DE2908147A1 - ROOM UNIT WITH A PROGRAM AND SETPOINT VALUE AND A ROOM SENSOR OF A WEATHER-GUIDED FLOW TEMPERATURE CONTROLLER FOR A HEATING SYSTEM - Google Patents

Description

2908U7

& 6YBJ

LGZ LANDlS & GYR ZUG AG CH-6301 ZUG. Switzerland

Room unit with a program and setpoint generator and a room sensor a weather-compensated flow temperature controller for a heating system

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PA 2Ο64

Room unit with a program and setpoint generator as well as a Room sensor of a weather-compensated flow temperature controller for a heating system

The invention relates to a room device for a weathering vessel Led flow temperature controller for a heating system according to the preamble of claim 1.

There are weather-compensated flow temperature controls for Known heating systems whose program and setpoint generator is housed in a room unit arranged in the living room, while the actual control part is located on the boiler or in the immediate vicinity of it. It is also known in Room unit to also install a room sensor, which is electrically connected as a passive two-pole to a bridge branch of the controller part is switched.

To generate rapid heating, it is also known to adjust the flow temperature for a certain time at a higher value than the current outside temperature. In addition, it is known to use the To switch the room sensor so that with increasing setpoint deviation an increased temperature correction of the flow temperature corresponding to the current outside temperature takes place. Both measures can lead to undesired overshoots and are expensive.

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For a temperature reduction at night, for example, the heating flow temperature is switched to a lower value often, rather than completely shut as long as the heating _f to the natural cooling, the desired room temperature is reached.

The cooling curve of the room temperature then runs asymptotically against the value of the desired room temperature " whereby the initial tangent of the cooling curve often intersects the asymptote at a point that lies on the time axis outside the duration of the reduction, so that fuel is unnecessarily consumed in this period of time.

To transfer the control commands between the room unit and a multi-core cable was previously required for the controller section.

The invention is based on the object with little technical Effort and a small number of individual conductors make the connection between the room unit and the controller part of a To manage the heating system and, in addition to the commands for a time-controlled program sequence, also a blocking of the Heating system when switching to a lower room temperature and rapid heating when switching to a higher one To reach room temperature.

The invention is characterized in claim 1.

An exemplary embodiment of the invention is explained in more detail below with reference to the drawing:
3O

Show it; Fig. 1 is a basic diagram of a room device

and the associated controller for a heating system and

FIg. 2 is a circuit diagram of the room unit with more details than in Fig.

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The same reference numerals are used for the same parts in both figures. 1 is described first in the following, in which 1 denotes a room device which is connected by two connections 2 and 3 to a first and a second feed line 4 and 5 for feeding it. A feed voltage U is applied between the two feed lines 4 and 5, which feeds both the room unit 1 and a weather-compensated flow temperature controller - henceforth called controller 6. An output 7 of the controller 6 acts either on an actuator (not shown) or directly on a burner. The controller 6 and the room unit 1 are connected to one another by a single additional line 8, the voltage U _{1 of which can be changed} to a feed line 5 from the room unit 1 and, together with an outside sensor, influences the flow temperature to be maintained by the controller 6 as a command variable.

Furthermore, a transistor 9 and 10 is present between line 8 and lines 4 and 5. These are shown in FIG. 1 shown as two switches «They work together with amplifiers 28, 29, described below, of a temperature measuring device 24 as a threshold switch. These speak to a certain temperature difference between the actual and the setpoint of the room temperature and then cause a complete switch-off or a full switch-on of the heating output.

In Fig. 2, the room unit is shown with a broken line 1 indicated. A first voltage divider consists of the series circuit of two resistors 11 and 12 and a slide potentiometer 13 and is connected to feed lines 4 and 5. A program and setpoint generator 14 can consist of one Timer and switch elements that can be operated by hand. It influences the voltage drop across the potentiometer 13 and thus also changes the voltage distribution between a center point 15 of the voltage divider and the two Feed lines 4 and 5. The center point 15 is the connection point of resistors 11 and 12. At the midpoint 15

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two amplifiers 18, 19 are connected to their non-inverting inputs 16 and 17, respectively, while the inverting Input of each amplifier 18, 19 is connected to its output 2O and 22, respectively. The output 2O of the first amplifier 18 is connected to a resistor 21 to the line 8, while the output 22 of the second amplifier 19 via a Resistance 23 acts on the temperature measuring device 24 described below.

