DE19734361A1 - Control of water heating system - Google Patents

Abstract

The supply of hot water for use in a building is provided by a heater (10) that is coupled to a controller (11) that has a signal processor (14) and a daily cycle memory (20). Input to the controller is from a sensor (18) connected to the tap through which water is drawn off. The sensor signals are in the form of pulses that are used by the controller to determine a pattern of use that is used in establishing the heater program cycle.

Description

State of the art

The invention is based on a device for operation a heating system of the independent type Claim.

It is known that a heater Domestic hot water tank at a certain temperature level stops, so with a desired hot water tap warm water is available without delay. The warming of the domestic hot water tank also takes place at such times which are generally not expected to be tapped. To save energy, the user can over a timer keeps the hot water circuit activate. However, the user must have the timer beforehand program and thus already its future Define user behavior. Do these habits change is a rapid supply of warm water outside the country activated heating periods not guaranteed. The time switch must be changed if user behavior changes.  

Advantages of the invention

The device according to the invention for operating a Heating system includes a burner, the domestic water warmed up. A controller controls the burner via Control signal to that of a daily program of a time switch depends. The device according to the invention stands out characterized in that a dispensing sensor is provided, the one Tap signal detected, which indicates a hot water tap. The Dispensing signal is fed to a signal processing system that Dispensing signal assigns the respective time of day. The Daily program depends on the tap signal. thanks to this Dependency ensures that the keep warm circuit the process water is controlled so that changing User behavior is taken into account. Seasonal Shifts in typical usage actions are recognized and adaptively based on future actuation processes. Of the Ease of use increases because the user does not have a constant Reprogramming of the daily program Time switch must make. Even when commissioning This warming circuit can be set to one by the user parameterization of the time switch to be carried out become reliable after a few days Notes indicate which user behavior the Keeping the hot water circuit must be adapted. Separate controls for operating the timer are available not required. Thanks to the targeted activation of the Keeping warming can be unnecessary warm-up phases of the Avoid hot water, which reduces the energy consumption of the Heating system reduced.

In a useful training it is provided that Dispensing signal is stored in a daily memory. Several Tap profiles can be evaluated in this way, whereby the quality of the needs-based control of the  Warming circuit improved. Predictions of the future Tap behavior will be thanks to the recourse to several Records of previous taps improved.

An advantageous development provides that at least a previous tap signal and the current one Dispensing signal a probability of a future Tapping is determined, which influences the daily program. The Probability can be determined, for example Gain averaging.

In a further development, the respective dispensing signals evaluated by weighting factors. The weighted Tap signals are used as a measure of probability added. The respective values of the weighting factors depend from the respective days on which the corresponding Dispensing signal was detected. Thanks to the weighting factors current changes in user behavior when forecasting in to a greater extent. This fits the Activation of the warming circuit quicker the changed User habits. A clever choice of Weighting factors optimize the quality of a tap forecast.

In an advantageous embodiment, the Probability of a future tap with a Probability threshold compared. The control signal depends on the comparison. After comparing the Probability with a predeterminable threshold, at whose Do not fall below an activation of the warming circuit is deemed sensible, the respective results binary state of the control signal. With the choice of Probability threshold can be entered in a simple manner set specific user type. Will the Probability threshold set very low the user a fairly high level of certainty that too  unlikely times of warm water quickly is available, but at the expense of a relative frequent heating of the domestic hot water tank. Will the Probability threshold set relatively high, takes the user has certain waiting times in buying, the Shortening the warm-up phase Heating system guaranteed.

In an appropriate further training one hangs Target temperature of the hot water from Probability of a future tap. One with the Probability corresponding continuous Target temperature specification avoids the difficulties of one binary control of the warming circuit, which is currently in the immediate vicinity of the probability threshold one not always with actual user behavior perform compliant activation of the warming circuit can.

Further appropriate training from other dependent Claims emerge from the description.

drawing

An embodiment of a device according to the invention is shown in the drawing and explained in more detail in the following description. In the drawings Fig. 1 is a block diagram, Fig. 2a to 2e possible waveforms, and Fig. 3 is a flowchart.

Description of the embodiment

A dispensing sensor 18 detects a dispensing signal z _n which is fed to a signal processing unit 14 which contains a daily memory 22 . The signal processing 14 influences a daily program 20 . Depending on the daily program 20 , a controller 11 outputs an actuating signal S to a burner 10 . Signal processing 14 and daily program 20 are contained in controller 11 .

FIGS. 2a to 2c possible diurnal patterns are Zapf signals z _n, z _n-1, z _n-2 below. The probability p (z _{n + 1} ) of a future tap is determined as a function of the time of day from the tap signals z _n , z _n-1 , z _n-2 , FIG. 2d. A probability threshold ps with a constant course is also shown. If the probability p (z _{n + 1} ) falls below the probability threshold ps, the future actuating signal S _{n + 1} assumes the value zero, otherwise the value one, FIG. 2e.

The control 11 activates the burner 10 for hot water heating via the control signal S in such a way that a keep-warm circuit is activated at predefinable times. When the keep-warm function is active, for example, a domestic hot water tank is kept at a certain temperature level. If the temperature of the domestic water falls below a specified lower limit, the burner 10 heats until an upper temperature limit is reached. The temperature level of the domestic hot water tank is within these limits. If the keep-warm circuit is not active, the burner 10 receives no signal for domestic water heating.

