DE3315881A1 - Method of operation of a heating-system circulating pump - Google Patents

Abstract

Published without abstract.

Description

Operating procedure for a heating circulation pump

The invention relates to an operating method for a heating circulation pump in a heating system controlled by a heating controller, in which the dependent the heating circulation pump is switched off by a signal if the signal is longer as a first period of time 6t1, in which the heating / circulation pump for a third time period At3 is turned back on after being longer than a second Period of time was switched off and the heating circulation pump again immediately turns on when the signal disappears.

Such an operating method is known from DE-OS 31 10 136. This is done after a long period of downtime when the mixing valve is in the area the end position "closed" is the motor of the circulation pump for a predetermined period of time At3 switched on automatically and At2 automatically for a specified period of time switched off. However, if the mixing valve is not in the end position is "closed", the motor of the circulation pump remains switched on continuously.

In the event of longer downtimes, for example in summer, a limescale build-up in the heating circulation pump, which increases the service life of the circulation pump could be prevented. The well-known arrangement is therefore about it suitable, e.g. if the heating system is switched off in summer, an occasional Switch on to avoid deposits. An application of this well-known Arrangement in normal heating mode is neither intended nor possible because the actual value transmitter of the constantly active heating controller after switching off the heating circulation pump for the actual heating circuit temperature representative value more would capture.

The object of the invention is therefore to provide an operating method for a Design the heating circulation pump of the type mentioned so that in heating mode the heating circulation pump is only switched on when it is actually needed.

According to the invention, this object is achieved in that the signal is issued by a comparator when the heating circuit temperature recorded by a sensor is higher than the setpoint temperature specified by the heating controller that the second Time span t2 is dimensioned in such a way that a room temperature generated by the heating system is achieved in this time period At2 changes only slightly that the third time period is dimensioned in such a way is that the sensor At3 is set to one for the heating circuit temperature during this period representative temperature is brought that the heating circulation pump without delay is switched off again when the signal after the third time period CIIt3 is still pending and that an output signal from the heating controller that controls the heating system inactive during the third time period At3 after switching on the heating circulation pump is switched.

With this operating method, the heating circulation pump is switched off, if no more thermal energy is required for a longer period of time. Periodically it is switched on again briefly to flush the heating system and thus bringing the sensor to a temperature that is representative of the heating system. If it turns out that this is below the setpoint, the heating circulation pump is activated put back into operation, but otherwise switched off again immediately. at this mode of operation cannot only be used during summer operation the Heating, but also during normal heating operation electricity for the operation of the Heating tissue pump can be saved. In summer, where a determination of the current heating circuit temperature is not necessary, one could refer to what was explained at the beginning well-known operating method that only stuck the heating circulation pump should prevent, pass over. As long as no heat is requested from the heating system there is no unwanted heat exchange between the rooms to be heated and the generally colder cellar due to the water circulated in the pipe system. If the heating system is coupled with a heat pump for outdoor installation, This means that there is also heat transfer during the downtimes of the heating circulation pump outwardly prevented. When operating with a heat pump, it also turns out to be particularly advantageous that the controller output signal only after the end of the third time period At3 enabled and thus an unnecessary cold start of the heat pump is avoided.

The second time span 2 is advantageously in the range of 0.5 up to 2 hours. This range has proven to be beneficial because it is generally used the room temperature drops slightly at most.

The third time period is expediently between 5 and 15 minutes. This time is generally sufficient to flush the heating system through and thus to bring the Pihler to a representative temperature.

The heating pump is advantageously switched on continuously when the temperature recorded by the sensor is in the area where there is a risk of frost. So that will Freezing of the heating system is prevented even if the target temperature is reached is extremely low due to a setting or a fault in the heating controller.

An exemplary embodiment of the invention is described below with reference to FIG Figures 1 to 4 explained in more detail.

Fig. 1 shows schematically the arrangement of a heating system. With a Heating circulation pump 1 is the heating water via a pipe system through radiator 6, possibly.

an outdoor heat pump 9 and a four-way mixer 2 circulated. In the exemplary embodiment, a boiler is attached to the four-way mixer 2 7 connected. The four-way mixer 2 is controlled by a controller 3. The regulator 3 determines a setpoint value from the outside temperature detected by an outside sensor 5 for the return temperature of the heating system. This is recorded with a sensor 4. The controller 3 contains a comparator which supplies a "1" signal at an output 3a, if the actual value of the heating circuit temperature detected by a sensor 4 is above one of the Setpoint determined by controller 3 is. The output 3a of the controller 3 is via a Control circuit 8 connected to the heating circulation pump 1 with the control circuit 8 the operating method explained below with reference to FIGS. 2 and 3 accomplished. FIG. 2 shows, by way of example, the course of the values detected with the sensor 4 Actual temperature tests the setpoint temperature Tset specified by controller 3 as well as the Temperature setpoints resulting from the temperature setpoint T5011 through switching hysteresis TSOS T5011 Figure 3 shows the switching status of the heating circulation pump with the same time axis 7th

As long as the actual temperature value Tact is below the setpoint TSollt, the circulation pump is running. If the actual temperature Tist exceeds the setpoint temperature T50111, so the heating circulation pump initially continues to run for a period of time At1 and becomes then switched off. A shutdown always takes place when the heating system longer Time no heat is required. The time period # t1 can e.g. about 1/2 hour. The temperature detected by sensor 4 is correct is now the temperature at the installation location of the sensor 4, so it does not represent any representative measured value for the actual heating circuit temperature. In general the sensor 4 is insulated in the boiler room so that it hardly cools down. In order to prevent the heating system from running due to incorrect temperature information does not provide any more heat even when required, the heating circulation pump is switched on after a Time span # t2 switched on again.

