SE500088C2 - Method for setting the mean temperature of the feed temperature of a heating medium and apparatus therefor - Google Patents

Abstract

PURPOSE: To set average supply temperature such that a total average valve passage speed of a heating medium becomes optimum, by determining a start function where supply temperature is changed owing to heating, determining a desired function by changing parameters of the start function, and changing the supply temperature until a heating process fits to the desired function. CONSTITUTION: A heating system comprises three heat radiators 13, 14, 15, and hot water from a boiler 5 flows through the heat radiators 13, 14, 15 and is returned to the boiler 5. When room temperature is lower than set one, thermostatic valves 16, 17, 18 of the heat radiators are opened, but in the opposite case supply of hot water is drawn. Preset means 1 is provided for setting an average value of the supply temperature TV whereby a desired supply temperature value Ts formed. The desired value is changed by a correction amount at an addition point 2. An integrator 3 integrates this signal with time, and a hysteresis switch 4 turns off the boiler 5 when an output value of the integrator 3 exceeds a predetermined first value while turning on the same 5 when the same is lower than a second value.

Description

_20 LD C) (f) CJ From DE-OS 33 45 949 a device for controlling a central heating system is known, which tries to determine this ideal feed temperature by measuring the change of the heat resistance by means of temperature and flow rate meters. However, due to the many measuring sensors, this solution requires relatively large investment costs. The object of the present invention is now to provide an automatically operating control method for setting the average value of the feed temperature to such a value that an optimal total flow rate for the heating medium is achieved. The object is now achieved in that when heating the plant from the cooled state, from the temporal temperature course of the feed temperature, parameters for a starting function valid for full opening of the throttle points are determined, that by changing at least one of these parameters a setpoint function is calculated. in the event of a reduced throughput for the heat carrier, that the setpoint function is used as the basis for the desired setpoint heating function and that the feed temperature setpoint changes until the course of the heating in each heating phase is adapted to the setpoint function.

Thus, according to the invention, the load of the heating system in the "self-oscillating state" comes through the degree of change of the feed temperature. If a lot of heating medium is then necessary, the supply temperature thus rises only slowly, the radiator valves being so wide open that they are not in the optimum control range. Therefore, the average value of the feed temperature must then also be increased. When starting a heating system, it can in principle be assumed that the thermostatic valves are completely open. The load on the boiler consequently amounts to 100%, since the maximum possible amount of heating medium flows through the system. In such a load case, the feed temperature will only rise when a large amount of heating medium must be heated. In this operating state, it is determined to rise slowly, through a constant heating effect. read the start function. After a certain time, the rooms are heated and _; the thermostatic valves start to choke. Once such normal operation has been achieved, the course of the feed temperature at each start of the heater will be steeper than at the initial maximum load situation. The course of the heating of the feed temperature is in this normal case in relation to the originally established maximum load curve an expression of the degree of flow with which the system operates and whether the feed temperature is set correctly. By evaluating a setpoint function, which corresponds to an optimal heating process and thus the optimal flow rate, and by approximating the actual feed temperature profile to this setpoint function, an optimal flow rate and the correct feed temperature average are obtained.

It is advantageous then that no further measuring means are needed, since as a rule there is a temperature sensor for measuring the feed temperature and one for the return temperature. Due to the automatically operating procedure, a more frequent readjustment of the curve is possible. The heating system can therefore be adapted to seasonal fluctuations. The return temperature can also be determined without its own return temperature sensor when a pumping process takes place before each start of the heating device. When the pumping process has been going on long enough, the heating medium with return temperature will be fed into the supply line. The temperature sensor arranged there thus emits the return temperature which is fed for further calculation of the start and set function.

In a preferred embodiment of the method, the start or setpoint function, with the changed feed temperature, can be specified by the following auxiliary function: P -C - t K m E- (1 expc) + T Tv (t) = mk 'as G88 whereby TV (t ) is the feed temperature, PK is the maximum heating power of the boiler, Cm is the heat capacity of flowing water, t is the time, L: Ck is the heat capacity of the boiler and TR is the return temperature.

This auxiliary function provides sufficiently close approximation to the truly desired course of the feed temperature. Since the heating usually takes place at the beginning of the e-function, the degree of ascent and the relationship between the ascent between start function and setpoint function can be well determined. In the specified auxiliary function, the parameters can be easily determined, especially as it is sufficient to determine each parameter combination FK / Cm and Cm / Ck.

Preferably, the parameters of the start function are determined by measuring the feed temperature at at least three times.

This gives a sufficient number of values to determine the auxiliary function.