A tap sensor 18 generates, for example, a binary tap signal z _n as a function of tap water. For example, a water switch can be used as the dispensing sensor 18 . The signal of a flow turbine activated during a tap can also be evaluated as a tap signal z _n . The signal processor 14 provides this tap signal z _n with the time at which the tap is taken. A daily rhythm can usually be assigned to user behavior. The index n denotes the current day on which the tap z _n is currently taking place. The indices n-1, n-2 stand for a previous tap, for example the index n-1 for a tap on the previous day, the index n-2 for a tap on the previous day. FIGS. 2a to 2c is a continuous course of the current Tapping z _n and the previous draw-offs z _n-1, z _n-2 below. The currently recorded tap z _n is stored in a daily memory 22 . In the further description, two previous tapping signals z _n-1 , z _{n-2 are used in} addition to the current tapping signal z _n to determine the probability p (z _{n + 1} ) of a future tapping z _{n + 1} . For example, the tapping curves stored in FIGS . 2a to 2c have resulted.

After the current tap z _{n has} already been recorded, step 101 , the probability p (z _{n + 1} ) is calculated, step 102 . The three dispensing signals z _n , z _n-1 , z _n-2 are weighted equally. The probability p (z _{n + 1} ) is determined by simple averaging. For example, since at 6:00 a.m. only two of the three taps signal a tap of domestic hot water, the probability p (z _{n + 1} ) for this point is two thirds. The course of the probability P (z _{n + 1} ) outlined in FIG. 2d results in the manner described.

This probability p (z _{n + 1} ) is compared with the probability threshold ps. If the probability p (z _{n + 1} ) falls below the probability threshold ps, which is set to 0.5, for example, the keeping-warm circuit of the burner 10 is not activated. Depending on the comparison, the future daily program 20 and the corresponding actuating signal S _{n + 1 result} which activate or deactivate the keep-warm circuit of the burner 10 .

Alternative embodiments are conceivable. The calculation of the probability p (z _{n + 1} ) in step 102 can be modified such that the dispensing signals z _n , z _n-1 , z _n-2 are weighted differently by weighting factors G _n , G _n-1 , G _{n- 2nd} The further back the tapping process, the lower the weighting factor G to be selected, by which the respective tapping signal z is multiplied. The weighted dispensing signals z are then added and divided by a normalization factor, which is calculated from the sum of the weighting factors G.

As a further alternative, the probability P (z _{n + 1} ) of the future dispensing process, taking into account the current dispensing signal z _n and the probability p (z _n ) of the previous dispensing forecast, is obtained, for example, by adding it to the current dispensing signal z _n . determined. The current dispensing signal z _n is again to be weighted in a suitable manner.

In a further alternative exemplary embodiment, it is provided, depending on the probability p (z _{n + 1} ), of specifying a setpoint temperature of the process water which is proportional to this for a future tap.

A quartz clock can be provided in the signal processor 14 for the purpose of time allocation of the dispensing signal z _n . However, the signal processor 14 could just as well have a receiver for a radio clock signal, which is used for time allocation.

To insignificant short taps not the future Such tapping operations are used as a basis for tapping behavior specifically hidden, the tap duration a certain predeterminable minimum value.

In addition to a continuous detection of the dispensing signal z _n , the respective states of the dispensing signal z _{n are} stored at certain discrete-time support points and used in accordance with the time of the previous day to determine the probability P (z _{n + 1} ) in the manner already described.

Tap behavior on weekends and during the week generally shows significant differences. A tap forecast takes this division into two by using the tap signals z _n , z _n-1 , z _{n-2 of} the weekdays in the manner described for the weekday forecast, and the days of the weekend for the weekend forecast as a database.

The invention does not only relate to Areas of application that relate to a forecast of a Support hot water tapping. For the purpose of one Home heating control can also meet heating requirements recorded and in a future heating control be taken into account.

Claims (9)

1. Device for operating a heating system, with a burner ( 10 ) that heats hot water, with a controller ( 11 ) that controls the burner ( 10 ) via an actuating signal (S) that depends on a daily program ( 20 ) of a timer , characterized in that a dispensing sensor ( 18 ) is provided which detects a dispensing signal (z _n ) which indicates a tap of hot water, the dispensing signal (z _n ) is fed to a signal processing unit ( 14 ) which provides the respective dispensing signal (z _n ) Assigns time of day, and the daily program ( 20 ) depends on the tap signal (z _n ). 2. Device according to claim 1, characterized in that the dispensing signal (z _n ) is stored in a daily memory ( 22 ). 3. Device according to one of the preceding claims, characterized in that a probability p (z _{n + 1} ) for a future tap from at least one previous tap signal (z _n-1 , z _n-2 ) and the current tap signal (z _n ) is determined, which influences the daily program ( 20 ). 4. The device according to claim 3, characterized in that the probability p (z _{n + 1} ) for a future tap by averaging from at least one previous tap signal (z _n-1 , z _n-2 ) and the current tap signal (z _n ) is determined. 5. Device according to one of the preceding claims 3 or 4, characterized in that the respective dispensing signals (z _n , z _n-1 , z _n-2 ) with respective weighting factors (G _n , G _n-1 , G _n-2 ) are weighted and the tap signals weighted in this way are added, from which the probability p (z _{n + 1} ) results. 6. The device according to claim 5, characterized in that the respective values of the weighting factors (G _n , G _n-1 G _n-2 ) depend on the respective day (n, n-1, n-2) on which the respective Tap signal (z _n , z _n-1 , z _n-2 ) was detected. 7. Device according to one of the preceding claims 3 to 6, characterized in that the probability P (z _{n + 1} ) of a future tap is compared with a probability threshold (ps), and the control signal (S) is formed as a function of the comparison . 8. Device according to one of the preceding claims, characterized in that the dispensing signal (z _n ) only detects those dispensing processes which do not fall below a minimum duration. 9. Device according to one of the preceding claims 3 to 8, characterized in that a target temperature of the process water depends on the probability p (z _{n + 1} ) of a future tap.