DE3112330A1 - Method of controlling a room-heating installation - Google Patents

Abstract

The invention relates to a method of controlling a room-heating installation with a heating device, a number of heat transmitters, a circulating pump, an expansion vessel and valves which are connected in a flow circuit and of which the valves to the heat transmitters are opened and closed depending upon temperature sensors. Known methods of this type have in particular the disadvantage that rooms are fully heated even when not or only seldom used for a relatively long period of the day. This problem is not even solved by thermostatic radiator valves. The invention proposes, in the case of a method of the abovementioned type, that both the surface of each heat transmitter and each room are assigned temperature sensors which are scanned at an adjustable frequency by a recording device and cause a control device to open the valve in the course of the respective heat transmitter in the event of a deviation of the actual temperature value of the heat transmitter surface and of the room temperature from their desired temperature values and to close the valve when the desired temperature value of the heat transmitter surface is reached. With this, a cost-reducing room temperature control depending on external influences acting individually on each room is guaranteed with relatively low heating device capacity but with utilisation of a high efficiency of the heating device.

Description

Description;

The invention relates to a method for regulating a space heating system with a heating device, several heat exchangers, a circulation pump, an expansion tank as well as valves which are connected in a flow circuit and of which the Valves to the heat exchangers open and depending on temperature sensors getting closed.

Conventional systems that have become known through prior public use of this type have an outside temperature-controlled regulation of the temperature of the supply water on, which is made by a multi-way mixing valve, which on the one hand with the flow line and on the other hand with one or more bypass lines to Return line is in communication. The boiler output is linked with DIN 4701 according to the total transmission losses of the sum of all rooms that be heated by such a heating system, designed. With such a In the process, relatively large boiler outputs are just as inevitable as the fact that rooms are fully heated even if they are used for a long time Period of a time of day are not used or only rarely used.

In order to achieve an individual regulation one has the advance of the Heat exchanger assigned to thermostatic radiator valves. This thermostatic However, radiator valves usually only have a rough scale, for example from 0 - 10 and their adjustability remains the estimation of the left to the respective user. This is particularly important when the outside temperature changes an increased amount of heat consumed by the heat exchanger concerned only can then be avoided if, with increasing outside temperatures, the Radiator valve for less water flow and when outside temperatures drop is caused to a higher water flow rate. However, this is also the case an objective directed towards impossibility, since such handling only remains with an estimate. This thermostatic valve is disadvantageous but also that they are usually arranged in the vicinity of the respective heat exchanger and thus ultimately on the immediate ambient temperature of this heat exchanger, however, do not react to the more important room temperature.

On the basis of this prior art, the object of the invention is to be found based on creating a method of the type mentioned above, with which a cost-reducing room temperature control depending on the individual room external influences with a relatively low heater output can be guaranteed by taking advantage of a high efficiency of the heating device can.

This object is achieved in that both the Surface of every heat exchanger as well as every room temperature sensor be assigned, which in an adjustable frequency by a registration device are scanned and in the event of a deviation from the actual temperature value of the heat transfer surface and the room temperature from its setpoint temperature values to a control device Opening the valve in the flow of the relevant heat exchanger and when it is reached the target temperature value of the heat exchanger surface for streaking the valve caused. Through this process, the surface of every heat exchanger and the room temperature can be set individually for each room to be heated Target temperature iUr room and heat exchanger compared. Will both target temperatures minus a hysteresis set in the control device The heating requirement for this room is reported to the control device. On the other hand, if the surface temperature of the heat exchanger only falls below the hysteresis, However, given the preselected room temperature, the latter is the primary control criterion used and no heating requirement from the registration device of the control device reported for this room.

The new control procedure stands out from other, previously known ones Control method in that there is each room depending on the heat storage capacity the heat exchanger and the heat storage capacity of the surrounding building walls of the room in question as well as the direct external influences, such as solar radiation through the windows and weather influences, e.g. through greater wind loads on the North and west side or in winter on the east side, individually registered, the Notifies the regulator device and this then leads to an opening of the valve in the flow of the heat exchanger concerned.

The heating device is only as large as the hourly heat demand of the room with the greatest transmission losses, on the other hand, the heat exchangers larger than conventionally designed. This increases the heating power of the heater lowered, however, the overall efficiency of the heating device increased, which consists of a Oil, gas, coke or coal-fired boilers, from a heat pump or a storage tank can exist.

