DE10129480A1 - Method by which the thermal charging of electric storage heaters is determined, has inputs from the previous discharging cycle and other relevant parameters - Google Patents

Abstract

The thermal loading of the heat storage medium in an electric thermal storage heater is determined with reference to the delivery fan rotation speed, difference between actual and reference room temperature and adjustment for predicted variations.

Description

The invention relates to a method for charging the Storage core of an electric storage heater, in which during a Discharge cycle the discharge of the memory core in a dynamic Discharge state by a fan running at a variable speed generated air flow takes place and wherein the fan run by a with a Room temperature sensor provided discharge controller is controlled.

Such methods are used for charging controls in electric storage furnaces DIN 54 574 used. In the known charging regulations is in Storage core provided a temperature sensor that the residual heat of the Memory core recorded, also internal charging setpoint and weather-based charging controls known.

The known solutions and methods for charging the memory core of Electric storage ovens are relatively complex. The core of the temperature sensor requires separate wiring measures, setpoint devices require additional ones Wiring effort, also weather-dependent Charging controls required.

The invention has for its object a method for needs-based Charge the storage core of an electric storage heater to specify the is easier to use, easier to install and cheaper to manufacture. This task is accomplished by a process with the characteristic features of claim 1 solved. Advantageous further developments of the method result deriving from subclaims 2-12.

It is regarded as the essence of the invention to use the method without using a Carry out charging setpoint generator and / or core temperature sensor can and the last discharge cycle from the electric storage heater dissipated amount of heat from fan speed, fan running time and sensor temperature to investigate. These quantities if necessary with a calculation of the nuclear radiation in the static condition give the possibility of charging for a following Charge cycle to calculate. However, the use of the invention excludes that additional installation of a charging setpoint generator is not sufficient, that of some Users as an option. Unlike known methods, which are based on relatively rigid conditions, it is the inventive Process possible, the core charge independently on the actual Adjust the heat requirement of the heated room. The process also learns from the heating habits of the residents and the respective use of the rooms, depending on how the heat from the Furnace is delivered. After-heating according to requirements ensures that that - a certain continuity in space use and space heating provided - sufficient heating power of the heater is ensured. The static discharge of the memory core can also be taken into account proportionately become.

The measured values of the fan speed, the fan running time and the sensor temperature can be stored and / or in the process over several discharge cycles be averaged. This creates a user profile of the oven over a longer period Period created that can serve as the basis for the respective nuclear loads. Changes to lower or higher room temperatures on one Setpoint sensors of the room temperature controller can be used to determine the Charge level in the sense of an increase or decrease in the charge level be taken into account.

In an advantageous further development, the method also provides one from a utility company Predefined, standardized charging model from a measurement of the release signal remote charging within 24 hours. It is important here that the electrical connected load of the heating elements and the memory core volume are adjusted so that for device series with Charging setpoint and / or core probe to be able to perform different memory sizes, the same loading times are required. Some RUs deviate from this standard regulation and require that the connected load is reduced with the same memory size, which is a Extension of charging time required. Usual loading time models are the model 8 + 0, which assumes a charging time of 8 hours. This Standard charging model is used by the utility companies to about 50%. For example has a storage heater with 4 kW connected load after 8 hours Heat quantity of 32 kWh saved. A charging model with reduced Connected load (only 3.2 kW connected load) goes from 8 + 2 hours Charging time off, another charging model assumes a total charging time from 12 hours and comes with a connected load of 2.66 kW. I.e. 32 kWh are stored in 12 hours. This model will referred to as 8 + 4 model. Finally, an 8 + 6 model is common, that provides a charging time of 14 hours, with a connected load of 2.3 kW a heat quantity of 32 kWh is stored in 14 hours.

A limitation is required for all charges, on Safety temperature limiter limits charging at approx. 120% and switches off the core heating permanently if this charge value reaches or is exceeded.

