SE450431B - TRANSFER DEVICE FOR DATA TRANSFER BETWEEN A CONTROL CENTER AND MULTIPLE CONTROLS OR CONTROLS BY A DATA BUS - Google Patents

Description

450 431 N The invention thus aims to offer a possible immediately locate such an error while maintaining of the operability of all the remaining regulators na.

The features of the invention are apparent from claim 1.

An embodiment of the invention is described below in detail. more with reference to the drawing.

In the only figure, the reference numeral 1 denotes a control center of a building, as with a two-wire data bus 2 as a transmission device are connected to several regulators The figure shows two regulators 3a and 3b with two different ones connection possibilities. Dashed lines 4 indicate that regulators 3 in any sequence can be connected to data bus 2. Each controller 3 is assigned a specific poison, for example a device belonging to the building within areas of heating and ventilation as well as sanitary or climatic facilities. The controller 3 and the control center 1 occupy it for its control and regulation tasks necessary the energy from it local network, which in the drawing figure is indicated by two conclusions 5. _ Each controller 3 forms with one setting element, one setpoint sensor and possibly at least one sensor one independent rules resp. control circuit, whose control or control parameters can be stored in a microprocessor belonging to the controller 3 processor 6. Each controller 3 further includes one between them both conductors of the data bus 2 connected to the receiving and transmitting device 7 resp. 8, which are schematically shown in the figure.

The receiving device 7 forms a voltage divider with by means of two resistors 9 and 10, to whose outlet point between the two resistors 9, 10 are an input 11 of the microprocessor 6 connected.

The transmission device 8 of each regulator 3 consists of one low-ohm series connection of an overcurrent fuse 12, a current switch 13 and an impedance 14. As switch 13, one serves 450 451 transistor, the base of which is controlled by an output 24 of the microprocessor 6. As an overcurrent fuse 12, a fuse fuse.

Like the controller 3, the control center 1 comprises a microcontroller processor 15 and a similar receiving and transmitting device ning 7 resp.8 as the regulator3. The receiving device '7 is also connected to an input 16 of the microprocessor 15, and the transistor serving as switch 13 is also controlled by microprocessor 15 over an output 25. Furthermore, the control central l in addition to two voltage sources of different power for only voltage supply of the data bus 2 one of the pulse telegrams affected coupling device. In the described example is formed the two voltage sources of a voltage source 17 and one with this series-connected load resistor 18. These sources would however, can also consist of two alternatively connectable, independent sources of voltage. As a coupling device serves a switch 19, which is actuated by the microprocessor 15, which is indicated by a dashed line 20. The switch 19 transmits bridges the load resistor 18 and thus provides the opportunity to choice between the two voltage sources of different power for of the data bus 2.

The microprocessor 15 monitors the voltage profile of the data the bus 2 either directly over the entrance 16 of the receiving device 7 or has two connections for this purpose. 21 connected to the data bus 2.

The input of pulse telegrams takes place by pulse-through switching of the switch 13. Corresponding transmission device R then acts on the data bus 2 as a low ohmic load. During a telegram transmission and during transmission pauses supply voltage source data 17 data bus 2 with reduced power. Ie. tax The resistance resistor 18 is then connected in front of the voltage source 17. I the transmission breaks and during the transmission times, during which the data bus 2 conductors are not low-impedance loaded, ie. when current the switches 13 of all transmitting devices 8 are blocked, the voltage source 17 over the load resistor 18 emits another the digital state of the telegram transmission corresponding 450 431 normal voltage UH to the data bus 2. In the example this amounts to to at least 20 V. When switching on any of the the switches 13, i.e. when loading the voltage source 17 over the load resistor 18 with a transmitting device 8, falls the voltage on the data bus 2 to one against the digital stand L corresponding to low voltage UL. In doing so, the internal the state of the voltage source 17 together with the load resistance stand 18 so selected that even when sending it furthest away located the regulator 3, in whose circuit then also a genome the relatively high conduction resistance of the data bus 2 is developed voltage drop occurs, the voltage UL at the connection the terminals of the data bus to the control center l decrease to max 6 V. The one in each controller 3 and also in the control center itself 1 when transmitting through the overcurrent fuse 12 the current can not trigger this. f In order to reduce the flank steepness of the telegram pulse it is appropriate that the impedance 14 be trained as choke coil, as shown at control center 1 and in the controller 3a. However, instead of the impedance 14, for example, also a secondary winding of a transformer 22 may be used, such as is displayed in controller 3b. There is a primary winding 23 of the trans- the formator 22 connected to it serving as a switch 13 transistor in such a way that the current pulse in the secondary the winding when connecting the transistor induces a voltage ningi.the primary winding 23, which generates a current acting against the base current supplying the transistor. The thus future feedback prevents the rapid rise of the current in the transmitting device 8. In the example described is for this purpose the primary winding 23 is connected between the output 24 and the base of the transistor. Other connections are also possible.

In relation to the choke coil, this device has the the part that the flank steepness is no longer dependent on the spread of the voltage drop across the transistor.