To increase the heat storage capacity, each heat exchanger approx. 40% to 70% larger than a conventionally calculated heat exchanger designed. Advantageous becomes the heat exchanger of every room designed so large that with a detection of 10 rooms by the registration and The controller means that the heating-up time is only 10% of the cooling-down time of the room in question by 1 K.

On the one hand, this results in rapid heating of the room in question ensured and on the other hand a greater heat storage capacity given that in turn, the cooling time of the room is extended.

According to a particularly advantageous development of the invention the controller is assigned an automatic timer through which certain Rooms are adjustable in terms of their heating depending on the time of day Get priority over other rooms. A specific Priority of different rooms programmed at certain, adjustable times of the day will. Furthermore, for example, the heating of a bathroom can be dependent on can be preselected from the time of day as follows: From 6:00 a.m. to 8:00 a.m. at 220C, from 8:00 a.m. to 6:00 p.m. on 190C, from 6:00 p.m. to 8:00 p.m. on 220C and 0 from 8 p.m. to 6 a.m. at 19 C.

If desired, this priority can also be interrupted manually or be set contrary to the preprogrammed priority.

With the control method described above, a time-dependent heating of the center of gravity carried out individually and automatically in different room zones of a building without affecting the subjective feeling of warmth single Left to people. Because of this permanent redistribution of heat within a building according to optimal criteria one could use the new procedure also referred to as "spatial heat quantity swing" whose motion vector on the one hand from external atmospheric influences such as solar radiation, wind, cold snaps, Sunny and dark sides of a building, heat storage capacity of every room and of each radiator, and on the other hand of a preselectable priority of individual ones Rooms is determined depending on the time of day. To this regulatory process to give a quick flexibility, is advantageously the frequency of the registration device, with which the actual temperature values of the heat exchanger surface on the one hand and the room on the other hand, about 0.1 Hz. This means that the recording device a comparison of the actual temperature values with the target temperature values every 10 seconds of the heat exchanger surface on the one hand and space on the other The controller device can react accordingly quickly to deviations. If from the registration device searches for a room as not having priority the next room to be heated with priority and if there is no heating requirement for this is registered, it only then gives the controller a signal for heating of the space not scanned with priority.

To the registration device and thus the control device at do not address the essential ventilation of a room in a misleading way to let, if a room is strongly ventilated, e.g. by opening a Window, the control device, e.g. by means of one on the lower edge of the window frame arranged circuit breaker, switched off, but with poor ventilation, e.g. by tilting the window, it remains switched on.

The control method described above is particularly suitable for conventional radiators and convectors.

However, it is taking into account the greater inertia in radiant heating Can be used with conventional pipe registers.

The control method according to the invention is illustrated below with reference to FIG described in several working diagrams. The figures show: FIG. 1 a room temperature-time diagram for a room to illustrate its cooling time on the one hand and its heating time on the other hand.

Fig. 2 shows the heat transfer of the heat exchangers in different Evacuation depending on the time of day within a 24-hour cycle.

3 shows the dependence of the radiator surface temperature of a The room's atmospheric outside temperature and the change in room temperature based on 21 0C using the example of a convector.

In Fig. 1, the time t is on the abscissa in minutes and on the The ordinate plotted the room temperature VR in OC.

0 Assuming a room temperature VR of 22 C at the point A at time t = 0 cools the room in the form of the solid, continuous line A-B in the form of an exponential function from a room temperature of 21 ° C. This cooling time around 1 0K from A to B is 25 minutes in the present case. This is followed by the Heating curve from B to C, which is advantageous only 10% of the cooling time and thus 2.5 minutes.

From point C, which, in terms of room temperature, is 22 0C is identical to point A, closes again the cooling time from C to D. The point D is again equivalent to the point B. This solid line The course of the curve from A-B-C-D should vary depending on the individual heat storage capacity the building walls and the radiator concerned, for example at an outside temperature of -1O0C.

At lower outside temperatures, for example -8 0C, -60C, -40C and -20C results in the group of curves shown in dashed lines.

In FIG. 2, the time of one day is beginning on the abscissa plotted at 4:00 a.m., where the ordinate goes to the amount of heat Q in watts identifies. If you now include the time-of-day dependence of the in this diagram Heat transfer Q from one or more heat exchangers in a room just enter this space, the drawn straight lines 10 - 16 result with the individual Discontinuities. These curves should indicate the following spaces in detail: 10 = vestibule 11 = bathroom 12 = parents' bedroom 13 = first children's room 14 = second children's room 15 = utility room 16 = living room For example in the control device for the bathroom 11 only in the times of day between 6 and 8:00 a.m. and 6:00 p.m. and 8:00 p.m. a larger amount of heat is required stored, however, a reduction is made in the other times of the day. The same applies, for example, to the utility room according to curve 15, which is only during working hours between 6:00 p.m. and 8:00 p.m. to a higher one Temperature level is raised with a correspondingly higher heat quantity requirement.

