DE4023439A1 - Room temperature regulator - has valve-controlled heater and temp. sensor with heating resistor influencing valve position connected to supply via converter - Google Patents

Abstract

A circuit for regulating temp. in a room contg. at least one heater with a valve regulating the flow of heating medium and a temp. sensor contains an electrical heating resistor (3,7) connected to the power supply and influencing the valve position. A converter (8) connected between the power supply and the resistorr is connected to a control circuit (9) generating a control voltage. The output of the heating resistor is proportional to the percentage height of the control voltage. USE/ADVANTAGE - Room temp. control circuit is developed to enable desired room temp. reductions at any time.

Description

The invention relates to a circuit arrangement to regulate the temperature in a room in which at least one heater with a supply of a heating medium regulating valve, a temperature sensor and one connected to a power source, the Influencing the position of the valve serving electrical heating resistor are arranged (DE-OS 35 36 311).

"Valve" in the sense of the invention can be a valve on Radiator of a hot water heating system. It can but also a heating flap, a slide or trade an air damper. The valve should be on everyone Case affect the heat input for a room in which a temperature sensor, for example a temperature-dependent switch with associated, the Temperature reduction serving heating resistor arranged is.

The described in DE-OS 35 36 311 Circuit arrangement has two heating resistors. The one, in the technical language as "thermal Feedback resistor "designated heating resistor that the set on a thermostat Temperature reached faster and adhered to more precisely becomes. Without such a heating resistor, it would be too  heating room first become too warm because of the requested amount of heat only up to the bimetal of the Thermostat must reach until it can react. The Heating resistor is therefore switched on when the Thermostat heat is required. He's fooling the thermostat a room temperature before that actually doesn't is reached. The thermostat can therefore supply heat prevent the room from overheating entry. This part of the known circuit arrangement works as described Room temperature controller. The second heating resistor of this Circuit arrangement serves as the lowering resistance of the Night reduction. When switching on the lowering resistor and the associated heating is transferred to the thermostat or whose bimetal is 5 ° C higher, for example Pretended temperature when in the affected room actually prevails. The one to be controlled by the thermostat The temperature in this room will be around 5 ° C lowered. The lowering resistance can be done by hand or by means of a timer can be switched on and off. The measure the temperature drop is determined by the resistance value of the Lowering resistance determined. If a bigger one or smaller value for lowering the temperature is desired the lowering resistor must be replaced.

The invention is based on the object further described circuit arrangement so that any lowering of the to be regulated at any time Temperature in a room is possible.

According to the invention, this object is achieved by

• - That between the power source and the heating resistor a converter is switched on at the input the power source and at its output the Heating resistor are connected and
• - That the converter also with a control circuit connected between 0 and 100% lying control signal in the form of an electrical  Provides tension through which the of the Input source input to the converter according to the percentage of the Control signal in a proportional, the Output variable supplied heating resistor implemented becomes.

With this circuit arrangement can easily the temperature in each room of a building using a valve, a temperature sensor and the converter is equipped at any level at any time be managed. Through the translator - remote controlled - only the amount of over the Heating resistor flowing current and thus the Heating output of the same set. The heating power can be adjusted between 0 and 100% by the converter depending on the size of the control circuit delivered voltage.

If the heating resistor is on with a thermostat coupled lowering resistance, the maximum Heating output of the same, for example, around 10 ° C lead to increased temperature at the thermostat, what a Lowering the temperature level to be regulated in the room 10 ° C would result. If the temperature level just around 5 ° C should be reduced, then that of the Control circuit delivered voltage reduced by 50%. By the heating resistor then flows - proportional to percentage change in control signal - a 50% current reduced compared to the maximum current, so only half the stream. It is accordingly in the thermostat only a temperature of 5 ° C is generated. By Adjustment of the voltage of the control circuit to any percentage values can thus be simple at any time Adjusted the temperature to be controlled in the room will. The thermostat then controls the temperature in the each room on a given by the translator more or less high level.  

In principle, this also applies if the heating resistor is coupled to a valve that one has temperature-dependent expansion body, which of the Heating resistor is affected and the position of the Working piston of the valve controls.

Further advantageous embodiments of the invention go from the subclaims.

Embodiments of the subject matter of the invention are in shown the drawings.

Show it:

Fig. 1 shows a schematic representation of a circuit arrangement according to the invention.

