NL9301575A - Method for controlling a heating system. - Google Patents

Description

Method for controlling a heating system

The invention relates to a method for controlling a heating installation with a heat source fed by a burner and a control device with which a blocking time for switching the burner on again after it has been switched off by the heat demand can be preset, and apparatus for performing this method.

Sources of heat with low thermal inertia limit the number of switchovers of a timer which enforces preset operating breaks for the burner. Known are devices - e.g. according to DE-OS 3.718.653 -, which have a timer which is set on the working side with a fixed blocking time of approx. 5 min. With a device described in EP-PS 8.461, a control device with a timer is provided for this purpose. , of which the fixed blocking time expires repeatedly, as long as there is no heat demand. This minimum blocking time is disadvantageous in particular for devices with a low water content, for instance when plate heating bodies are used, since the blocking time is then too long under circumstances. After switching on the burner, the temperature rises very quickly and exceeds the nominal value of the flow temperature. The burner switches off again after a short time, so that a strong cooling of the system can be expected in the subsequent blocking time. The consequences are very strong temperature fluctuations, which often lead to complaints. Therefore, in a known circulating water heater, the timer is provided with a potentiometer for adjusting the blocking time. However, an adjustment to a short blocking time is only feasible by service professionals, whereby a shortening of the life of the device, determined by the number of changes, must be taken up. The increase in the number of changes, that is to say the switch-on and switch-off frequency of the burner, also has an increase in the emission when starting in the starting phase of the burner.

From German Offenlegungsschrift Nr. 3,908,136 and German Patent No. 3,426,937 have become known, with the aid of which the blocking time can be determined depending on the length of the preceding switched-on period, or the number of switched-on heat consumers. These devices are only suitable for certain heating systems. In addition, expensive circuits with sensitive measuring probes are necessary.

The object of the invention is to provide a general method and correspondingly simpler devices for the control of a heating installation of the type indicated above, whereby the utilization comfort, the switching play number and the emission when starting the heating installation are improved.

The object is achieved according to the invention in that the blocking time can be varied by a parameter representing the heat demand, such that the blocking time for the burner being switched on again decreases with increasing value of the parameter. By introducing a variable, automatically optimally adjusting blocking time for switching on again, the switching play number is adapted to the situation of the heat demand according to the circumstances. In general, with high heat demand, especially at very low outside temperature, short blocking times and long blocking times occur with low heat demand.

The parameter representing heat demand is preferably either a nominal value of the flow temperature VTnon or an inverse of the flow rate of the current value of the flow temperature VTact. In the latter variant, the inverse of the run-up speed is taken as a parameter, since at a higher run-up speed of the temperature there is a small heat demand and therefore a relatively long blocking time is possible. The run-up speed is preferably determined after the start-up phase of the burner. The length of the start phase is either predetermined (e.g. 1 or 2 min) and constant, or variable with the variation of the temperature difference between the flow temperature VTact and the temperature in the area of a heat exchanger, the start phase then ending at Tm - VTact = constant. By determining the actual length of the start phase, on the one hand errors in determining the run-up speed of the current value of the flow temperature VTact, which occur with a too short preset start phase, are avoided, and on the other hand the time space for determining the run-up speed is not unnecessarily reduced, which is to be expected in the case of a very long start-up phase given for the sake of certainty.

According to a favorable further development, a temperature probe for determining the temperature T ^ is arranged in the center of the block of a heat exchanger designed as a lamella block. The comparison of the values determined with this temperature probe and a lead temperature probe can be easily done by means of a differential amplifier. The condition -VTact = constant is fulfilled if the output signal of the differential amplifier changes only slightly.

A favorable embodiment for using the nominal value of the supply temperature VTnoB as a parameter is characterized in that a continuous room thermostat is arranged, the output signal of which is fed to a differential amplifier and the timer connected also to the supply temperature, the differential amplifier and the timer being an electronic operate the switch, which acts on the fuel supply to the burner. It can be ensured that a circuit for activating the timer and for predetermining a minimum and a maximum blocking time for the reactivation tBin and tKalc is connected to the timer.