If you add the heat quantities of the individual curves 10 to 16, the result is In connection with the right abscissa 17, there is a total transfer of heat according to curve 18. A conventional control method is applied to curve 18 opposite, the curve 19 results. The hatched area 20 between these the two curves 18 and 19 give the amount of heat saved with the new control method.

In Fig. 3, the abscissa is the atmospheric outside temperature applied in ° C from + 200C to 200C. The surface temperature is on the ordinate applied in OC of a heat exchanger from + 200C to 11000. At the intersection of the abscissa and ordinate is another ordinate running approximately below 0 45 plotted, which is the change in room temperature in ° C based on a room temperature of 210 reproduces. If one enters the course of the surface temperature in this coordinate system of a heat exchanger depending on the outside temperature results in the progressive course according to curve 21. The course of this curve 21 is primarily depending on the heat storage capacity of the heat exchanger used on the one hand and the mean heat demand and thus the mean heat transfer coefficient k des the room concerned on the other hand. Accordingly, the curve 21 can be worse Storage capacity and poorer heat transfer coefficient k steeper and better Heat storage capacity and lower heat transfer coefficient k run flatter. Relates the room temperature to 21 ° C, results in connection with the ordinate 22 under Taking into account the change in room temperature, the family of curves 23 to 27.

When the room temperature drops by 1K from point E on curve 21 the point F of curve 26, the heating time for the heat exchanger in question begins to the room in question.

What was said about the course of curve 21 also applies here accordingly.

Claims (10)

Title of the invention: Method for regulating a space heating system Claims: method for regulating a space heating system with a heating device, several heat exchangers, a circulation pump, an expansion vessel and valves, which are connected in a flow circuit and from which the valves to the Heat exchangers open and closed depending on temperature sensors are, characterized in that both the surface of each heat exchanger as well as temperature sensors can be assigned to each room, which can be set in an adjustable Frequency can be scanned by a registration device and in the event of a deviation the actual temperature value of the heat exchanger surface and the room temperature of a control device for their setpoint temperature values to open the Valve in the flow of the relevant heat exchanger and when the target temperature value is reached causes the heat exchanger surface to close the valve. 2. The method according to claim 1, characterized in that the heating device only as large as the hourly heat demand of the room with the greatest transmission losses, on the other hand, the heat exchangers are designed to be larger than conventionally. 3. The method according to claims 1 and 2, characterized in that that every heat exchanger is approx. 40% to 70% larger than a heat exchanger is designed according to the conventional calculation method. 4. The method according to claims 1 to 3, characterized in that that each heat exchanger in a room is designed to be so large that when it is detected of 10 rooms by the registration and control device the heating time 10% of the The cooling time of the room is around 1 K. 5. Process according to claims 1 to 4, characterized in that that the control device is assigned an automatic timer, through which certain rooms in terms of their heating depending on the time of day adjustable Vonang received in front of other rooms. 6. The method according to claims 1 to 5, characterized in that that if the hysteresis of the actual temperature value falls below the relevant Heat exchanger surface in a room with simultaneous achievement of the room target temperature value the latter is used as the overriding control criterion and is used by the registration device no heating requirement for this room is reported to the control device. 7. The method according to claims 1 to 6, characterized in that that the frequency of the recording device with which the actual temperature values are covered by the heat exchanger surface on the one hand and the room on the other, approx. 0.1 Hz. 8. The method according to claims 1 to 7, characterized in that that the registration device, if a space scanned by it as not priority is recognized, searches for the next room to be heated with priority and, if for this no heating requirement is registered, only then a signal is sent to the control device granted for heating the room initially recognized as not having priority. 9. The method according to claims 1 to 8, characterized in that that with strong ventilation of a room, e.g. by opening a window, the regulator device, e.g. by means of an interrupt switch located on the lower edge of the window frame, is switched off, on the other hand with poor ventilation, e.g. by a tilted position of the window remains switched on. 10. The method according to claims 1 to 9, characterized in that that as a heat exchanger both conventional radiators and convectors as well conventional pipe registers can be used for radiant heating.