DE19601130C2 - Process for controlling a room heating system - Google Patents

Description

The invention relates to a method for controlling a Space heating system with a central heat generator, for example gas boilers, for heating a Heat transfer medium and with a room temperature controller that the The actual room temperature is recorded and a room temperature setpoint is adjustable, as well as with an actuator, such as a control valve or controllable circulation pump, for setting the heat transfer medium Flow rate per unit of time.

A method of controlling a temperature of a Central heating system is described in DE 35 37 104 C2. This serves to correct the heating curve. The heating system described shows the above assemblies.

In DE 38 32 495 A1, the temperature of a Heating medium of a circulation heater with a minimum temperature Limitation operated. Here is at a given temperature a low speed of the circulation pump is provided for the heating medium. The circulating speed of the heating medium is only reduced if there is a specified minimum temperature of the heating medium.  

This ensures that, in particular in the transition period Heating period by reducing the amount of the pumped Heating medium adapted the burner output to the actual need can be.

A heating system is also described in DE 41 36 771 A1 where the heating circuit pump with reduced activity or reduced Volume flow is operated and thus a reduced Power supply to the heating circuit is reached.

For systems that have a certain boiler temperature or Due to the system, the flow temperature cannot be lower is one Reduction of the heating capacity below a minimum temperature by the The heating circuit volume flow can be reduced.

The object of the invention is a method of the type mentioned to propose by which the heat generator on a possible low temperature level is operated.

This task is solved by the characteristics of the  characterizing part of claim 1.

With increasing room heat demand, the Heat transfer medium flow rate without increasing the Flow temperature increased. The heat generator works so long at a low temperature level. Out of it there is an economical operation with low Losses. Only if, despite the maximum flow rate the respective room heat requirement is not covered, the Flow temperature raised.

Advantageous refinements of the invention result from the subclaims and the following description of an embodiment. The drawing shows:

Fig. 1 shows a room heating system schematically,

Fig. 2 is a diagram of Durchflußmengenerhöhung,

Fig. 3 is a diagram of the flow temperature increase and

Fig. 4 is a supplement to FIG. 3.

A central heat generator (I), for example a gas boiler, works with a control device ( 2 ) for the flow temperature. In the example, the space heating system is divided into space heating zones (I, II). Additional zones can also be provided. Each space heating zone comprises at least one space heater ( 3 , 4 ; 3 ', 4 ') in one or more rooms to be heated. Each room heating zone (I, II) is supplied with heating water from the heat generator (I) via a flow line ( 5 or 5 '). Each room heating zone (I, II) is assigned a motor-driven control valve ( 6 or 6 ') or a circulating pump with adjustable speed. The control valve or the circulation pump is controlled by a control circuit ( 7 or 7 ') of the relevant space heating zone (I, II). A room temperature setpoint generator ( 8 or 8 ') is located on the control circuit ( 7 , 7 ') and can be set by a timer (9 or 9 '). The control circuit ( 7 , 7 ') detects the actual temperature of the lead room of the respective room heating zone via a room temperature sensor ( 10 or 10 ').

The operation of the system described is in essential following, the ratios be described with regard to the space heating zone (I). For the room heating zone (II) applies accordingly.

In Fig. 2 it is assumed that at the time (t0) the control valve ( 6 ) or the instead of this provided speed-controllable circulation pump is set so that a minimum flow rate (Q1) flows. As long as the set target temperature is reached with this temperature, nothing else happens.

If the set target temperature is not reached in the room in question, then the control circuit ( 7 ) switches on the control valve ( 6 ) further, so that a larger flow rate Q2 flows to the radiators ( 3 , 4 ), which is shown in FIG. 2 at the time (t1 ) the case is. The increased flow rate is maintained at least for a defined dwell time tV, for example 10 minutes to 15 minutes, because the target temperature cannot be reached immediately. The dwell time tV is dimensioned such that, in many practical operating cases, the room temperature can increase by a few K to the target temperature.

If the target temperature is not reached after the dwell time tV, then the control circuit ( 7 ) switches the flow rate by a further step to Q3, which is the case in FIG. 2 at time t2.

If the target temperature is not reached even with the flow rate (Q3), for example because the target value has been set higher, the flow rate is set to its maximum value Qmax, which is the case in FIG. 2 at t3. If the target temperature is not reached with the flow rate Qmax after the dwell time tV, then the flow temperature Tv is increased, which is described in more detail below. Up to time t4, the control device ( 2 ) regulates the flow temperature to a value that is as specific as possible for the system.

Instead of the three stages shown in FIG. 2, more flow rate stages can also be provided. Each stage remains switched at least during the dwell time tV.

Exceeds the room temperature during the time (t1 to t4) the target temperature, then there is a corresponding gradual switching back of the flow rate.

