RU2011126003A - METHOD FOR REDUCING MINIMUM ENERGY CONSUMPTION IN A WATER HEATER WITH A HEAT BATTERY - Google Patents

Abstract

1. A method for controlling a water heater (1) with a heat accumulator, in which water is heated by a heating element (3) controlled by a regulator (4) capable of bringing the water temperature (T) to a variable target temperature (T), and which includes: the first stage , on which the data of the water intake profile is recorded, repeating mainly without changes during subsequent water intake cycles, and data on the heating rate (VT) typical for the water heater (1), the second stage, at which, before the moment (t) of the start of each intake ( P) from all n water intakes (P) included in each of the water intake cycles, bring the water temperature (T) to at least an intake temperature (T; T') sufficient to ensure said water intake at the consumption temperature (T) by starting heating at the time (t; t'), provided that in any case the temperature (T) of the water is maintained below or equal to the maximum set temperature (T) with a value below the dangerous level, while the said temperature (T; T') of the intake and the time (t; t') of the start of heating is determined on the basis of the recorded data, characterized in that the recording of the data of the water intake profile is carried out at least during the training cycle of the water intake and consists in calculating the start time (t) and the corresponding decrease in temperature (ΔT) for each of the n samplings (P), while such a calculation is carried out only by processing data obtained by measuring the moment (t, t) in time and estimating the temperature (T) of water, which is the average of one or more temperatures (T , T1, T2) measured at different heights (S, S1, S2) of the tank (2).2. Water heating control method

Claims (31)

1. A method for controlling a water heater (1) with a heat accumulator, in which the water is heated by a heating element (3) controlled by a controller (4), capable of bringing the temperature (T _m ) of the water to a variable target temperature (T _target ), and which includes: the first stage, which records the data of the profile of water intake, repeating mainly without changes during subsequent cycles of water intake, and data of the rate (VT _h ) of heating, typical of a water heater (1), the second stage, at which, before the moment (t _k ) of the beginning of each intake (P _k ) of all n withdrawals (P _n ) of water included in each of the cycles of water intake, the temperature (T _m ) of the water is brought to at least the temperature ( T _set.k ; T ' _set.i ) a sufficient intake to ensure the mentioned water intake with a temperature (T _u ) of consumption by starting heating at the moment (t _ONk ; t' _ONi ), provided that in any case the temperature (T _m ) the water is maintained below or equal to the maximum set temperature (T _set.max ) with a value below the dangerous level, while the temperature the round (T _set.k ; T ' _set.i ) of the intake and the moment (t _ONk ; t' _ONi ) of the start of heating are determined based on the recorded data, characterized in that the registration of the water intake profile data is carried out at least during the training cycle of water intake and consists in calculating the moment (t _k ) of the beginning and the corresponding decrease in temperature (ΔT _k ) for each of n fences (P _k ), while the calculation is carried out only by processing the data obtained by measuring the time (t, t _c ) time and estimating the temperature (T _m ) of water, which is the average of one or more temperatures (T, T1, T2), measured at different heights (S, S1, S2) tank (2). 2. The method of controlling the water heater (1) according to claim 1, characterized in that the intake (P _k ) of water is considered started if the first and second conditions are successively fulfilled, according to the first condition, at the time (tc) of the time at the end of the sampling interval (δt _c ) it is noted that the temperature (T _m (t _c )) of the water recorded at the mentioned time (t _c ) has decreased relative to the value of (T _m ( t _c -δt _c )), recorded at the previous moment (t _c -δt _c ), by an amount greater than or equal to the specified first value of the decrease (δT _p1 ) in temperature, that is, the condition

, said temperature reduction amount (δT _p1 ) is selected so as to prevent cooling due to heat dissipation, according to the second condition, the verification of the fulfillment of the first condition continues until the temperature (T _m ) decreases by a predetermined second value (δT _p2 ) of reduction, which is selected so as to exclude the fulfillment of the first condition due to small water withdrawals or temperature control, which are undesirable to take into account. 3. The method of controlling the water heater (1) according to claim 2, characterized in that the sampling interval (δt _c ) is 60 s, and the first temperature reduction value (δT _p1 ) is 0.33 ° C. 4. The method of controlling the water heater (1) according to claim 2, characterized in that the second value (δT _p2 ) of reduction is from 4 to 13 ° C. 5. The method of controlling the water heater (1) according to claim 4, characterized in that the second reduction value (δT _p2 ) is 6.5 ° C. 6. The method of controlling the water heater (1) according to any one of claims 2-5, characterized in that the pre-emptive interval (δt _adv ) is preceded by the time (t _k ) of the start of each water intake (P _k ) relative to the time (t _c ) time the first condition is satisfied, or in the formula expression