Advantageously, the set function is determined by the start function by change, in particular by reducing the parameter Cm. This parameter sets the standard for the rise of the temperature course at the return curve.

By reducing the parameter Cm, the curve will become steeper.

This means a smaller amount of flow. With a smaller flow rate, however, the feed temperature must be raised, in order to thereby transport a sufficient amount of heat from the heating device to the radiators.

An optimal setting, in which the thermostatic radiator valves are partially throttled, is then obtained when the parameter Cm in the setpoint function is approximately 20% to 40% less than the parameter Cm for the start function. This means that a correspondingly smaller amount of heating medium flows through the heating system, i.e. only 60% -0 to 80% of the maximum possible amount.

Advantageously, the start function is determined at each transition from nsttsankningarirt to asgarift. Thus, a daily uninstallation of the setpoint function is possible. The heating system can thus better follow the switching on or off of several radiators and / or seasonal fluctuations in the heat demand.

Preferably, a predetermined dead time is arranged between the determination of the starting function and the determination of the set function.

This dead time amounts to at least one heating cycle, preferably several. This ensures that the heating of the rooms does not delay.

Advantageously, from the difference between the changed supply temperature setpoint and the supply temperature value, an input variable is formed for an integrator, which switches the heating device on and off via a hysterical connection. Such a hysteresis coupling is known, for example, from DE-PS 34 26 937. This procedure allows a simple regulation.

Preferably, the threshold value for the hysteresis coupling is determined from the parameters of the setpoint function. This is an advantageous additional use of the parameters of the help function. The average value for the feed temperature can easily be adapted to the desired evaluation by varying the threshold value for the hysterics connection.

CJ CJ CU C? CO m According to the invention, there is further provided a coupling for carrying out the method, with an evaluation device which, due to external influencing factors, generates a feed temperature setpoint signal, an integrator which is supplied with the difference between a modified feed temperature setpoint signal and a feed temperature hysterical value signal. - a boiler control signal for switching the heating device, when the integrator's output signal exceeds a first determined value and falls below a second determined value, a parameter identification device which determines the parameters of the start function, a calculation unit which calculates the set function and the difference between for the heating medium, an error signal generating unit which, depending on the setpoint function formed in the calculation unit and the determined difference, forms an error, and depending on this error one produces one of three temperature signal values one of which is at least positive and one negative and a summing unit, which adds the temperature signal value at each shut-off of the boiler, the output of the summing unit being added to the output of the evaluation device.

Advantageously, the three temperature signal values correspond to a temperature change of -0.2 °, 0 ° and + 0.2 ° C. The degree of change of the changed feed temperature setpoint is thus relatively small. The heating system can easily follow the change.

The invention will be described in the following in a preferred embodiment with reference to the accompanying drawing figure. This drawing figure schematically shows a heating system.

The heating system has, for example, three radiators 13, 14, 15, which are fed via a supply line 11 with hot water from a boiler 5. After flowing through the radiators 13, 14, the water flows back to the boiler via a return line 12. The amount of water flow through each radiator 13, 14, 15 500 088 is determined by separate valves 16, 17, 18. These valves 16, 17, 18 are designed as ordinary thermostatic valves, ie their degree of opening is determined by the temperature of the associated rooms to which the radiator refers. heat. If the temperature in this room is below the set setpoint temperature, the thermostatic radiator valve opens, if it is above, the valve restricts the inflow of hot water to the radiator.

The boiler usually has a heating device, for example a burner for oil, gas or the like or an electric heating device and a storage tank for water.

The feed temperature TV and the return temperature TR are measured at the feed line 11 and the return line 12 or in the boiler S, for example by means of a thermometer 25 with a connected measured value converter, which converts the temperature value into an electrical signal which is supplied via the lines 19, 20 and 23, respectively. . Although with the two different temperature sensing bodies a more accurate measurement value for determining the supply and return temperature can be obtained, it is sufficient if only one (not shown) temperature sensor is present for sensing the feed temperature. To determine the return temperature, before each start of the heating system in the boiler, a heating medium is circulated for a certain period of time in the circulation process, so that the supply temperature is equal to the return temperature. This feed temperature is then fed to the processor and used for the next heating period as a constant rotor temperature.

