DE10110288B4 - Method for room temperature control using an electric storage oven provided with a blower - Google Patents

Abstract

method for room temperature control by means of a fan Electric storage oven, the room temperature being fixed in or on the oven housing Room temperature sensor is detected, the one with the fan run controlling electronic circuit cooperates and for which The fan comes to a standstill results in a different ambient temperature than with a fan run, with a falsification the room temperature measurement is connected by compensation the one coming from the room temperature sensor readings considered is, with respect to a blower on or off in each case a first time period t1, t3 with respect to those coming from the room temperature sensor readings detected and is stored in which the ambient temperature detected by the room temperature sensor remains essentially constant and a second period in each case t2, t4 is recorded with regard to the measured values coming from the room temperature sensor, in which the ambient temperature detected by the room temperature sensor drops or increases and the compensation automatically by means of the stored values the adulterated Raumtemperaturmeßwerte he follows.

Description

The The invention relates to a method for controlling room temperature one with a blower provided electric storage furnace with the further features of the claim 1.

The room temperature of rooms heated via an electric storage oven is recorded via room temperature sensors which, in known device types, are either arranged separately in the room, for example on a wall, or are fastened directly to or in the oven housing, for example from DE 34 27 523 C2 is known.

at such an integrated arrangement of the room temperature sensor, the with one the fan run controlling electronic circuit of the electric storage furnace interacts, is a change of the electrical output signal of the room temperature sensor observe depending on whether the storage stove is in a dynamic Condition (blower running) or is in a static state (fan is stationary) because in static Condition of the sensors integrated on or in the furnace housing the nuclear charge radiation is more or less heated. at Switching to the dynamic state becomes this radiation effect reduced or canceled so that the room temperature sensor in measures different temperatures in the two operating states mentioned.

From the above DE 34 27 523 C2 it has already become known to compensate for the output signal of the room temperature sensor depending on the particular operating state of the oven, ie to lower or raise it electronically as required.

This Known electronic compensation methods have proven to be extremely advantageous proven to be about temperature drifts in the room that go beyond the comfort zone to be avoided, which can be triggered by different furnace operating states, but they must be compensated temperature jumps depending on the type and performance of the storage heater and installation position of the integrated Room temperature sensor on or in the furnace housing different so that for each oven an individual adjustment of the degree of compensation is required is. This is labor intensive and only by trained personnel feasible if an optimal compensation setting should be found.

Out DE 42 26 383 C2 A measuring and control method for an electronic two-point or proportional control device has already become known, the sensor of which has no access to the controlled variable due to external influences during a timeout specified by the device, and that during a control time by determining the actual value of the controlled variable by the Sensor regulates to the target value of the controlled variable.

The The invention has for its object a method for room temperature control to train such that individual Settings of the degree of compensation based on the structural conditions of the respective electric storage stoves are no longer required. This task is accomplished through the combination of the features of claim 1 solved. Advantageous further training result from the subclaims 2 - 6.

It is initially considered to be the essence of the invention to analyze the deviations in the ambient temperature of the room temperature sensor that occur after the fan has been switched on and off, to save the analysis result and to automatically take into account the values that are preferably stored over several cycles, with reference to on a fan switch-on or switch-off, a first time period t ₁ , t _{3 is recorded} and stored, in which the ambient temperature detected by the room temperature sensor remains essentially constant and a second time period t ₂ , t ₄ is recorded each time the fan is switched on and off in which the ambient temperature drops or rises. This procedure enables self-learning compensation, using a suitable processor, such as is used to control modern storage heaters, it is possible to set up a control program that detects the upward and downward temperature jumps when the operating state changes, so that they can be taken into account in subsequent changes in operating status. In a particularly advantageous manner, it is possible to compensate for the abrupt sensor behavior and to determine an optimal value for the compensation, without the need for separate, manual adjustment processes. The control program of the storage heater automatically adjusts the necessary compensation to the conditions of the room and the structural conditions of the storage heater and takes into account how much the integrated room temperature sensor is affected by the furnace conditions.

In the process, the amplitude of the deviations in the ambient temperature of the room temperature sensor is first analyzed and stored electrically. This makes it possible for him optimize the required degree of compensation.

There the time course of the deviations in the ambient temperature of the Room temperature sensor is also analyzed and stored, it is possible for compensation to take into account the fact that the ambient temperature when the operating state changes not immediately after and not like a staircase function drops or increases, but initially remains constant for a while and only then with a certain one Incline rises or falls to a stable value.

Especially accurate results for the compensation can then advantageously be determined if a plurality of deviations in the ambient temperature of the Room temperature sensor time history and amplitude are stored and a weighting or the values are averaged.