. 7. A method for controlling a water heater (1) according to any one of claims 2-5, characterized in that for determining the value (T _set.k ) of the temperature of water intake, the following steps are carried out, in which: save the temperature T _m (t _c -δt _adv ) recorded at the time (t _k ) of the start of the fence, as the initial temperature (T _mik ) of the fence, keep the temperature recorded at the moment when the temperature (T _m ) of the water stops decreasing, that is, at the moment when the condition ceases to be fulfilled

, as the final temperature (T _mfk ) of the fence, if one or more sensors (S; S1, S2) are located near the bottom (2.3) of the water heater (1), check whether the final intake temperature (T _mfk ) is below a predetermined boundary value (T _s ; T _opt ), take the decrease (ΔT _k ) of the temperature (T _m ) of the water for the value of the difference between the initial and final temperatures (T _mik , T _mfk ) of the intake, if one or more sensors (S; S1, S2) are located near the bottom (2.3), and the final temperature (T _mfk ) of the fence is lower than the set limit value (T _s ; T _opt ), the decrease value (ΔT _k ) temperature by introducing a correction term (ΔT '' _k ), determined empirically for each model of water heater (1) and the corresponding type of water supply system, determine the temperature (T _set.k ) of water intake by summing the value of the decrease (ΔT _k ) in temperature, which is optionally adjusted as described above, and the optimal temperature (T _opt ) for emptying. 8. The method of controlling the water heater (1) according to claim 7, characterized in that the boundary value (T _s ; T _opt ) is from 20 to 30 ° C, and the correction term (ΔT '' _k ) is equal to the decrease (ΔT _k ) of the temperature by 50%. 9. The method of controlling the water heater (1) according to claim 7, characterized in that the boundary value (T _s ; T _opt ) is equal to the optimum emptying temperature (T _opt ), and the correction term (ΔT '' _k ) is equal to the difference between the optimal temperature ( T _opt ) emptying and final temperature (T _mfk ) of water intake. 10. The method of controlling the water heater (1) according to claim 7, characterized in that the proactive interval (δt _adv ) is from 0 to 180 seconds. 11. The method of controlling the water heater (1) according to claim 7, characterized in that the proactive interval (δt _adv ) is equal to the interval (δt _c ) of the sample. 12. The method of controlling the water heater (1) according to any one of claims 1-5, 8-11, characterized in that the registration of the heating rate (VT _h ) is carried out at least during the training cycle of water intake during the period when the temperature (T _m ) the water rises continuously, and involves the stages at which: register the value (T _m1 ) of the temperature (T _m ) of water at a given point in time, register the value (T _m2 ) reached by the temperature (T _m ) of the water after a predetermined measurement interval (Δ _t ), calculate the value of the speed (VT _h ) heating according to the formula

. 13. The method of controlling the water heater (1) according to claim 12, characterized in that the registration of the heating rate (VT _h ) is repeated whenever the controller (4) drives the heating element (3). 14. The method of controlling the water heater (1) according to claim 12, characterized in that the recording of heating speed (VT _h ) data is continuously repeated when the heating element (3) is turned on at intervals equal to a predetermined measurement interval (Δt). 15. The method of controlling the water heater (1) according to claim 12, characterized in that the predetermined measurement interval (Δt) is 15 minutes. 16. The method of controlling the water heater (1) according to claim 12, characterized in that the registration of the heating rate (VT _h ) is also carried out during the water intake cycle following the training water intake cycles. 17. The method of controlling the water heater (1) according to any one of claims 13-16, characterized in that the successively calculated values of the heating rate (VT _h ) are re-processed to reduce the degree of discrepancy between them. 18. The method of controlling the water heater (1) according to claim 17, characterized in that the value taken as the heating rate (VT _h ) is set equal to the moving average of a predetermined number of the last calculated values. 19. The method of controlling the water heater (1) according to claim 17, characterized in that the value taken as the heating rate (VT _h ) is the last result obtained in chronological order, filtered using a time constant (τ), preferably equal to one and a half hours, in this case, a recursive type filter (IIR) is used as a filter. 20. The method of controlling the water heater (1) according to any one of claims 1-5, 8-11, 13-16, 18, 19, characterized in that when determining the moment (t _ONk ; t ' _ONi ) of the start of heating to provide fences ( P _k ; P _i ) water is carried out at the stage at which: at short time intervals (δ _w) account for all w fences (P _1, ... P _i, ..., P _w), the time (t _i) the beginning of which have a predetermined time window (Δt _w), immediately following the current time point while the time window (Δt _w ) is selected based on the type of water supply system for which the water heater is designed (1), and is sufficiently long to include the moment (t _i ) of the beginning of all fences (P _i ) whose moments (t ' _ONi ) the beginnings of imaginary heating are presumably preceded by moments (t ' _ON ) that correspond to (i-1) preceding their fences (P ₁ , ..., P _i-1 ), at the mentioned moment (t _w ) the beginning of the fence falling on the time window (Δt _w ), the same number of imaginary fences (P ' ₁ , ..., P' _i , ..., P ' _w ) are constructed, each of which has the same moment ( t _w ) of the beginning, as well as the moment of the beginning of the corresponding real fence (P _i ), and the initial temperature (T ' _set.i ) of the imaginary fence, determined by adding the initial temperatures (T _set.1 , T _set.2 , ..., T _{set . (i-1)} ) of all water abstractions falling on the time window (Δt _w ) and preceding the abstraction (P _i ), and the corresponding initial temperature (T _set.i ) of the actual abstraction, based and which was determined by each of the initial temperatures (T _set.1 , T _set.2 , ..., T _{set. (i-1)} ) of the optimal temperature (T _opt ) emptying according to the formula