For the control of the boiler, i.e. for the setting of the average value of the supply temperature TV, an evaluation device 1 is arranged, in which a supply temperature setpoint TS is formed from several external influencing factors such as the outer temperature Tuta and a curve rise H. The size TS can be formed according to the known form. TS = H (22 - Tute) + 22 + 2 / H 500 one Uoo '8 H indicates a curve rise, whereby at a lower H-value a relatively lower mean value feed temperature is achieved, while at higher H-value a higher feed temperature mean value is achieved . This setpoint is changed in a summation point 2 by a later described correction quantity to a modified setpoint TF. From this modified setpoint Tp, the actual value of the feed temperature Tv is subtracted over a signal line 20 at a difference formation point 29. This difference is applied to the input of an integrator 3. The integrator 3 integrates this signal over time. The output of the integrator 3 is supplied to a hysteresis coupling 4, which disconnects the heating device of the boiler 5 when the initial value of the integrator 3 exceeds a certain first value and switches on the heating device of the boiler when the initial value of the integrator falls below a certain second value.

In the heating phase, ie when the heating device heats the water, the time course for heating the feed temperature TV can be described with the following auxiliary function, where TV (t) is the feed temperature, PK is the maximum heating effect of the boiler, Cm is the flow rate of the water, is the heating capacity of the boiler and l5 500 (588 TR is the return temperature.

A parameter identification device 7 determines at several different times, preferably at least three, the feed temperature Tv and determines the parameters PK, Cm and Ck therefrom. In order to unambiguously determine the function, it is usually sufficient even to determine only the ratios PK / Cm and Cm / Ck. As input quantities, a parameter identification device 7 is supplied with a time signal, the supply temperature TV via a signal line 26, which is connected to the signal line 19, and the return temperature TR via a signal line 24 which is connected to the signal line 23. The parameter identification device 7 operates only during the first heating of the heating. eg in the transition from night setback operation to day operation. The parameters determined in the parameter identification device 7 then define a start function.

The parameters are then transferred to a calculation unit 6, where they can be modified to form a setpoint function. In a later heating cycle, a setpoint function is formed with the help of the modified parameter, which indicates the temporal setpoint process when heating the feed temperature TV. This calculated course of TV is supplied via a signal line 28 to a differential formation point 8, which is supplied with the value of the feed temperature TV via a signal line 27, which is connected to the signal line 19. At the difference formation point 8, the difference between the calculated value TV and the measured the value of TV. This difference is applied to an error signal generating unit 9. This error signal generating unit 9 determines an error from the difference calculated at the differential formation point 8 and the value of the setpoint function supplied via a signal unit 30.

The error signal generating unit 9 emits at its output depending on determined errors one of three temperature signal values A and thereby according to the following rule: When the error is between -2% and +22, A == 0; when the error is more than 2%, the magnitude pa A is = 0.2 ° C; the sign of A thus follows the sign of the error. The output of the 500 USS Fault Generating Unit 9 is added to a summing unit 10 at each stop of the boiler 5 heater. The output of the summation unit 10 is added at the summation point 2 to the output TS of the evaluation device 1. At the summation point 2, a changed or modified setpoint TF is formed for the feed temperature. During normal operation, this modified setpoint Tp for the feed temperature is used to, as described above, together with the actual value TV of the feed temperature, form a difference, which is then supplied to the integrator 3.

The heating system works as follows: When switching the system from night immersion operation to normal day operation, it can be assumed that all radiator thermostats 16, 17, 18 are fully open and that the maximum amount of water flows through the radiators 13, 14, 15. Boiler 5 is started. Thereafter, the feed temperature of the TV rises and is measured. In accordance with the measured curve, in the parameter identification device 7, for example by means of a microprocessor, the constants PK, Cm, Ck of the auxiliary function of the heating system can be calculated. Since these constants are calculated at the start of the heating system, a start function is thus obtained, ie the equation that applies to the heating system at 100% throughput.

With the help of this start function, you can now calculate a pre-function, in that, for example, a new value for Cm is inserted. The new value can, for example, be 20% to 40%, especially 30%, less than in the start function. The purpose of the regulator formed by the integrator 3, the hysteresis coupling 4, the boiler S, the return line 20 and the difference forming point 26 is now to set an average value for the supply temperature so that the supply temperature Tv contains the modified setpoint T given by the desired setpoint curve; for the feed temperature. When the feed temperature TV 11 - 500 G88 has the desired course, a throughput corresponding to approximately 501 to 80%, preferably 70%, of the maximum throughput is achieved. In this flow, the radiator thermostat valves 18, 17, 18 are in a partially throttled state, ie they can react to the temperature change in the room by being opened more or throttled more and thus fulfill their control function.