It is advantageously possible a new storage of the deviations of the ambient temperature of the room temperature sensor constantly make, d. H. a certain number of cycles the values are saved hold and, for example, the last ten saved Use values for averaging. With a new operating cycle new values are then recorded, stored and for that the oldest of, for example, ten values deleted. It goes without saying it also possible a larger one or smaller number of stored values for averaging or weighting consulted.

A There is a new storage of the deviation of the ambient temperature of the room temperature sensor especially useful if z. B. changes the nuclear charge of the electric storage furnace or a new set room temperature is set on a setpoint device becomes.

All in all It is the task of electronic compensation to deviate from the from the room temperature sensor when the operating state changes, the temperatures initially measured exactly to determine and then compensate so that the room temperature value apparently remains constant so that the room temperature control does not require post-heating of the room caused because supposedly a drop in temperature the room temperature sensor is detected.

The Invention is based on exemplary embodiments closer in the drawing figures explained. This demonstrate:

1 a schematic representation of the deviations in the ambient temperature of the room temperature sensor based on the two possible operating states "fan off" (static) and "fan on" (dynamic) and

2 a flow chart to explain the essential processes in self-learning compensation as part of the room temperature control.

In drawing figure 1 is with graph 1 first the operating state of the fan motor is shown on the time axis, at 1a the fan motor is switched off at 1b switched on. The graph 2 shows the changes in the output signal ΔT at the room temperature sensor. The output signal initially remains essentially constant for a period of time t ₁ after the fan motor has been switched on and then falls to a value during a period of time t ₂ 2 B that it maintains a period of time t ₃ after the fan motor has been switched off, and returns to the value during a period of time t ₄ 2a to increase. The amplitude of the fluctuation of the output signal can have a value .DELTA.t ₁ after switching on, which does not necessarily have to be equal to the value .DELTA.t ₂ by which the output signal rises again after switching off the fan motor because, for example, between the falling and the rising Core charge of the electric storage heater may have changed or a new setpoint for the room temperature has been set.

According to the method, the time intervals t ₁ , t ₂ , t ₃ , t ₄ and the amplitude fluctuations ΔT ₁ and ΔT ₂ are now recorded and stored for each cycle.

How z. B. can be proceeded from the flow chart according to 2 ,

Since the self-learning compensation only represents a part of the entire room temperature control program, this is due to a control program 10 first an input signal 11 which already takes other, rule-relevant variables into account.

With 12 are now the setpoint of the room temperature, with 13 the nuclear charge and with 14 z. B. the actual value of the room temperature is taken into account.

The output signal of the control program is then used to decide whether the fan switches to a dynamic operating state ( 16 ) or not ( 17 ). Depending on the respective operating status, is now at 18 an analysis of the temperature jump made on the temperature sensor, with 19 the periods t ₁ - t ₄ are recorded and with 20 the temperature jumps ΔT ₁ and ΔT ₂ . According to 21 If a temperature change occurs, these temperature changes are stored and compensation data is determined, whereby according to 23 also be it is taken into account whether operating parameters change or not. If at 23 When external functions are mentioned, predetermined parameters such as a basic parameterization can be taken into account here, for example a temperature jump determined by an empirical value, e.g. B. 2.5 ° C then by the compensation only relatively slightly on z. B. 2.9 ° C must be adjusted.

The automatically determined compensation value is at 24 and can be saved in the input values of the control program 11 received.

Claims (6)

Method for room temperature control using one with a blower provided electric storage furnace, the room temperature via an im or on the furnace housing attached room temperature sensor is detected, the one with the fan run controlling electronic circuit interacts and for the when the fan is at a standstill results in a different ambient temperature than with a fan run, with a falsification the room temperature measurement is connected by compensation the one coming from the room temperature sensor readings considered is, with respect to a blower on or off in each case a first time period t1, t3 with respect to those coming from the room temperature sensor readings detected and is stored in which the ambient temperature detected by the room temperature sensor remains essentially constant and a second period in each case t2, t4 is recorded with regard to the measured values coming from the room temperature sensor, in which the ambient temperature detected by the room temperature sensor drops or increases and the compensation automatically by means of the stored values the falsified room temperature readings take place. Method according to one of the preceding claims, characterized characterized that a Majority of deviations in the ambient temperature of the room temperature sensor (temporal Course and amplitude) and a weighting and / or The values are averaged. Method according to one of the preceding claims, characterized characterized that a The deviations in the ambient temperature of the room temperature sensor are constantly saved. Method according to one of the preceding claims, characterized characterized that a New storage of deviations in the ambient temperature every time then occurs when the operating parameters of the electric storage furnace change. Method according to one of the preceding claims, characterized characterized that a New storage of the deviation of the ambient temperature of the room temperature sensor every time then occurs when the core charge of the electric storage furnace changes. Method according to one of the preceding claims, characterized characterized that a New storage of deviations in the ambient temperature every time then occurs when a new set room temperature is set on a setpoint device becomes.