power transfer is possible, see 2 . In this constellation, no frit current can be ensured between the contacts of the carriage couplings. Fritting therefore happens to depend on the correct arrangement of cars. The same also applies if other coupled participants with the same interfaces are used instead of the rail cars.

A solution to this problem would be to install the entire data bus equipment four times per car, see 3 . A power source is always connected to a power sink, even if the train sequence changes. In this way it could be ensured that a frit current flows permanently over the contacts. However, this solution has the disadvantage that the entire bus equipment, including PoDL, has to be used twice per car, which represents a significant cost factor. It is also necessary to use a switch with 4 ports instead of one with only 2 ports per car.

Based on the prior art presented, the invention is based on the object of specifying a method and a circuit arrangement with which a frit current is permanently available even with bidirectional power transmission and secure data transmission is guaranteed.

• Die Daten werden von einem Teilnehmer über die trennbaren Kontakte an den Leitungsenden an einen weiteren ab- und/oder ankoppelbaren Teilnehmer übertragen,
• unabhängig von der Zusammenschaltung der Kontakte der miteinander verbundenen Teilnehmer liegt immer an diesen Kontakten eine von jeweils in einem Teilnehmer vorgesehenen Spannungsquelle generierte Frittspannung an und es ist ein Stromfluss des Frittstromes an den Kontakten an den Leitungsenden eines Teilnehmers gewährleistet,
• ferner sind die Spannungsquellen so ausgebildet und mit jeweils einem Serienwiderstand belastet, dass sich beim Zusammenfügen der Kontakte die Spannungen durch eine bidirektionale Leistungsübertragung addieren.

According to the invention, a method for reducing the transmission resistance on separable contacts on lines in bidirectional bus systems by fritting is specified, which is characterized by the following method steps:

• The data is transmitted from one participant to another participant who can be disconnected and/or coupled via the separable contacts at the line ends,
• regardless of the interconnection of the contacts of the connected participants A frit voltage generated by the voltage source provided in each participant is always present at these contacts and a current flow of the frit current is ensured at the contacts at the line ends of a participant,
• Furthermore, the voltage sources are designed and each loaded with a series resistance so that when the contacts are joined together, the voltages add up through a bidirectional power transmission.

Further advantageous process steps and refinements thereof are specified in subclaims 2 to 9, including measurement and circuit details. Claims 10 and 11 specify structural arrangements and a circuit with which the method can be implemented. Appropriate areas of application of the method are specified in claim 12, although the application is not limited to this.

When implementing the method, direct current or alternating current can in principle be used to generate the frit voltage or the frit current. The selection of the type of voltage source should be made taking into account the requirements for the frit current and the requirements for data transmission.

It is also expedient for the frit current and/or the frit voltage to be measured permanently or at intervals and for the measured values to be evaluated to determine the contact quality. For this purpose, the corresponding known measuring devices must be contacted with the voltage source.

The frit current and/or the frit voltage should be adjusted or regulated using known circuit means in such a way that optimal cleaning and/or reduction of oxides, corrosion and contamination of the contacts is achieved. In the case of a measured higher contact resistance, the frit voltage on the contacts of the coupled participants should be increased in order to achieve a stronger frit effect. It is advisable that the previous frit flow is reset after appropriate contact cleaning.

Contact interruptions or excessive contact resistance values should be measured and recorded via the frit current using an analog-to-digital converter, 5 . The recorded data can be stored together with a subscriber identification in a retrievable manner in the subscriber and/or transmitted to a central computer, with the data representing a direct reference to emerging contact or coupling failures and/or being evaluated in this regard. After saving, the interruptions and/or the determined high contact resistance values on both neighboring participants can be compared with the contact resistance values of the participant in at least one other participant row using their identification numbers. If the contact resistance value of the contacts on the participant with the relevant identification number is found to be also high, this contact and thus the participant can be assessed as faulty and this can be signaled. In such a case, the contact must be replaced or made functional again using other suitable means (e.g. grinding). Provision can also be made for the measured and/or evaluated values to be shown on a display.

The method is particularly suitable for use in conjunction with mechanically and electrically coupled railway carriages for the transport of goods or people with or without at least one locomotive or in conjunction with a locomotive or model railway carriage consisting of several railcars. The contacts can be provided in the coupling part, whereby the coupling part of each wagon (participant) can be designed to be manually or automatically connectable to the next wagon. The contacts can therefore also be provided in a digital automatic coupling on the participants.

In terms of circuitry, each participant should have at least one voltage source with a resistor connected in series, which is connected to the respective input and/or output contacts on the data lines, 4 and 5 .