Any change in the voltage distribution at the center point 15 to the two feed lines 4 and 5 affects the two amplifiers 18, 19. The first amplifier 18 influences the variable voltage U 1 at its output 2O. and thus acts on the controller 6, while the second amplifier 19 supplies a comparison signal at its output 22 to the temperature measuring device 24, which is also fed by the voltage U on the feed lines 4 and 5.

Instead of the two amplifiers 18, 19, only one could be used, for example the amplifier 18. This is then to be connected to the midpoint 15 with its non-inverting input 16 as before, while its output is to be coupled both to the line 8 and to the temperature measuring device 24. To do this, output 2O must have both the resistor 21 as well as the resistor 23 be connected. The inverting input is also connected to the output 2O to be connected.

The use of two amplifiers 18, 19 according to FIG. 2 enables the clean separation of the signals to the controller 6 and to the temperature measuring device 24. Undesired mutual influences are excluded. The second amplifier can be used without additional effort when used as an amplifier 18, 19; 28, 29 operational amplifiers are used, four of which are built into a common housing and one is commercially available Form a module and two of them are used for the temperature measuring device 24 described below. The fol-

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The information given relates only to the execution according to of Fig. 2.

The temperature measuring device 24 comprises two further voltage dividers connected to the feed lines 4 and 5 as well the two further amplifiers 28, 29, of which the first voltage divider is formed from two series-connected resistors 25 and 26, the connection point 27 on the one hand with the Resistor 23 connected to the output 22 of the amplifier 19 and on the other hand, each with a first input of the third and fourth amplifiers 28 and 29, respectively.

The second voltage divider of the temperature measuring device 24 consists of a one connected to the feed line 4 on the one hand Room sensor 3O and two resistors 31 and 32 connected in series with this. A connection point 33 between the Room sensor 3O and the resistor 31 forms a second input to the third amplifier 28, while a connection point 34 is connected between the resistors 31 and 32 to the second input of the fourth amplifier 29. The second connection of resistor 32 is connected to feed line 5.

Each output 35 and 36 of the amplifier 28 and 29 is connected via a resistor 37 each to a base of the transistors 9, 10. The collector-emitter path of the transistors 9, 1O is connected between the line 8 and one of the feed lines 4 and 5, respectively. A further resistor 38 is provided between the base and the emitter of both transistors 9 and 10. A resistor 39 each connects the second inputs of the third and fourth amplifiers 28 and 29 to their outputs 35 and 36, respectively. The amplifiers 28, 29 thus act together with the transistors 9 and 10 as threshold value switches.

A manual switch 4O is also arranged in the lead to the base of the transistor 9.

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The setup described works as follows:

The first voltage divider with resistors 11, 12 and 13 is designed so that with one on the program and setpoint generator 14 setpoint of e.g. 20 ° C and not switched through Transistors 9, 10, the output 20 of the amplifier 18 on the line 8 generates a voltage IL that is half as large how the supply voltage U is. In this state, the controller 6 acts purely weather-compensated and regulates according to the set Heating curve, enter the flow temperature corresponding to the current outside temperature. Correctly adapted to the building The heating curve then results in the desired temperature of 20 ° C in the living room.

The temperature measuring device 24 continuously compares the measured values of the room sensor 3O with the setpoint signal output by the second amplifier 19. Is the measured value compared to the Setpoint by more than about 3 ° C too high or too low, then one of the two outputs 35 or 36 is the corresponding Transistor 9 or 10 switched through, whereas the transistors 9, 1O when the temperature-actual and approximate coincidence Setpoints are locked.

As soon as one of the transistors 9, 10 turns on, this sets the line 8 almost to the potential of the corresponding feed line 4 or 5, which means a strong detuning of the controller 6. This either fully stops the heat supply of the heater or switch it to full power. In the event of a temperature drop when switching the programmer to the night program the heat generation will therefore remain switched off until the desired room temperature is reached again, like this is described below. In the case of switching to a higher temperature level, for example when switching back on the day program in the morning, heating takes place with a flow temperature that is approximately that on the boiler controller of the Heating system can reach the set temperature. This means that rapid heating results, but only if the

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Manual switch 4O is closed and transistor 9 has the potential the line 8 has brought approximately the potential of the feed line 4.

To prevent the control loop from oscillating, the transistors 9, 10 and the associated amplifier 28 and 29 formed threshold switches each have a switching difference of about 1 ° C. As soon as the room temperature approaches the setpoint both during cooling and heating up to 2 ° C has the corresponding transistor 9, 1O blocked again and the voltage U .. corresponding to the instantaneous setpoint appears again on line 8. The flow temperature is adjusted again according to the current outside temperature. This avoids any overshooting of the room temperature.