The transmission operation is led at the normal course from control center 1, the transmission pulses being formed in the same way both in the control center 1 and in the controllers 3. -_ ~. ...__.__ fl .i, ....... .......__..___....... _, J 7 450 431 of the control devices 7 both in the control center 1 and the voltage changes occurring in the regulators 3 at the entrances 16 resp. ll happen everywhere in the same way.

A first start command from the control center 1 is received by all controllers 3. Then the address is given by it the first controller in, for example, 8 bit word length. The first the controller thus remains the only controller in the receiving mode, while the other controllers turn off. Then it happens the transmission of commands, which are stored by the microprocessor 6.

After a short pause, the called controller 3 transmits its own address and then his reply, which may be a confirmation, but can also be a measured value. After a long break has passed calls the control center 1 through a new start command, which again received by all controllers 3, the other controller.

In the same way, one controller is called after the other end until after the last controller 3 the first controller returns again it's turn.

If one of the switches 13 due to a fault is continuously honestly remains in the lead state and thus blocks the whole telegram transmission, so in the control center 1 the voltage source 17 with increased power is switched on for a disturbance location. lization. For this purpose, the microprocessor 15 monitors i the described example of its connections 21 continuously the error-free course of the telegram transmission, i.e. temporal the course of the voltage on the data bus 2. The microprocessor 19 in the event of a disturbance, the operation of the switch 19, which bridge then bridges the load resistance 18. It now to the voltage source data l7 with higher power connected the data bus 2 sounds in the transmitting device 7 of the controller 3, the switch of which 13 is continuously conductive, a current flow greater than the tripping current of its overcurrent fuse 12.

As soon as the current flow is interrupted by tripping of the the power fuse 12 causes the microprocessor 15 to switch the sensor 19 is reopened and thus the data bus 2 is fed back to the voltage source 17 across the load resistor 18. Thus can the data exchange between the control center 1 and the remaining ones 450 431 the regulators 3 are taken up again.

In the example described, up to a maximum of 129 lators are called. This gives at a transfer rate of 1024 Baud a transmission time of, for example, 0.5 seconds per regula ~ and thus at maximum capacity utilization a repetitive was 64 seconds.

Program data for all controllers 3 is without possibility at a loss stored in the microprocessor 15 by the control center 1 and is continuously transferred to the individual regulators 3.

The storage can take place in the regulators 3 themselves in such a way that this data in the event of a power failure is lost. Mentioned data must then, when the voltage returns, be rebuilt from control center l.

The possibility of disconnecting an individual controller 3, whose switch 13 in the transmission circuit is constantly conducting due to a disturbance, makes it possible to build a functional safe and inexpensive facility, which also in the event of failure of the transmission device 8 by a single regulator 3 can continue working.

Claims (8)

450 45 PATENT REQUIREMENTS l. Transmission device for data transmission between a control center and Elera control or monitoring devices, in and for control, control or monitoring of devices in the area of heating and ventilation as well as sanitary or air conditioning systems, including a control center with the controllers resp. the control devices connecting the data bus, whereby both the control center and also the controllers resp. the control devices each comprise a transmitting and a receiving device for transmitting pulse telegrams between the control center and the calculators, respectively. the control devices and vice versa, it is known that the transmission device (8) in the controllers resp. the control devices (3) each consist of a low-ohm series connection connected between the two data bus lines (2) by an overcurrent fuse (l2L a switch (lä) and an impedance (14), and that the control center (1) in addition to two voltage sources (l7; 17, 18 ) of different power for feeding the data bus (2) has a switching device (19) actuated by the pulse telegrams for switching the supply of the data bus from one voltage source to the other in the event of disturbed data transmission, in order to trigger the transmission of the disturbed transmission device (8). power fuse (12). Transmission device according to Claim 1, characterized in that the switch (13) in each transmitting device (8) consists of a transistor controlled by a microprocessor (6; low) each. Transmission device according to Claim 2, characterized in that the impedance (14) connected in series with the switch (13) is designed as a choke coil. Transmission device according to claim 2, characterized in that the impedance (14) connected in series with the switch (13) consists of the secondary winding of a 450 431 transformer (22L whose primary winding (23) is connected to the base of it as a switch (13) serving the transistor and an output (24, 25) of the microprocessor (6 and 15, respectively), and that the current pulse in the secondary winding when the transistor is switched on induces a voltage in the primary winding (23), which generates a current which acts against the the transistor controlling the base current. Transmission device according to one of the preceding claims, characterized in that the voltage source (17) with the lower power feeds the data bus (2) during the transmission pauses and during the telegram transmission and that the voltage source (17) with the higher power can be switched on for interference localization. . Transmission device according to Claim 5, characterized in that the voltage source (17) with the lower power at the switched-off switch (13) emits a normal voltage (UH) corresponding to the higher binary state (H) to the data bus (2), which voltage when switching on one of the switches (13) drops to a low voltage (ULL) corresponding to the lower binary state (L) Transmission device according to claim 5, characterized in that the data bus (2) connected to the voltage source (17) with the higher power in the transmission device (8) with a continuously conducting switch (13) allows a current which is larger to flow. than the tripping current for the overcurrent fuse (12). Transmission device according to Claim 7, characterized in that the overcurrent fuse (12) consists of a fuse.