NL192541C - Method for setting the average value of the supply temperature of a heating liquid, which is heated intermittently in a heating system, and a control device for this. - Google Patents

Description

1 192541

The invention relates to a method for setting the average value of the supply temperature of a heating liquid, which is intermittently heated. is heated in a heating system, provided with a heating device with control device and one or more throttle valves for the heating liquid, wherein a desired value of the supply temperature is input to the control device on the basis of external influence factors, and wherein when heating the heating device from the cooled state, the heating liquid is heated from the full opening of the throttle valves to the desired value of the supply temperature by intermittently switching the heating device on and off.

The above method is known from German Offenlegungsschrift 33 45 949.

It is known from this "Offenlegungsschrift" that a central heating system is controlled, whereby the supply temperature of the heating liquid is determined by measuring the changes in the heat resistance using measuring sensors for the temperature of the flow rate. Under the heat resistance (Rth ) is known as a quotient of a temperature or temperature difference which determines the heat output and the amount of heat dQ / dt delivered to that space per unit of time, the latter often being referred to as heat flow Ith. Tra) / lth, in which Tv is the supply temperature and Tra is the room temperature (in ° C or K) The heat flow Ith mentioned refers to the amount of heat per unit time, as delivered by the heating elements or heating surfaces of the heating system. such a system is installed at the throttling sites, eg at the entrance of the heating line chams, thermostatic or throttle valves, which, however, are always fully opened at too low supply temperature and are substantially closed at too high supply temperature to achieve the desired room temperature, resulting in a high energy loss at the too high supply temperature, while at a low supply temperature the spaces not be heated adequately.

In the above known system, this is overcome by determining the load thereof in the "swung-in state" by the rate of change of the supply temperature. As stated, when much heating fluid is needed and the supply temperature increases only slowly, the thermostatic valves are opened too far and are not in the optimum control range. Therefore, the mean value of the supply temperature must therefore be increased. When starting up a heating system, e.g. In the morning or after return from holiday after termination of a savings resp. low temperature phase, the valves are in maximum opening condition, i.e. minimum throttle operation in which the heat resistance is minimal. It remains unchanged as long as the hypothermic or cold condition of the room persists. When the supply temperature gradually increases when heating and the desired temperature set manually in the thermostatic valves is approached, the said valves start to throttle, i.e. the heat resistance increases correspondingly. In order to determine the ideal supply temperature, the changes in the heat resistance are determined with the aid of measuring sensors of the temperature and the flow rate. However, this solution requires many measuring probes and control elements such as a flow maker and mixing valve, which entails relatively large investment costs.

The object of the invention is to overcome the above-mentioned problems. This object is thus achieved in a method of the type mentioned in the preamble, that in said heating of the heating device from a cooled state, from the temperature variation over time of the supply temperature (Tvt), parameters of a at the full opening of the throttle start function is determined, that at least one of these parameters, such as the heat capacity (Cm) of the heating fluid, is corrected to another fixed value associated with the throttled state of the throttles at reduced flow, resulting in a desired function of 50 the supply temperature, the supply temperature value of this desired function being compared each time with the measured supply temperature value to derive a modification value added to the supply temperature desired value (Ts).

In this method, when the heating system is started up, when the valves are fully opened, the load on the heating device or boiler will consequently be 100% since the maximum possible amount of heating liquid flows through the system. At this load, the supply temperature will only increase slowly since a large amount of liquid must be heated by a constant heating power. In this operating state, the start function 192541 2 is determined.

After a certain period of time, the mimts start to fan up and the thermostatic valves start to throttle the supply. When such normal operation is achieved, the flow temperature trend will be steeper with each start of the heater than in the initial maximum load condition. The variation of the heating of the supply temperature in this normal case in relation to the initially established maximum load curve is an expression of this, with which flow rate the system is operating and whether the supply temperature is correctly set. By pre-setting a desired function, which corresponds to an optimum heating curve and thus to the optimum flow rate and the approximation of the actual supply temperature curve to this desired function, an optimum flow rate and the correct average value of the supply temperature follow.

Advantageously, no additional measuring devices, such as a flow meter and mixing valve, are required, since temperature sensors for measuring the supply and return temperatures are present in the tile. Due to the automatic operation of the method, a more frequent resetting of the curve is possible. The heating system can thus be adapted to fluctuations determined by the time of year. The return temperature can also be determined without its own return temperature sensors, if a pump is supplied for each start-up of the heating system. Namely, if the pump supply lasts long enough, heating liquid with return temperature is introduced into the supply line. The temperature sensor arranged there determines the return temperature, which is used for the further calculation of the starter grater. desired function is stored.