Fig. 2 is an addition to the circuit arrangement.

FIG. 3 shows a circuit arrangement modified compared to FIG. 1.

FIGS. 4 and 5 shows a detail of the circuit in two different embodiments.

Letters L and N, for example, are intended to denote the 220 V AC network. Instead of the L / N network, any other suitable voltage or current source can also be used. Connected to the network L / N is a thermostat 1 installed in a room of a building with a switch 2 which is preferably designed as a bimetal switch. In the illustrated embodiment, a heating resistor 3 is located in the circuit of the thermostat 1 , through which a valve 4 can be influenced. The valve 4 can have a temperature-dependent expansion body, through which the working piston 5 of the valve 4 can be adjusted in the direction of the double arrow 6 .

In the immediate vicinity of the thermostat 1 or the switch 2 there is a lowering resistor 7 which serves to lower the temperature and is connected via a converter 8 to the network L / N representing the current source for the converter 8 . The heat generated by the lowering resistor 7 therefore directly influences the thermostat 1 or its switch 2 . A control circuit 9 is connected to the converter 8 and supplies a control signal in the form of an electrical voltage. The height of the current flowing through the lowering resistor 7 can be adjusted by the converter 9 .

The circuit arrangement according to FIG. 1 works as follows:

As long as no current flows through the lowering resistor 7 , the temperature in the room in question is regulated by the thermostat 1 to the temperature set thereon. If the supply of the heating medium to the heating device equipped with the valve 4 is to be throttled or stopped, then the switch 2 closes. Characterized flows through the heating resistor 3 stream, which is then heated and the valve 4 moves the piston 5 by means of the strain inducing element into the closed position of the valve. 4 In this way, for example, a temperature of 20 ° C can be controlled in a room.

It may now be desirable that the temperature in the room be lower at certain times. Such times are, for example, the night or in schools in the afternoons or in hotels where there is no room occupied. If, for example, the lowering resistor 7 generates a temperature of 5 ° C, the thermostat 1, as a room temperature controller, regulates the temperature in the room to 15 ° C when it is set to 20 ° C. Nothing needs to be adjusted on the thermostat 1 and in particular on its control mechanism. The converter 8 influencing the lowering resistor 7 can be operated remotely via a correspondingly long line, for example from a control center.

The current flowing to the drop resistor 7 can be changed between 0 and 100% by the converter 8 . This is - in particular remotely controlled - effected by the control circuit 9 , which supplies an electrical voltage as a control signal which can be adjusted as a constant voltage between 0 and 100%, which corresponds to 0 to 10 V, for example.

The maximum reduction in temperature by the circuit arrangement should be 10 ° C., for example. The maximum output variable of the converter 8 is then set so that the lowering resistor 7 is heated to 10 ° C. by the corresponding current. If the thermostat 1 is set to 20 ° C, it regulates the temperature in the room to 10 ° C when the temperature reduction is fully switched on. This can be particularly interesting for the night or for times when a room is not being used. At other times the temperature drop should be less. For example, it should only be 4 ° C, i.e. 40% of the maximum value. In this case, the control signal of the control circuit is changed to 60%, so that the output variable of the converter 8 , that is to say the current flowing to the drop resistor 7 , is limited to 60%. The temperature in the room is then regulated to 16 ° C (20-4) if the thermostat 1 is further set to 20 ° C.

Since the converter 8 supplies a proportional output variable (current) in accordance with the percentage of the control signal coming from the control circuit 9 , any temperature between 0 and 100% of the maximum temperature at the lowering resistor 7 can be easily generated and without intervention in the control mechanism Lowering the room temperature.

If the times of the temperature reduction, also with temporarily different temperature levels, are known, corresponding control commands can be stored in a computer 10 , which then automatically adjusts the control circuit 9 .

In this way, the temperatures in all rooms or even only in a part of the rooms of a large building can be individually reduced to a desired level by a computer 10 at any time. In the rooms in the circuit according to FIG. 1, only one thermostat 1 with lowering resistor 7 must be present, which is controlled by a converter 8 . Each of these converters 8 is connected to its own control circuit 9 , which in turn are all connected to the computer 10 .

Basically the same mode of operation as described for FIG. 1 results in the circuit arrangement according to FIG. 3. Instead of the thermostat 1 , a simple temperature sensor 11 is provided here, which is connected to the control circuit 9 . The output of the converter 8 is now connected to the heating resistor 3 of the valve 1 , so that the position of the working piston 5 of the same is directly influenced by the converter 8 .

