Patent Application
20050188237
The present invention relates to a bus system for controlling a component of a printing machine with a plurality of slaves as bus components and a clock generator to output a first clock signal and a second clock signal to the plurality of slaves. The present invention also relates to a corresponding method for operating a bus system.
A printing system comprises a plurality of printing rollers, which are preferably individually activated. To this end a drive regulator is required for each printing cylinder or each printing roller. The drive regulators are activated by means of a clocked bus system.
The failure of a printing system can be an enormous economic problem for an enterprise. Therefore where possible more than one synchronization clock master is used in the clocked bus system for activating the drive regulators. Drive controllers or regulators are used as the synchronization clock masters. If necessary, e.g. if a synchronization clock master fails, it is possible to switch between masters. Such a switching operation is effected for example using a polling list within the synchronization group.
It is also known from the publication EP 0 816 963 A2 that it is possible to switch between the clock masters using a priority list. This priority list can also run cyclically, so that the global synchronization clock is generated by all the drive controllers one after the other for a specific time interval.
However switching between synchronization clock masters requires a specific minimum period. In some circumstances the printing system fails during this switching period.
The object of the present invention is therefore to minimize the downtime of a printing system when switching to another clock master.
According to the invention this object is achieved by a bus system for controlling a component of a printing machine with a plurality of slaves as bus components and a clock generator to output a first clock signal and a second clock signal to the plurality of slaves, at least one of the slaves having a selection device for selecting the first or second clock signal as the synchronization clock to be used.
Also according to the invention a method is provided for operating a bus system for controlling a component of a printing machine by outputting a first clock signal and a second clock signal to a plurality of slaves, which represent bus components, the first and second clock signals being output simultaneously and at least one of the plurality of slaves selecting the first or second clock signal present as the synchronization clock to be used.
Simultaneous transmission of the at least two clock signals or clocks allows floating and immediate switching. For a printing machine this means that switching is not associated with the threat of paper tearing or production stopping. This is extremely important in the case of time-critical newspaper printing machines, as there is frequently a time interval of only three to four hours between the start of printing when the editing process is completed and delivery of the newspapers. The invention is expected to be of enormous benefit for such areas of application.
The selection device of a slave can be configured to make an independent selection solely based on internal information. It is therefore possible for the slave to make a clock selection for example based on a time criterion. The first clock signal to arrive could therefore be accepted as the synchronization clock, while clock signals arriving later are ignored.
Alternatively the bus system according to the invention can have a control component for transmitting a clock control signal, so that the selection by the selection device of the at least one slave can be implemented on the basis of the clock control signal for one of the clock signals. This means that selection of the clock control signals can be controlled centrally by the slave and is easier to trace.
In a preferred embodiment two data lines are linked to each of the plurality of slaves of the bus system, said data lines being connected together in each slave and being connected outside each slave in such a manner that a closed communication ring is formed. This type of connection allows individual drive regulators to be exchanged during operation, i.e. when communication is ongoing. The individual drive regulators of the bus system then receive data or clock signals in each instance via half the ring, so that failure of the printing system can be prevented.
The clock generator can comprise at least two separate clock masters, one of which is configured to emit the first clock signal and another to emit the second clock signal. This embodiment has the advantage that the clock masters are physically separate and it is therefore highly unlikely that both systems will fail. The individual clock masters can thereby each be integrated in a drive regulator.
Alternatively the clock generator can however also comprise a single clock master to output both the first and the second clock signals. This can reduce system costs and the clock signal of the clock master is split into two clock signals using two lines and routed to the individual drive regulators or slaves in a physically separate fashion.
The bus system can be configured such that a bus sub-system with the same features as the bus system described above is linked to at least one of the slaves. It is therefore possible for a plurality of bus systems with a topology according to the invention to be connected together by a higher order bus system of the same or similar structure. It is then possible specifically to connect a plurality of communication rings together by means of a higher order communication ring.
A preferred application of the bus system according to the invention results for printing machines or their components in the printing industry, as mentioned above. A component of a printing machine here refers particularly to a printing unit or folding unit.
The present invention is described in more detail below with reference to the accompanying drawings, in which:
The exemplary embodiment described in more detail below represents a preferred embodiment of the present invention.
The printing system 1 symbolized in
The drive regulators 3 are connected in a ring structure. This means that each drive regulator 3 is connected to its two immediate neighbors. Therefore each drive regulator 3 has two connecting lines, which are designed for bi-directional data communication.
The clock signals generated by the drive controller 4, the control system 5 or a plurality of drive regulators 3 or slaves are routed via the connecting lines to the individual drive regulators 3 using two separate routes. The first route takes one direction round the communication ring and the second route takes the counter direction. To ensure the ring structure, the two connections of each drive regulator 3 are coupled together internally so that a clock signal present at one connection of the drive regulator 3 is looped through to the other connection.
Two clock signals are therefore present at each drive regulator, which can be used as the synchronization clock.
Two of the drive regulators 3 are preferably declared to be clock masters. Both send their own synchronization clock simultaneously to the other connected drive regulators 3. Each slave or drive regulator 3 can then decide itself which clock it observes. The decision is made such that the clock identified as the first is deemed to be the synchronization clock.
In an alternative embodiment, each drive regulator 3 or slave receives a signal from a higher order control system, e.g. the drive controller 4 or the control system 5, which specifies the clock to be used for synchronization.
If one of the two clock signals present fails, all the slaves switch internally to the other clock signal or the other clock master. Depending on the embodiment, this switch is based solely on the fact that a second clock signal is no longer present or it is based on the control signal from the higher-order unit.
The communication ring shown in the Figure now has the advantage that any drive regulator 3 can be removed from the bus system, i.e. the communication ring, without interrupting the synchronization clock. This is because each drive regulator 3 receives a clock signal from two sides, i.e. via the two halves of the ring, and if half fails, a clock signal is always still present at the respective drive regulator 3 via the other side of the ring. This results in redundancy via the closed communication ring through the second communication channel. The redundancy thereby results at a physical level from the two connections at each drive regulator 3.
As already stated, a drive regulator 3 can be removed or withdrawn from the system, if it is defective for example. With the communication topology shown in the Figure, two immediately adjacent drive regulators 3 can also be removed from the system without any adverse effect for the other drive regulators. Two drive regulators that are apart from each other could however not be withdrawn from the system, as the drive regulators in between would not then receive the clock.
Each drive regulator switches to the respective clock or evaluates the two clock signals present in an independent fashion. Therefore the drive regulators in the printing system can be synchronized with different clocks during operation.
Each of the printing systems and each folding unit has a ring-shaped bus system. Each of these individual bus systems shown in
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2004 004 843.6 | Jan 2004 | DE | national |