In an advantageous embodiment of the method, the starter grater. desired function, with which the supply temperature changes, adjusted by the following auxiliary function:

25 Tv (t) = ^ (1 -ex ^^) + TR

Tv (t) = the preliminary temperature (° C), PK = the maximum heat output of the boiler (J.s1),

Cm = the heat capacity of the water flowing through (J. ° C'1.s'1), 30 t = the time (s), CK = the heat capacity of the boiler (J. ° C'1), and TR = the return temperature (° C).

This auxiliary function provides a sufficiently accurate approximation of the actual desired flow temperature. Since the heating will generally take place in the initial area of the e-function 35, the slope and the ratio of the increases between the start function and the desired function can be well determined. In the indicated auxiliary function, the parameters can be easily determined, especially since it is sufficient to determine the parameter combination Pk / Cm and CJCk each time.

Preferably, the parameters of the start function are determined by measuring the supply temperature at at least three times. This gives an adequate number of values to record the auxiliary function.

The desired function from the start function is advantageously determined by changing, in particular by decreasing the parameters Cm. This parameter is indicative of the rise in the curve representing the temperature variation.

Decreasing the parameter Cm makes the curve steeper. This means a low flow-45 amount. However, with a smaller flow rate, the supply temperature must be higher, so that an adequate amount of heat is transported through the heating system to the heating bodies.

An optimum setting, in which the thermostatic heating body valves are partly throttled, then follows when the parameter Cm in the desired function is approximately 20% to 40% smaller than the 50 parameter Cm of the start function. This means that a correspondingly smaller amount of the heating fluid flows through the heating system, so only about 60% to 80% of the maximum possible amount.

The start function is advantageously determined at each transition from low temperature night mode to day mode. This makes it possible to reset the desired function on a daily basis. The heating system can thus better monitor the switching on or off of several heating elements and / or fluctuations in the required heat determined by the time of the year.

Advantageously, a predetermined waiting time is included between determining the start function and determining the desired function. This waiting time is at least one heating cycle, preferably several. This ensures that the heating of the rooms is not delayed.

Advantageously, an input variable for an integrator is formed from the difference of the changed setpoint value of the supply temperature and actual value of the supply temperature, which switches the heating device on and off via a hysteresis switch. Such a hysteresis switch is known, for example, from DE 3,426,937: Preferably, the threshold values for the hysteresis switch are determined from the parameters of the desired function. This is an advantageous additional application of the parameters of the auxiliary function. The average value of the supply temperature can easily be adjusted to desired presets by varying the threshold values of the hysteresis switch.

The invention further relates to a control device for use in the method, comprising a presetting device, which generates a desired value signal of the supply temperature on the basis of external influence factors, an integrator to which the difference between the desired value signal of the supply temperature and an actual value signal of the supply temperature is supplied, a hysteresis switch which generates a control signal for switching the heating device when the integrator output signal exceeds or responds to a first predetermined value. falls below a second predetermined value, as known from German Offenlegungsschrift 3,345,949. According to the invention, this control device is characterized by a parameter identification device, which determines the parameters of the start function of the supply temperature, a calculation unit that calculates the desired function of the supply temperature and the difference between the value of the desired function and the respective measured value of the supply temperature forms an error signal generating unit, which, depending on the value of the desired function formed in the calculation unit and the difference determined, forms an error and, depending on this error, generates one of at least two temperature signal values, of which at least one or is positive or negative, and an adder, which adds the temperature signal value (A) at each shutdown of the heater, adding the output of the adder to the output of the biasing device to set the desired value of the supply temperature to modify.

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

The invention will be described below with reference to a preferred exemplary embodiment in connection with the drawing. The single figure therein schematically shows a heating system.

The heating system has, for example, three heating bodies or radiators, 13, 14, 15, which are supplied with hot water from a boiler 5 via a supply line 11. After the heating bodies 13, 14, 15 have flowed through, the water flows back to boiler 5 via a return pipe 12. The amount of water flow through each heating body 13,14,15 is determined by a thermostatic valve 16,17,18, the opening degree of which depends on the temperature of the room being heated. 40 If the temperature in this room is below the set desired temperature, the thermostat valve opens, if it is above it, the valve throttles the supply of hot water to the heating body.

The boiler 5 has as a heating device, for example a burner for oil, gas and the like, or an electric heating device and a storage container for water.

The supply temperature Tv and the return temperature TR are set in the supply line 11 and 11, respectively.

45 measured in return line 12 or in the boiler 5, for example with the aid of a thermometer 25 with connected measuring value converter, which converts a temperature value into electrical signals, which are fed to a further processing unit via lines 19, 20, 23. Although more accurate measured values for determining the supply and return temperature are obtained with two separate temperature sensors, it is also sufficient if only one temperature sensor (not shown) for the supply temperature is present. To determine the return temperature, the hot water is then circulated in the heating circuit for a certain time before the heating device is started in the boiler, so that the supply temperature is equal to the return temperature. This supply temperature is then stored and used as a constant return temperature for the next heating period.