After each stop of the boiler, ie after each switch-off of the heating device, the measured temperature course of the feed temperature TV will be compared with the calculated setpoint function at several points. Depending on the result of this comparison, the average value of the feed temperature will be kept constant, increased by 0.2 ° C or decreased by -0.2 ° C. This change is so small that the system has sufficient time to adjust to its new boundary conditions. This adjustment of the mean value to the load is exercised as long as day operation is set.

A further advantage of the system consists in that from the calculated constants Cm, Ck and PK a so-called alpha value can be determined, which is applied to the hysteresis coupling 4 via a signal line 31.

This alpha value serves to determine the two predetermined setpoints or to change them, at the excess of which a control signal for the boiler for switching the heating device is generated. This eliminates a slightly more uncertain manual setting of these values.

The system's load will thus not only be protected, but they emit the mainly consumed heat demand. The supply temperature TV is controlled so that the radiator thermostats can always remain within the control range in the event of changing external conditions. 500 088 12 The outer temperature Tute and the curve rise H, which is fed to the evaluation device, are further used during daytime operation to modify the setpoint T5 depending on the external conditions.

This input for the summation point 2 must therefore not necessarily be constant during the day.

Claims (12)

500 058 13 EAIENTKRAV A method of setting the average value of the feed temperature to a heating medium heated by a heating device intermittently in a heating system having at least one adjustable throttling point for the heating medium, a feed temperature setpoint being determined due to external influencing factors at full heating and heating medium. of the throttle points is heated to the feed temperature setpoint, characterized in that when the system is heated from the cooled state, from the feed temperature ETv (t) J temporal temperature course parameters for a start function valid for full opening of the throttle points (16-18) are determined, that by changing at least one of these parameters (Cm) a setpoint function is calculated, which applies at a reduced throughput for the heat carrier, that the setpoint function is used as the desired setpoint heating function and that the feed temperature setpoint (Ty) is changed until the heating for each heating phase adapted to the set function. Method according to claim 1, characterized in that the start or setpoint function, with which the feed temperature (TV) is changed, is adapted to the following auxiliary function: -C - t Ck rqän (1-exp rvza) = B where Tv (t) is feed temperature, PK is the maximum heating power of the boiler, Cm is the heat capacity of the water flowing through, t is the time, LH CD cm CO 14 Ck is the heat capacity of the boiler and TR is the return temperature. 3. A method according to claim 2 C 8 C c n a of claim 1 or 2, in that the parameter of the start function is determined by measuring the feed temperature (TV) at at least three times. Method according to Claim 2 or 3, characterized in that the setpoint function is determined from the start function by changing the parameter Cm. of that Method according to claim 4, characterized in that the setpoint function is determined by reducing the parameter Cm. Method according to claim S, characterized in that the parameter Cm in the setpoint function is approximately 20% to 40% less than the parameter Cm in the start function. Method according to one of Claims 1 to 6, characterized in that the start function is determined at each transition from night setback operation to day operation. Method according to one of Claims 1 to 7, characterized in that a certain dead time is arranged between the determination of the starting function and the determination of the set-off function. 9. A method according to any one of claims 1-8, characterized in that from the difference between the changed feed temperature setpoint (TF) and the annual value (TV) of the feed temperature an input quantity for integrator is formed, which over a hysteresis connection ( 4) OCU UIROPPIBI UPP 'HEATING DEVICE <5). 5130 G88 15 Method according to Claim 9, characterized in that the setpoint for the hysteresis coupling (4) is determined from the parameters of the set function for the function. \ Coupling device for carrying out the method according to one of Claims 1 to 10, characterized by an evaluation device (1) which, due to external influencing factors A (H, Tu¿a), generates a setpoint signal (TS) for feed temperature. an integrator (3), which is supplied with the difference between a modified feed temperature setpoint signal (Tp) and a feed temperature value signal (TV), a hysteresis switch (4) which generates a control signal for the boiler for switching the heating device (5) when the integrator exits the first signal determined value or falls below a second predetermined value, a parameter identification device (7) which determines the parameters of the start function (PK / Cm, Cm / Ck), a calculation unit (6,8), which calculates the set function and forms the difference between the set function and the measured heating - the course of the heating medium, an error signal generating unit (9), which, depending on the formation formed in the calculation unit (6,8) the function and the determined difference form an error and depending on this error generates one of at least two temperature signal values (A), of which at least one is positive and one is negative, and a summation unit (10), which adds the temperature signal value (A) at each shut-off of the boiler, the output of the summation unit <<10) being added to the output of the evaluation device <1). to modify the setpoint signal (TS) for the feed temperature. Coupling device according to Claim 11, characterized in that the three temperature signal values (A) correspond to a temperature change of -0.2 °, 0 ° and + 0.2 ° C.