The proposed invention envisages using a voltage source with a series-connected resistor instead of the power source and power sink in each car. How out 4 The inventive design of the bidirectional power transmission to ensure a frit flow is shown in a self-explanatory manner. In the neighboring participants, which are connected to one another via a coupling, there is a voltage source with a series-connected resistor and is connected to the data lines in the respective participant. The data lines in both participants are connected to each other via contacts at the line ends.

This arrangement ensures that a frit current always flows over the data contacts, regardless of the train arrangement.

The frit current is calculated as: . $$I=\frac{2U_0}{2R}=\frac{U_0}{R}$$

The same circuit diagram is in 5 ( 5 ) played. This version only differs from 4 in that the current sensor of a frit current measuring device ADC is arranged in the series connection of the voltage source U with the resistor R. The measured frit current can be displayed or the transition resistance in the adjacent contacts (coupling) can be derived and displayed and/or can also be digitally assigned to an identification number of the participant in order to be evaluated. In addition to ensuring a permanent frit flow, which is independent of the car row, the arrangement according to the invention can also be used to monitor the contact quality and to adapt the frit flow adaptively to the contact conditions.

As in 5 shown, the frit flow is measured continuously. For this purpose, the current is continuously sampled using an AD converter. The sampling rate should be at least high enough to be able to detect short-term interruptions in the contacts. If one assumes that such short-term interruptions are in the range of 1ms, a sampling rate of approx. 2KHz is sufficient. To detect smaller interruptions, the sampling rate must be scaled accordingly. These measurements can be recorded in the car in conjunction with the identification numbers of the cars involved. In the event of increased contact interruptions, the two cars involved are clearly identified. If there is again an increase in contact interruptions involving one of the wagons in another pair of wagons, this is a clear indication of which wagon these contact problems originate from, so that it should be subject to an overhaul.

Another possible embodiment of the invention is to determine the contact quality by means of the current measurement. If the resistance measurement of the contacts results in a higher contact resistance, the frit current can be adjusted adaptively in order to achieve a stronger “burning free” of the contacts. This effect can also be taken into account in the contact statistics.

From the 6 , 7 and 8th It can be seen from the illustrations that the power transmissions when two participants are coupled together are completely independent of the line of cars, which ensures that the adjacent contacts are electrically cleaned, regardless of which line of cars the participants are arranged in.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 2444238 [0002]

Claims (12)

Method for reducing the transmission resistance on separable contacts on lines in bidirectional bus systems by fritting, wherein data from one participant is transmitted via the separable contacts at the line ends to another participant that can be disconnected and/or coupled, wherein, regardless of the interconnection of the contacts of the participants connected to one another, a frit voltage generated by a voltage source provided in a participant is always present at these contacts and a current flow of the frit current is ensured at the contacts at the line ends of a participant and wherein the voltage sources are designed and each loaded with a series resistance so that when the contacts are joined together, the voltages add up through a bidirectional power transmission. Procedure according to Claim 1 , characterized in that the frit current and/or the frit voltage are measured permanently or at intervals and the measured values are evaluated to determine the contact quality. Procedure according to Claim 1 or 2 , characterized in that the frit current and/or the frit voltage are adjusted or regulated and that optimal cleaning and/or reduction of the contacts from oxides, corrosion and contamination is achieved. Procedure according to Claim 3 characterized in that in the case of a measured higher contact resistance, the frit voltage on the contacts of the participants coupled to one another is increased in order to achieve a stronger frit effect. Procedure according to Claim 4 , characterized in that after appropriate contact cleaning, the previous frit flow is set again. Procedure according to Claim 2 or 3 , characterized in that contact interruptions are measured and recorded via the frit current using an analog-digital converter. Procedure according to Claim 6 , characterized in that the recorded data, together with a subscriber identification, is stored in the subscriber and/or transmitted to a central computer in a retrievable manner, the data representing a direct reference to emerging contact or coupling failures and/or being evaluated in this regard. Procedure according to Claim 7 , characterized in that high contact resistance values determined in the neighboring participants are compared under their identification number with the contact resistance values of the participant in at least one other row of participants and, if an equally high contact resistance value is determined, the contact on the participant with the relevant identification number is signaled as faulty. Method according to one of the preceding Claims 2 until 8th , characterized in that the measured and/or evaluated values are shown on a display. Method according to one of the preceding claims, characterized by use in conjunction with mechanically and electrically coupled railway carriages for the transport of goods or people with or without at least one locomotive or in conjunction with a locomotive or model railway carriage consisting of several railcars. Circuit arrangement according to Claim 10 combined with Claim 9 , characterized in that the contacts are provided in a digital automatic coupling on the participants. Circuit arrangement for carrying out the method according to one of the preceding claims, characterized in that at least one voltage source with a resistor connected in series is provided in each participant and that the voltage sources are each connected to the input and/or output side contacts on the data lines.

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