Is a device that works according to the inventive method for the first time installed, there is of course no "last discharge cycle" available as Calculation basis for the charge level could serve. For this case additionally provided that the heat requirement of the position of the setpoint generator of the room temperature controller is derived. E.g. can be provided that in a frost protection position (setpoint generator on lower stop) the charge level of the electric storage furnace is only 30% of the maximum nuclear charge. Becomes a "comfortable" room temperature set, which can be around 20 ° C, there is a charge when charging full charge of the memory core.

In an advantageous development of the method it is provided that depending on the setpoint generator or changes to the setpoint generator during a Discharge cycle of 24 hours by measuring the room temperature gradient it is checked whether the room temperature values set on the setpoint device can be met. Alternatively, it can also be provided that Fan speed gradients in the final phase of the discharge cycle and then check whether the set room temperature values are maintained can be. The fan speed runs up to one at the end of the discharge cycle maximum speed high, this is an indication that the core is largely discharged.

If this is established, the setpoint of the Room temperature are automatically lowered so that for the rest Discharge time, the room temperature can be kept at a reduced value can. This advantageously avoids that the temperature against End of the discharge cycle drops to a relatively low room temperature.

Alternatively and / or in addition, it can also be provided that the Memory core existing residual heat value by comparing the stored To determine the amount of heat and the amount of heat given off. The saved The amount of heat results from the original charging time and the associated charge Charging model, the amount of heat emitted can be easily removed Fan speed, proportional fan runtime, static discharge and / or Determine sensor temperature.

Finally, it can be provided in an advantageous manner Setpoint increases in the room temperature on the setpoint generator for one already automatically determine the shortage of residual heat determined or not and when charging the memory core afterwards to consider charge increasing.

The invention is based on exemplary embodiments in the drawing figures explained in more detail. These show

Fig. 1 is a schematic representation of the essential components of a storage heater with integrated discharge controller with additional heating and selbstlerndender charging,

Fig. 2 is a flowchart showing a self-learning charging without core sensor and charging setpoint generator.

The storage heater designated as a whole 1 has a connecting switch strip 2 , heating circuits 3 for heating a storage core (not shown in more detail), an electronic discharge controller 4 with a setpoint generator 5 connected thereto and a plurality of thermal relays 6 , 7 , 8 .

The heating circuits are also connected via a safety temperature limiter 9 , which is provided with a thermal sensor 10 on the storage core in order to avoid overheating of the storage core.

The essential components of the discharge controller 4 are a power supply unit 15 , a triac circuit 16 for a fan motor 17 , a relay 18 for an additional heater 19 , a relay 20 to switch the thermal relay 6 for the heating circuits, a room temperature sensor 21 and a microprocessor 22 which is connected to components 15 , 16 , 18 , 20 and 21 .

The inputs of the discharge controller 4 are assigned as follows
L phase: 24 hours (mains supply is constantly on)
L phase: for additional heating (neutral phase)
L2 phase: for charging (neutral phase)
LF signal: (neutral phase) for enabling the additional heating
LA signal: (neutral phase) for releasing the core charge
N: neutral conductor
SA: function decoding (temperature reduction with neutral phase)
P1: Setpoint room temperature potentiometer
P2: Potentiometer setpoint temperature
P3: Potentiometer setpoint temperature
LX: signal (neutral phase for release of discharge) (remote control)

The outputs are assigned as follows
LH: Relay output for additional heating
LT: Relay output for thermal relay
LE: Fan motor output

The microprocessor is used to control proportional fan control, such as it is known in the prior art, with a starting pulse and for driving through of a proportional control band, it generates variable fan voltages, defined a switch-off and switch-on threshold, controls a temperature reduction, controls the core charge the charge release, monitors the sensor diagnosis and includes the self-learning charging control according to the present Invention.