A further embodiment, in which a switch-on duration of the burner prior to switching off is the parameter, can be realized in that a timer is provided with a counter, which is started when the burner is switched on, while the switching-on duration with a first frequency is controlled, and after switching off the burner to a maximum counter position with a lower second frequency. For generating the first and second frequencies, a frequency modulator can be arranged, which is fed by an oscillator via a frequency divider and which is controlled by the output signals of a Schmitt trigger processing the respective heat demand. In this embodiment, an electronic switch acting on the fuel supply to the burner is preferably included, the control line of which via an AND means with the Q output of a flip-flop and with the output of a building element that processes the heat demand, for example of a Schmitt trigger is connected, with the S input of the flip-flop also at the output of this component and the R input of the flip-flop at the output of the counter.

In a further embodiment for varying the blocking time for restarting the burner, the parameter representing the heat demand is a current value of the flow temperature VTact at the time of the heat demand ended. The particular advantage of this solution lies in its applicability, also in connection with two-point room thermostats, whose switching signal is independent of the set flow temperature. A two-point room thermostat can be set up, whose switching time for the termination of a heat demand is based on the current value of the flow temperature VTact as a parameter. If the room thermostat switches off at low current values of the supply temperature, long blocking times will occur; times are shorter at higher current temperatures.

The invention can be successfully used in a heating installation with a circulating water heater as a heat source fed by a burner. A particularly clear effect is obtained in installations with plate heating bodies, since they have a relatively low water content. With higher heat demand, rapid cooling of the plate heaters can therefore be expected, which is counteracted by correspondingly short blocking times before switching on again.

Advantageous further developments of the invention are the subject of the subclaims, respectively, or are further elucidated below with reference to the Figures together with the description of embodiments of the invention.

Thus shows:

Fig. 1 is a circuit diagram of a first embodiment of the invention,

Fig. 2 a circuit diagram of a second embodiment of the invention,

Fig. 3 is a flow chart of a third embodiment, and

Fig. 4 is a graph of the lead temperature versus time in the third embodiment.

Fig. 1 shows an influence on a timer for a blocking time of switching on a burner of a heating system again, depending on the respective actual nominal value of the supply temperature VT ^. A heat source operated by a burner essentially consists of a heat exchanger 1, which is connected to a return pipe 2 and a supply pipe 3 and which is heated by a burner 4, which is fed via a fuel supply pipe 6 provided with a solenoid valve 5. The supply pipe 3 is provided with a temperature probe 7, which is for instance designed as a temperature-dependent resistor. As a result, voltages are present on the associated connecting line 8, the actual value of which is variable with the temperature of supply line 3. Furthermore, a continuous room thermostat 9 is arranged, which is connected via a line 10 to a differential amplifier 11. The second input of differential amplifier 11 is formed by connecting line 8 of temperature probe 7. The continuous room thermostat 9 is provided with a nominal value adjuster 12 and a room temperature probe 13, the output signals of which are coupled to each other via a further differential amplifier 14. The output signal of this differential amplifier 14 goes to line 10. A branched line 15 from line 10 is connected to a timer 16. Timer 16 switches an electronic switch on and off via a control line 17. Electronic switch 18 is included in a conduit bundle, which connects differential amplifier 11 to magnetic coil 19 of solenoid valve 5. An amplifier 20 is connected behind electronic switch 18. A circuit 21, which is provided with switching elements for switching on the timer and for establishing a minimum and a maximum blocking time for the switching on again and tMX, supplies timer 16.