If the desired room temperature is not reached despite the maximum flow rate (Qmax), the control circuit ( 7 ) sends a signal to the control device ( 2 ) of the heat generator ( 1 ) via a signal line ( 11 or 11 '). The control device ( 2 ) thus increases the flow temperature Tv, for example from T1 to T2 (cf. FIG. 3). The temperature T1 can be a temperature required for frost protection operation of the system or a higher temperature. The temperature increase is required for a certain duration tD, for example 10 min to 15 min, the duration tD being such that after the setpoint temperature has risen from T1 to t2 there remains a system-specific time which is usually sufficient for the room temperature to be sufficient increased by a few K to the setpoint.

If the flow temperature T2 is not sufficient to reach the room temperature setpoint, then it is increased by one step, which is the case at time t5 in FIG. 3. The flow temperature is raised from T2 to T3. The same applies to further stages. At time t6, for example, the target room temperature has still not been reached with the flow temperature T3. Accordingly, the flow temperature is raised to T4.

The specific duration tD, during which the temperature request from the control circuit ( 7 ) is valid, is preferably such that the increased target temperature remains for some time. After the determined duration tD, if no temperature increase is requested within it, the flow temperature is reset, which is the case in FIG. 3, for example, at time t7. The flow temperature drops accordingly. At time t8, the control circuit ( 7 ) requests a further temperature increase, so that the flow temperature rises again. No further temperature request occurs after time t9, so that the flow temperature Tv returns to its initial value T1.

Each time the flow temperature Tv is increased, the control valve ( 6 ) is switched back by at least one step. You can switch back to the lowest flow rate each time the flow temperature is increased. It also supports that an increased flow temperature quickly becomes effective on the room radiators.

Fig. 4 shows a pre-set by the control device (2) flow temperature Tn in the normal daytime and a flow temperature Ta in the lowered night mode and a flow temperature Tf in frost protection mode. In Fig. 4, curves a, b, c show the relevant temperature increases that occur when the control circuit ( 7 ) requests an increased flow temperature. If a temperature is requested at time t1 ', the flow temperature increases comparatively small (curve a). When temperature is requested at time t2 ', there is a greater temperature increase to - initially Tn. At time t3', the temperature increase (curve c) is even greater when temperature is requested in order to - initially - reach temperature Tn.

The flow temperature (Tv) can also be preset on the control device ( 2 ) as a function of the outside temperature, with the temperature increase corresponding to the signal from the control circuit ( 7 ) then taking place from this preset flow temperature value.

Claims (9)

1.Procedure for controlling a room heating system with a central heat generator, for example a gas boiler, for heating a heat transfer medium and with a room temperature controller that detects the actual room temperature and on which a room temperature setpoint can be set, and with an actuator, such as a control valve or controllable circulation pump , for setting the heat transfer medium flow rate per unit of time, characterized in that if the actual room temperature is less than the room temperature setpoint, the flow rate (Q) is first increased in stages, with each flow rate level being switched on at least for a certain dwell time (tV) remains and the next higher flow rate level is only switched on if the room temperature setpoint has not yet been reached within the dwell time (tV), and only if the flow rate level of the maximum flow rate (Qmax) is switched on and the room temperature If the setpoint is not reached, the room temperature controller ( 7 ) sends a signal to the heat generator ( 1 , 2 ) to increase the flow temperature (Tv) of the heat transfer medium. 2. The method according to claim 1, characterized, that the flow temperature (Tv) of the heat transfer medium is gradually increased, each Leaving water temperature level at least for a certain one Duration (tD) remains switched on, and the next higher one  Flow temperature level is only switched on when the Room temperature actual value still the room temperature setpoint not reached. 3. The method according to claim 1 or 2, characterized, that the dwell time (tV) of the flow rate stages is determined according to the inertia of the system, for example 10 minutes to 15 minutes. 4. The method according to any one of the preceding claims, characterized, that the specific duration (tD) of the flow temperature levels is determined according to the inertia of the system, for example 10 minutes to 15 minutes. 5. The method according to any one of the preceding claims, in particular claim 4, characterized, that after reaching the certain duration (tD) the Flow temperature is lowered. 6. The method according to any one of the preceding claims, characterized, that when switching on an increase in the flow temperature (Tv) of the heat transfer medium the flow rate (Q) switched back at least by one flow rate level becomes. 7. The method according to claim 6, characterized, that when switching on an increase in the flow temperature (Tv) of the heat transfer medium to the flow rate lowest flow rate level (Q1) switched back becomes. 8. The method according to any one of the preceding claims, characterized in that the control of the flow rates for different zones (I, II) of the space heating system takes place separately, each zone having at least one space heater ( 3 , 3 '), an actuator ( 6 , 6 ' ) and a room temperature controller ( 7 , 7 ') are assigned. 9. The method according to any one of the preceding claims, characterized in that a control device ( 2 ) of the heat generator ( 1 ) from the room temperature controller ( 7 ) receives control signals for increasing the flow temperature, which it depends on the outside temperature and / or a day-night - Presetting or frost protection operation.