55 A presetting device 1 is provided for controlling the boiler, ie for setting the average value of the supply temperature Tv, in which a set value Ts consists of a number of external influence factors, such as the outside temperature T and a curve slope H. of the supply temperature 192541 4. The quantity Ts, for example, can be formed according to a known formula, in which

Ts = H (22 - Toutside) + 22 + 2 / H

H here indicates a curve steepness, wherein a low H value leads to a relatively low average supply temperature, while a higher H value leads to a higher average value of the supply temperature. This setpoint is changed in a adding point 2 by a correction variable described later into a modified setpoint TF. After this modified setpoint TF, the actual value of the supply temperature Tv is subtracted at a difference-forming point 29 via a signal line 20. 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 fed to a hysteresis switch 4, which switches off the heating device of the boiler 5 when the output value of the integrator 3 exceeds a predetermined first value and switches the heating device of the boiler 5 on again when the output value of the integrator falls below a predetermined second value.

In the heating phase, i.e. when the heating device heats the water, the time-increasing supply temperature Tv can be described by the following auxiliary function, 20

Tv (t) = the supply temperature, PK = the maximum heat output of the boiler,

Cm = the heat capacity of the water flowing through, t = the time, 25 Ck = the heat capacity of the boiler and TR = the return temperature.

A parameter calculator 7 determines the supply temperature Tv at several different times, preferably at least three, and determines the parameters PK, Cm and Ck therefrom. In order to be able to unambiguously record the auxiliary function 30, it is generally sufficient to determine only the quotients PK / Cm and C / / Ck. As input variables, a time signal is supplied to the parameter calculating device 7, 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 calculator (7) only works during the initial heating of the heating liquid, for example during the transition from low temperature night mode to day mode. The parameters calculated in parameter calculator 7 accordingly define a start function.

The parameters are transferred to a calculation unit 6 where they can be modified to form a desired function. In a later heating cycle, a desired function is formed with the aid of the modified parameters, which indicates the desired course of time when the supply temperature Tv is heated. This calculated course of Tv is supplied via a signal line 28 to a deduction point 8, to which the measured value of the supply temperature Tv is also supplied via a signal line 27 which is in connection with the signal line 19. The difference between the calculated value of the TV and the measured value of TV is calculated at the deduction point 8. The difference is applied to an error signal generating unit 9. This error signal generating unit 9 detects an error from the difference calculated in the deduction point 8 and the values of the desired function supplied via a signal line 30. The error signal generating unit 9 outputs in its output one of three temperature signal values A depending on the detected error, according to the following rule: when the error is between -2% and + 2%, A = 0; when the amount of the error is greater than 2%, it is 50 amount A = 0.2 ° C; the sign of A is aligned with the sign of the error.

The output of the error generating unit 9 is added in an adder 10 to each stop of the boiler boiler 5. The output of the adder 10 is added to the addition point 2 at the output Ts of the biasing device 1. In the addition point 2, a changed or modified set value TF of the supply temperature is thus formed. In normal operation, this 55 modified supply temperature setpoint TF is used to form a difference, as described above, together with the supply temperature value Tv, which is then supplied to the integrator 3.

Claims (11)