The operation of the circuit as a whole is shown in more detail below:

The continuous room thermostat creates a nominal value for the flow temperature VTn0B, which is compared by means of the differential amplifier 11 with the current value of the flow temperature VTact, which is on line 8. When a minimum difference is exceeded, i.e. with a minimum control deviation, there is a heat demand. The output signal of differential amplifier 11 is correspondingly high, so that in case electronic switch 18 is in closed condition, solenoid valve 5 is opened immediately and burner 4 is turned on. The burner activation is blocked when electric switch 18 is in the open position. Timer 16 opens electronic switch 18 for a certain period of time after each burner shutdown. As a result, the switching backlash number is smaller. However, timer 16 is not set to a specific time, but in turn is supplied by the nominal value of the flow temperature VTn0B via branch line 15. In this way it is ensured that the blocking time for restarting burner 4 decreases with increasing nominal value of the flow temperature VTnoa. This avoids strong temperature fluctuations, especially with high heat demand.

Fig. 2 shows in the same manner of representation as FIG. 1 a second embodiment, in which it is not the flow temperature VTn0B, but a period switched on before the burner is switched off, which determines the variation of the blocking time for the switch-on. The construction and arrangement of the construction parts 1 to 8 of the heat source and 9 to 14 of the continuous room thermostat correspond to those of Figs. 1. The line bundle between differential amplifier 11 and solenoid valve 5 with electronic switch 18, amplifier 20 and solenoid coil 19 are also as shown in FIG. 1. The output of differential amplifier 11 is connected to a Schmitt trigger in addition to electronic switch 18 via a branch line 22. An oscillator 24 generates a base frequency which is applied to a frequency divider 25. The outputs of frequency divider 25 are connected to a frequency inverter 26, which is controlled by the output signal of the Schmitt trigger. The output of frequency inverter 26 forms the input of a counter 27, the output of which is again connected to the R input of a flip-flop 28. The output of the Schmitt trigger 23 is also on the S input of a flip-flop 28 switched. In addition, from the output of Schmitt trigger 23, a branch line 29 has branched to an AND member 30. The second input of AND member 30 forms the Q output of flip-flop 28, while the resulting signal of the AND coupling acts on electronic switch 18 via a control line 31.

This circuit has the following effect:

The oscillator frequency is divided into two frequencies via frequency divider 25. A first higher frequency represents the switch-on effect and a second lower frequency represents the blocking time of the burner being switched on again. In this way, long blocking times can be established. The heat demand switches the Schmitt trigger output to H level. Thereby, the frequency inverter 26 is controlled such that the higher frequency is at its output. However, the H level at the output of the Schmitt trigger 23 is also at the input of flip-flop 28, so that it is set. The resulting H level of the output of flip-flop 28 in turn controls electronic switch 18. Gas is released via amplifier 20 and solenoid valve 5. At the same time, counter 27 with the higher frequency counts the switch-on time. When the heat demand ends, the output of the Schmitt trigger is set to zero. Electronic switch 18 is opened via AND means 30, whereby the gas supply is interrupted. Simultaneously, the lower frequency is further fed to counter 27 via frequency inverter 26. When counter 27 reaches its maximum count position, a reset signal goes to flip-flop 28. This ends the blocking time for restarting. An additional logic, for example digital comparators, not shown here, is required to establish a minimum and a maximum blocking time for the reactivation.

When shown in FIG. 3 and FIG. 4, the run-up speed of the current value of the flow temperature VTaot, during the switched-on phase of the burner which has been switched on, is the determining variable for the blocking time for the restarting. The necessary operating sequences are realized by software. Therefore, a hardware representation in a block switching image within the meaning of FIG. 1 and FIG. 2 does not make sense. The software program starts at heat demand 32 and switching on burner 4 33. A first timer 34, which is set for the duration of a burner start-up phase, is activated. After this start-up phase, the heating-up time may already have ended, i.e. the modulation of burner 4 starts. This condition is recognizable in that the delivered heating performance is below the maximum possible. In this case, a signal is generated which, after the next burner 4 shutdown, triggers the maximum blocking time for restart 36. A shorter blocking time is possible if, after the starting phase of the burner, heating continues with maximum power output. Only if modulation 35 has not started immediately after the start-up phase or during the start-up phase, shorter blocking times for switching on again are necessary. For this purpose, a first value of the flow temperature VTact is first measured and stored 36. At the same time, a second timer 37 is started. The subsequent modulation query 38 is repeated until modulation operation begins. The operating state 39 of the burner is tested simultaneously. As soon as the modulation starts and the flow temperature VTact increases more slowly - as Fig. 4 shows - a second value of the flow temperature VTact is measured and stored 40. The time counter associated with the second timer 37 is stopped 41. The flow speed of the flow temperature can now be determined from the difference between the second value of the flow temperature VT2 and the first value VT1 and the time required for this measured by the time counter of the second timer. After the ramp-up speed 42 has been calculated, the blocking time for reactivation 43 dependent on this parameter is performed. This program sequence is repeated when the burner is switched on again.