Because the setpoint signals are relative quantities to the supply voltage U are designed, it is possible to select a large change in the voltage IL per 1 ° C setpoint adjustment and the value transmitted on the line 8 in a resistor network corresponding to the resistors 23, 25, 26 of the temperature measuring device in controller 6 to weaken the sensitivity of the sensor again. This makes the transmission relative insensitive to interspersed interference voltages and fluctuations in the supply voltage.

The room unit described allows with only one additional Line 8 the transmission of normal setpoint commands as well as special commands for rapid heating and on Cooling down.

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SUMMARY (see Fig. 1)

All setting elements for individual requirements for the temperature curve in occupied rooms are included with a temperature sensor in the room unit (1). This is connected to the controller (6) of the heating system via a few lines (4, 5j 8). The room unit (1) is supplied with a voltage (U) by the same feed lines (4, 5} as the controller (6). Setpoint commands to the controller (6) are transmitted by the additional line (8) Feed line (5) can be changed as a command variable from the room unit (1). With U ^ = —5— regulated , the controller (6) purely weather-dependent according to its outside sensor. Threshold value switches (9, 1O) speak from certain differences between the actual and A program and setpoint encoder influences the voltage (ü \,) via at least one amplifier and a temperature measuring device to form the difference between the setpoint and actual value. As a threshold value switch (9 _S 1O), two transistors, each with a further amplifier, are used for the temperature measuring device.

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Claims (6)

2308147 PATENT CLAIMS 1. Room unit with a program and setpoint generator and a room sensor of a weather-compensated flow temperature controller for a heating system, which is arranged separately from the room unit, characterized in that the room unit (1) is supplied with a voltage (ü) from the same feed lines (4, 5) is how the controller (6) and is only connected to the controller (6) by an additional line (8), the voltage (U ₁ ) of which can be changed to one of the feed lines (4, 5) from the room unit (1) and as a reference variable together with an outside sensor influences the flow temperature to be maintained by the controller (6) and that threshold switches (9, 28; 1O, 29) a temperature measuring device (24) are present between the additional line (8) and the feed lines (4, 5) for the purpose of completely switching off or switching on the heating power. 2. Room unit according to claim 1, characterized in that a first voltage divider, consisting of the series connection of at least two resistors (11s 12, 13), is connected to the feed lines (4, 5), in which the voltage drop across ad & r resistors ( 13) can be influenced as a guide variable by the program and setpoint generator (14) to change the voltage distribution between a center point (15) of the voltage divider and the feed lines (4, 5). 3. Room device according to claim 2, characterized in that an amplifier (18) is connected to its input (16) at the center point (15) and to its output (2O) on the one hand is coupled to the additional line (δ) and on the other hand a comparison signal to one also from the voltage (U) on the feed lines (4 _r 5) fed temperature measuring device (24) delivers » 030035/0558 ' ^{/ m} PA 2O64 2908U7 4. Room unit according to claim 2, characterized in that at the center point (15) of the first voltage divider (11, 12, 13) two amplifiers (18, 19} with their non-inverting inputs (16, 17} are connected, while the inverting input each amplifier (18, 19} connected to its output (2O and 22, respectively}, and the output (2O) of the first amplifier (18} is connected with a resistor (21} to the additional line (8} _t while the output ( 22} of the second amplifier (19} alone supplies the comparison signal via a resistor (23} to the temperature measuring device (24}. 5. Room device according to claim 3 or 4, characterized in that that the temperature measuring device (24} has two amplifiers (28, 29}, the outputs (35 and 36) of which each have a base each of a transistor (9, 1O) are connected and the corresponding transistor when the room temperature is too low or too high (9, 1O) switch through their collector-emitter paths between the additional line 8 and one of the feed lines (4, 5) are connected, each amplifier (28, 29) together with its transistor (9, 1O) a threshold switch forms, and that as an amplifier (18, 19; 28, 29) operational amplifier serve, four of which are built into a common housing. 6. Room unit according to claim 2, characterized in that with one on the program and setpoint generator (14) preselected setpoint of approximately 2O ° C and not through-connected transistors (9, 1O) the output (2O) of the amplifier (18) at the additional Line (8) _{generates a voltage (U 1} ) which is half as large as the supply voltage (U), and that the transistors (9, 10) block when the temperature setpoint and actual value roughly match. 030035/0558 "'' PA 2O64