A method for setting the average value of the supply temperature of a heating liquid, which is heated intermittently in a heating system comprising a heating device with control device and one or more throttle valves for the heating liquid, wherein a desired value of the supply temperature of the heating liquid is introduced to the control device on the basis of external influence factors, and wherein when the heating device is heated from a cooled state, the heating liquid is heated from the full opening of the 50 throttle valves to the desired value of the supply temperature by intermittently switching the heating device on and off, characterized in that in said heating of the heating device from a cooled state, from the temperature variation in time of the supply temperature (Tv (t), parameters of a start function valid at the full opening of the throttle valves It is established that at least one of these parameters, such as the heat capacity (Cm) of the heating fluid, is corrected to another fixed value associated with the throttled condition of the throttle valves at reduced flow, resulting in a desired function of the supply temperature, whereby the value of the supply temperature of this desired 192541 6 function is compared each time with the measured value of the supply temperature to derive a modification value which is added to the desired value (Ts) of the supply temperature. Method according to claim 1, characterized in that the starting resp. desired function, with which the flow temperature (Tv) changes, is approached by the following auxiliary function: Method according to claim 1 or 2, characterized in that the parameters of the start function are determined at least three times by measuring the flow temperature (Tv). Method according to claim 2 or 3, characterized in that the desired function from the start function is determined by changing the parameter Cm. Method according to claim 4, characterized in that the desired function is determined by decreasing the parameter Cm. 5 Tv (t) = £ * (1 - exp -% * -) + Tr “m '“' k Tv (t) = the flow temperature (° C), Pk = the maximum heat output of the boiler (Js * 1) , 5 192541 The heating system works as follows: when converting the system from low temperature night mode to normal day mode, it can be assumed that all thermostatic valves 16, 17, 18 are fully open and the maximum amount of water through the heating elements 13, 14 , 15 flows. The boiler 5 is started. Then the supply temperature Tv rises and is measured. On the basis of the measured curve, the constants PK, Cro, Ck of the auxiliary function of the heating system can be calculated in the parameter calculator 7, for example with the aid of a microprocessor. Since these constants are calculated at the start of the heating system, a starting function is obtained, i.e. the equation, which applies to the heating system at 100% throughput. A desired function can now be calculated on the basis of this start function, because, for example, a new value Cm is applied. For example, the new value can be 20% to 40%, in particular 30%, smaller than with the start function. The task of the regulator formed by the integrator 3, the hysteresis switch 4, the boiler 5, the return line 20 and the deduction point 8, is now to set an average value for the supply temperature such that the supply temperature Tv is modified by the desired curve. setpoint TF of the supply temperature. When the supply temperature Tv has the desired course, a flow is achieved, which corresponds to about 60% to 80%, preferably 70% of the maximum flow. In this flow-through, the thermostatic valves 16, 17, 18 of the heating bodies are in a partially throttled state, i.e. they can react to temperature changes in the room through stronger opening or closing and thus fulfill their control function. After each shutdown of the boiler, i.e. after each shutdown of the heating device, the measured temperature trend of the supply temperature Tv is compared at several points with the calculated desired function. Depending on the result of this comparison, the average value of the supply temperature is 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 adapt to the new preconditions. This adjustment of the average value to the loads is carried out as long as day mode is set. An additional advantage of the system can be seen in that a so-called alpha value can be determined from the calculated constants Cm, Ck and PK, which can be supplied to the hysteresis switch 4 via a signal line 31. To this end, this alpha value must determine or change the two predetermined threshold values, in the case of the grating. below which a boiler control signal for switching the heating device is generated. This avoids a somewhat uncertain manual setting of this value. The load on the system is therefore not estimated, but the actual heat consumed is determined. The supply temperature Tv is controlled in such a way that the thermostats can nevertheless always remain in their control range under varying external conditions. The outside temperature Tbujten and the curve slope H supplied to the presetting device 1 are also used further in daytime operation to modify the set value Ts depending on the external conditions. Thus, this input of the addition point 2 need not necessarily be constant during the day. 40 Method according to claim 5, characterized in that parameter Cm in the desired function is approximately 20% to 40% smaller than parameter Cm in the start function. Method according to one of claims 1 to 6, characterized in that the start function is determined at every transition from night mode to day mode. Method according to one of claims 1 to 7, characterized in that a predetermined waiting time is included between the determination of the start function and the determination of the desired function. Control device for applying the method according to any one of claims 1 to 8, provided with a presetting device (1) which, based on external influence factors (H, Tbu (s)), produces a desired value signal. (Tg) of the supply temperature generates an integrator (3), to which the difference between the desired value signal (Ts) of the supply temperature and an actual value signal (Tv) of the supply temperature is supplied, a hysteresis switch (4), which generates a control signal for switching the heating device (5) when the integrator output signal exceeds a first predetermined value or falls below a second predetermined value, characterized by a parameter identification device (7), which parameters (Pk / Cm, C „/ CJ of the supply temperature start function, determines a calculation unit (6, 8) that calculates the desired function of the supply temperature 35 and the difference between the value of the desired function and the respective measured value of the supply temperature forms an error signal generating unit (9) which, depending on the value of the desired function formed in the calculation unit (6, 8) and the difference determined, forms an error and depending on this error one of generates at least two temperature signal values (A), at least one of which is either positive or negative, and an adder (10) that adds the temperature signal value (A) at each shutdown 40 of the heater, the output of the adder (10) is added to the output signal of the biasing device (1) to modify the desired value signal (T1) of the supply temperature. Control device according to claim 9, wherein the error signal generating unit (9) is designed such that the three temperature signal values (A) correspond to a temperature change of -0.2 °, 0 ° and + 0.2 ° C 45. 10 Cm = the heat capacity of the water flowing through (J. ° C1.s'1), t = the time (t), CK = the heat capacity of the boiler (J. ° C'1), and TR = the return temperature (° C). Control device according to claim 9, wherein the calculating unit (6) is connected to the hysteresis switch (4) to supply an alpha value derived from the parameters (Cm, Ck) of the desired function to determine the threshold values of the hysteresis switch 1 sheet drawing