The time period At2 is dimensioned so that the room temperature is not can decrease significantly. The heating circulation pump is switched on initially for a period of time At3, which is sufficient to flush the heating system through and thus to bring the sensor 4 back to a representative temperature. During the period At3, the output signal of controller 3 is blocked to allow control intervention to prevent incorrect temperature information from sensor 4. Only at the end of the Period At3 it is checked whether the current actual temperature test is above or is below its setpoint. If it is above its setpoint T5011ft, the heating circulation pump will 1 switched off again and the heating system periodically after the period # t2 flushed through again to determine the current actual temperature value. Is against it At the end of the period At3, the actual temperature value Tist is below the setpoint T5011, so the heating circulation pump 1 remains switched on and the controller 3 becomes active.

Should the actual temperature value Tist fall below the setpoint Ts011 ,, decrease, which is shown in Fig. 2 by dashed lines, so the heating circulation pump is switched on immediately for the period At3.

So it is first checked whether the drop in the actual temperature Tis actually a drop in the heating circuit temperature is equivalent to. If at the end of the time span the current actual temperature Tist is over again the setpoint Tsoll ', the heating circulation pump 1 is switched off again, the controller 3 remained inactive. However, if at the end of the period At3 shows that the heating circuit temperature is actually below the setpoint Tsoll ' heating circulation pump 1 remains switched on and controller 3 becomes active. When the actual temperature T act drops rapidly, the heating circulation pump is activated put into operation immediately and did not wait for the time period # t2.

Fig. 4 shows an example of how to use the described operating method could realize with discrete components. The output 3a of the controller 3 is connected to a first input of an AND gate 12, the output of which has a Switch-on delay element 13 is connected to a switch-off delay element 14 is.

The output of the switch-off delay element 14 is in turn on a Input of an AND gate 15 switched, the output of which has a switch 11 for the Heating circulation pump 1 controls. The output of the AND gate 15 is on negative signal edges responsive switch-on delay element 16 connected, the on the output side, in turn, connected to a first input of a CDERZatter 17 is. The second input of the ORI gate 17 is connected to the output 3a of the controller 3 tied together. The OR gate 17 is followed by a timer 18 which responds to an input signal no matter what length responds with an output signal of time duration t3. This The output signal is a further input of the AND gate 15 and also one inverting .in.gang of AND gate 12 is supplied. P'jin Ten rlaturwrichter 10 for frost protection is finally with a third input of the ODJ * 'R gate 15 connected.

In this circuit arrangement it is assumed that the controller 3 supplies a "1" signal at output 3a if Tist <TSO11 If this signal disappears, the switch 11 is not switched off immediately, but only after a delay time At1 predetermined by the timing element 14. If Tist again becomes smaller than T5011, then via the OR gate 17, the timer 18 and the OR gate 15 of the switch 11 is initially switched on for the period At3. That Timing element 14 does not initially take effect because AND gate 12 is blocked.

If after the expiry of the time period t3 the signal at the output 3 3a of the Controller 3 is still pending, the delay element remains via AND gate 12 13, the switch-off delay element 14 and the AND gate 15 of the switch 11 are switched on. The delay element 13 only has the task of triggering the timer 14 to prevent so long when a signal occurs at output 3a until this is blocked via the timer 18 at the AND gate 12.

When the switch 11 is switched off, the switch-on delay element becomes 16 and switches switch 11 via the Time element 18 for the period of time Bt on again.

3 If the controller 3 is microprocessor-fitted, it recommends the functions required for the operating procedure described with vom To let the microprocessor take over.

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Claims (4)

Claims 1. Operating method for a heating circulation pump (1) in a heating system controlled by a heating controller (3), in which in Depending on a signal, the heating circulation pump (1) is switched off when the signal is present for longer than a first period of time (At1) during which the heating circulation pump (1) is turned back on for a third period of time3) after being longer than a second period of time (ast2) was switched off and during which the heating circulation pump (1) is switched on again immediately when the signal disappears, d a d u r c h e k e n n n z e i c h -n e t that the signal is output by a comparator when the heating circuit temperature recorded by a sensor (4) is higher than the setpoint temperature predetermined by the heating controller (3), that the second period of time (ast2) is dimensioned so that a room temperature generated by the heating system in this period of time cit2) changes only little that the third period of time tAt3) so is dimensioned that the sensor (4) in this period of time (At2) on a for the heating circuit temperature representative temperature is brought that the heating circulation pump (1) without delay is switched off again when the signal has elapsed after the third time period (# t3) is still pending and that an output signal from the heating controller that controls the heating system (3) trend of the third time period (set) after switching on the heating circulation pump (1) is switched to inactive. 2. Operating method according to claim 1, d a d u r c h g e k e n n z It is true that the second period of time (# t2) ranges from 0.5 to 2 hours lies. 3. Operating method according to claim 1 or 2, d a d u r c h g e k e nn z e i c h ne t that the third time span (ast3) between 5 and 15 minutes lies. 4. Operating method according to one of claims 1 to 3, d a d u r c It is to be noted that the heating pump (1) is constantly switched on is when the temperature detected with the sensor (4) is in the area of risk of frost lies.