The invention is not limited in its embodiment to the above-mentioned preferred embodiments. Rather, a number of variants are conceivable which make use of the shown solution, also in embodiments which are otherwise grounded in principle. In particular, the implementation is not limited to establishing with separate logic assemblies, but can also be successfully accomplished with programmed logic - preferably using a computer.

Claims (14)

Method for controlling a heating system with a heat source fed by a burner and a control device with which a blocking time for restarting the burner after its shutdown determined by the heat demand can be preset, characterized in that the blocking time can be varied by a parameter representing the heat demand, such that the blocking time for restarting burner (4) decreases with increasing value of the parameter. Method according to claim 1, characterized in that the parameter is a nominal value of the flow temperature VTnoE. Method according to claim 1, characterized in that the parameter is an inverse rate of increase of the current value of the flow temperature VTaot during the switch-on phase of burner (4) which has preceded the switch-off, the rate of increase after the start-up phase of the burner (4) is determined. Method according to claim 3, characterized in that the length of the starting phase is predetermined (e.g. 1 or 2 min) and is constant. Method according to claim 3, characterized in that the length of the start phase varies with the variation of the temperature difference between the flow temperature VTaot and the temperature in the region of a heat exchanger (1), the start phase being terminated at - VTact = constant. Device for carrying out the method according to claim 5, characterized in that a temperature probe for determining the temperature Tm is arranged in the center of the block of a heat exchanger designed as a lamellar block. Device for carrying out the method according to claim 2, characterized in that it comprises a continuous room thermostat (9), the output of which flows to a differential amplifier (11) and timer (16) also connected to the flow temperature probe (7). wherein differential amplifier (11) and timer (16) power an electronic switch (18), which switch (18) either blocks or does not block the fuel supply to burner (4). Device according to claim 7, characterized in that a circuit (21) for switching on the timer and for establishing a minimum and a maximum blocking time for switching on again t1l and t1ax is connected to the timer ( 16). Device for carrying out a method according to claim 1, characterized in that the parameter is a switch-on time of burner (4) before switching off, wherein a timer (16) is provided with a counter (27), which burner burner (4) is started while the duty cycle is controlled with a first frequency and after shutdown up to a maximum counter reading with a lower second frequency. Device according to claim 9, characterized in that a frequency inverter (26) is provided for generating the first and the second frequencies, which is fed via a frequency divider (25) by an oscillator (24) and which is supplied by the output signals of a Schmitt trigger (23) processing the respective heat demand. Device according to claim 9 or 10, characterized in that an electronic switch (18) acting on the fuel supply to the burner (4) is arranged, the control line (31) of which is connected to the Q via an AND member (30). output of a flip-flop 28 and is connected to the output of a construction element processing the heat demand, for example a Schmitt trigger (23), the S input of flip-flop (28) also being connected to the output of this construction element and the R input of flip-flop (28) are at the output of counter (27). Method according to claim 1, characterized in that the parameter is an actual value of the flow temperature VTaot when the heat demand has ended. Device for carrying out a method according to claim 12, characterized in that a two-point room thermostat is arranged, based on its switching time for ending a heat demand as the current value of the flow temperature VTaot as a parameter. Device according to one of the preceding claims, characterized in that the heat source fed by a burner is a circulating water heater.