Since the microprocessor regulates the fan speed, switches the fan running time and is connected to the room temperature sensor 21 , it is able to determine the amount of heat dissipated from the fan speed, fan running time and sensor temperature. The microprocessor also has a memory so that the measured values of the fan speed, fan running time and the sensor temperature can be saved over several discharge cycles. Since the microprocessor is supplied with the release signals for core charging, ie the operation of the heating circuits 3, via the input LA, it is able to define a standardized charging model specified by a power supply company and to include it in the calculation of the amount of heat stored in the core.

If "discharge experience values" are not yet available because the electric storage heater 1 is newly installed, the heat requirement is derived from the position of the setpoint generator 5 , which is connected to the discharge controller 4 via the inputs P1, P2 and P3.

The device according to the invention can be designed in different ways. On the one hand, it is possible to design the charge controller and the discharge controller in an integrated manner, ie the charge controller and the discharge controller are combined in one module. However, there is also the possibility of designing the charge controller and discharge controller as separate modules and, if necessary, connecting them to one another so that the signals can be transferred from one module to the other module. A third possibility is to provide the charge control for older devices as a retrofittable, separate module which is adapted to the connections of the existing electronics of the storage furnace and can optionally also be attached externally. REFERENCE LIST 1 storage device
2 terminal block
3 heating circuits
4 discharge regulators
5 setpoint adjuster
6 thermal relays
7 thermal relays
8 thermal relays
9 safety temperature limiter
15 power supply
16 triac circuit
17 fan motor
18 relays
19 Additional heating
20 relays
21 room temperature sensors
22 microprocessor

Claims (13)

1. A method for charging the storage core of an electric storage heating device as required, in which during a discharge cycle the storage core is discharged in a dynamic discharge state by an air flow generated by a fan running at a variable speed and the fan running is regulated by a discharge controller provided with a room temperature sensor, characterized in that the amount of heat dissipated in a last discharge cycle is determined from the fan speed, the fan running time and the sensor temperature, and the degree of charging for the following charging cycle is calculated from the result of this determination. 2. The method according to claim 1, characterized in that the measured values of the fan speed, fan running time and sensor temperature several discharge cycles can be saved and / or averaged. 3. The method according to claim 1 or 2 characterized in that depending on the temperature detected by the room temperature sensor Discharge of the memory core determined in the static operating state and for the subsequent charging is taken into account. 4. The method according to any one of the preceding claims, characterized in that Changes to lower or higher room temperatures on one Setpoint generator of the room temperature controller for determining the Charge level in the sense of an increase or decrease in the charge level be taken into account. 5. The method according to any one of the preceding claims, characterized in that a standardized charging model from a Measurement of the release signal of the nuclear charge within one Period of 24 hours is determined. 6. The method according to claim 5, characterized in that Periods of multiple release signals within a period of 24 Hours added and from the total time span of the Release signals the EVU-predetermined charging model is determined. 7. The method according to any one of the preceding claims 4-6, characterized in that the first time the heat is required from the position of the Setpoint generator is derived. 8. The method according to claim 7, characterized in that after a frost protection setting of the setpoint generator, the degree of charging is about 30% of the maximum nuclear charge. 9. The method according to any one of the preceding claims, characterized in that with a setpoint setting of about 20 °, a complete parameterisable The memory core is charged. 10. The method according to any one of the preceding claims 4-9, characterized in that depending on the setpoint generator or change on the setpoint generator during a 24 hour discharge cycle by measuring the Room temperature gradient is checked whether the on the setpoint set room temperature values can be maintained. 11. The method according to claim 10, characterized in that if an insufficient amount of heat is found in the storage core The setpoint of the room temperature is automatically reduced in such a way that for the remaining discharge time the room temperature on the lowered value can be held. 12. The method according to any one of the preceding claims, characterized in that the residual heat value in the storage core by comparing the stored amount of heat determined with the given amount of heat becomes. 13. The method according to any one of the preceding claims, characterized in that Setpoint increases in the room temperature at a determined Undercoverage of the residual heat quantity is automatically reduced and at one subsequent charging of the storage core increases the charge be taken into account.