for each of the imaginary fences (P ' ₁ , ..., P' _i , ..., P ' _w ) calculate the moment (t' _ONi ) of the beginning of the imaginary heating according to the formula

, upon reaching the earliest of the times (t ' _ONi ) of the start of heating, set the target temperature (T _target ) at the initial temperature level (T' _set.i ) of the corresponding imaginary fence (P ' _i ), it being understood that the upper limit of said target temperature (T _target ) is the maximum set temperature (T _set.max ), and until the earliest point (t ' _ONi ) is _reached, the heating start is maintained at a temperature (T _target ) equal to the maintenance temperature (T _stand-by ). 21. The method of controlling the water heater (1) according to claim 20, characterized in that the short time intervals (δ _w ) are 60 s. 22. The method of controlling the water heater (1) according to claim 20 or 21, characterized in that, with a weekly duration of the water intake cycle, the length of the time window (Δt _w ) is 24 hours. 23. The method of controlling the water heater (1) according to claim 22, characterized in that the moments (t ' _ONi ) of the start of heating are preceded by an allowable lead (Δ _to1 ) to take into account the discrepancies between the actual moments (t _i ) of the start of water intake and the moments recorded in water intake training cycle time. 24. The method of controlling the water heater (1) according to claim 23, characterized in that the registration of the water intake profile continues during the water intake cycles following the first training cycle, and during the water intake cycles following the first training cycle, training is allowed lead (Δ _to1 ). 25. The method of controlling the water heater (1) according to claim 7, characterized in that, for a weekly duration of the water intake cycle at the beginning of each day following the first day, the initial set value (T _set ) of the water intake temperature is reduced or increased by a maximum of 3 ° C to bring it closer to the maximum value of the fence temperature stored the day before (T _set.g ). 26. The method of controlling the water heater (1) according to claim 20, characterized in that the maintenance temperature (T _stand-by ) is equal to the consumption temperature (T _u ). 27. The controller (4) of the water heater (1), comprising: means (IN, IN.1, IN.2, IN.3) of entering into it from the outside the first data at the manufacturing stage and (or) after installation and (or) later by the water user, means (IN, IN.4) for entering into it second data (T, T1, T2) of the temperature of the water heated in the tank (2) and recorded by one or more sensors (S; S1; S2), memory (MEM) for storing the first data received from the outside, second data received from one or more sensors (S, S1, S2), as well as additional parameters that are processed based on the first and second data, a processing unit (UE) for processing the first and second data in order to determine the parameters, a timer (CLOCK) for associating at least some of the parameters with the corresponding time points, first means (U1) for transmitting the output signals of the on-off or stepless control of the heating element (3), any second means (U2) for transmitting the output signals of the state of the system to the water user and (or) the operator, for recording data of their processing and regulation of the heating element (3) by methods according to one or more of claims 1-12. 28. A water heater (1), comprising: the regulator (4) according to claim 27, the heating element (3), one or more sensors (S; S1, S2) for recording temperatures (T, T1, T2) inside the tank (2), to perform methods according to one or more of claims 1 to 11. 29. The water heater (1) according to claim 28, characterized in that one or more sensors (S; S1, S2) are the only sensor (S; S1), which is located where the thermal relay sensor of the prior art water heater is usually located (one). 30. The water heater (1) according to claim 28, characterized in that the water heater (1) is a standard model, and one or more sensors (S; S1, S2) contain the first and second sensors (S1, S2), respectively, which placed at a distance of about 30 mm and about 230 mm from the bottom (2.3). 31. The water heater (1) according to claim 28, characterized in that it uses more than two sensors (S; S1, S2), which are distributed in such a way as to determine, with a certain accuracy, the temperature change circuit (T, T1, T2) according to vertical axis.