The converter 8 is a device for power control, for example an electronic circuit breaker. It can also be an integrated circuit for period group control. Such a device is controlled by the power-free control circuit 9 , by means of whose control signal a more or less high power is "let through" by the converter 8 . The powerless operation of the control circuit 9 has the advantage that it can be connected to the converter 8 via a line of almost any length. This is particularly advantageous if the circuit arrangement is used in a large system with a control center, from which the temperature in a large number of rooms can be regulated according to FIG. 2.

In the variant of the circuit arrangement according to FIG. 3, the lines 12 , with which the converters 8 are connected to the control circuits 9 , can also be used to connect the temperature sensors 11 , as is shown in broken lines in FIG. 3. The signal from the temperature sensor 11 is then passed through the converter 8 .

Two of the possible embodiments of the converter 8 are shown in a schematic representation in FIGS. 4 and 5:

The converter 8 according to FIG. 4 to be equipped with a clock generator 13, the duty ratio is changeable by the control signal of the control circuit 9.. In this case, the level of the current flowing to the lowering resistor 7 or to the heating resistor 3 is changed over time by the maximum possible current depending on the clock ratio flowing over the respective resistor in more or less long periods of time.

The converter 8, according to Fig. 5 with an electronic circuit, for example a direction indicated by a transistor transistor circuit 14, to be equipped, the power transmission is changed by the control signal of the control circuit 9.. Instead of the transistor circuit, a thyristor circuit, in particular a triac, can also be used.

Claims (10)

1. A circuit arrangement for regulating the temperature in a room in which at least one heating device with a valve controlling the supply of a heating medium, a temperature sensor and an electrical heating resistor connected to a power source and influencing the position of the valve are arranged, characterized in that

• - That between the current source and the heating resistor ( 3 , 7 ), a converter ( 8 ) is turned on, at the input of the current source and at the output of the heating resistor ( 3 , 7 ) are connected and
• - That the converter ( 8 ) is also connected to a control circuit ( 9 ) which supplies a control signal between 0 and 100% in the form of an electrical voltage through which the input variable supplied by the current source of the converter ( 8 ) in accordance with the percentage The level of the control signal is converted into a proportional output variable supplied to the heating resistor ( 3 , 7 ).

2. Circuit arrangement according to claim 1, characterized in

• - That in the room, the temperature of which is controlled, a thermostat ( 1 ) with a temperature-lowering electrical lowering resistor ( 7 ) is arranged as a heating resistor as a temperature sensor and
• - That the lowering resistor ( 7 ) is connected to the output of the converter ( 8 ).

3. Circuit arrangement according to claim 1, characterized in that

• - That on the equipped with a temperature-dependent expansion body valve ( 4 ) of the heating device, a heating resistor ( 3 ) is arranged, which is connected to the output of the converter ( 8 ) and
• - That in the room, the temperature of which is regulated, a temperature sensor ( 11 ) connected to the control circuit ( 9 ) is arranged.

4. Circuit arrangement according to one of claims 1 to 3, characterized in that the converter ( 8 ) comprises a clock generator by which the input variable is converted into a clocked output variable in accordance with the percentage size of the control signal. 5. Circuit arrangement according to one of claims 1 to 3, characterized in that the converter ( 8 ) comprises an electronic circuit whose current permeability is variable depending on the level of the control signal. 6. Circuit arrangement according to claim 1 or 5, characterized in that the converter ( 8 ) comprises a transistor circuit. 7. Circuit arrangement according to claim 1 or 5, characterized in that the converter ( 8 ) comprises a thyristor circuit. 8. Circuit arrangement according to one of claims 1 to 7, characterized in that the control circuit ( 9 ) is connected to a computer. 9. Circuit arrangement according to one of claims 1 to 8, characterized in that the temperature sensor ( 11 ) is connected via the same lines to the control circuit ( 9 ) as the converter ( 8 ) and the heating resistors ( 3,7 ). 10. Circuit arrangement according to one of claims 1 to 9, characterized in that two or more control circuits ( 9 ) are connected to a computer, which are each individually adjustable for regulating the temperature in different rooms of a building and in that each control circuit converter ( 8 ) located in another room is connected.