DE1904047A1 - Electric storage heater with controllable dynamic heat output and, by including freely selectable influencing variables, controllable and adjustable heat charging - Google Patents

Description

Electric storage heater with controllable dynamic heat output and through the inclusion of freely selectable influencing variables, controllable and regulatable heat charging The invention relates to an electric storage heater with controllable dynamic heat output and through adaptive inclusion of freely selectable influencing variables, controllable and regulatable Heat charging for the constant provision of thermal energy, e.g. for space heating.

Methods are known that use heavily programmed control the charging of the storage tank mainly in times of low tariff, e.g. at night, or to a lesser extent also during normal tariff times, e.g. during the day, in this way, that the performance time characteristic of the storage device corresponds to the specified program, whereby the charging period itself depends on the storage temperature or heat dissipation to the depends on the medium to be heated.

The individual procedures differ essentially in the Memory types and in the type of memory program.

None of the known methods is able to adaptively different To capture influencing variables at the same time, so that due to the programming a large storage volume is necessary, so also at the end of the discharge period still with certainty the temperature gradient in the storage tank required for heat dissipation is available, especially since a rigidly programmed one due to the prevailing load situation Recharging during the day significantly limits the efficiency.

No control system according to the current status takes this into account Simultaneous situation in the network.

The purpose of the invention is to provide a complex electric storage heating system to create, which under optimal utilization of all essential influencing variables leads to an economical solution with the least economic effort.

In particular, the growing importance of electrical energy is considered Refined form of energy for heating purposes with a small storage volume and variable Connection value taken into account.

Above all, value is placed on the exploitation of existing weak load times placed in the supply network.

The invention is based on the task of having several influencing variables to be recorded simultaneously according to selectable linear or non-linear evaluation and from this to form a control signal which the individual approves as a reference variable and maintenance-free control systems of the storage devices is specified so that a significant reduction due to the dynamic reloading process the storage volume and the connection value is reached.

According to the invention this is achieved in that statically variable or adaptively recorded dynamically changing influencing variables (e.g. outside temperature, Weather, load conditions in the feeding network, program dependency, remote control dependency) to a multi-complex control signal formed in a central unit with for Transmission suitable form, frequency and power are combined, which the connected device outputs depending on the already saved Amount of heat changed continuously in such a way that always an optimal utilization of the momentary given conditions is achieved.

The system consists of several assemblies. The first assembly represents the data collection and evaluation. This group's job is to make out all the essentials Influencing variables that have or should have an effect on the heating, a signal to shape. This signal must exactly match the dependencies of the storage energy correspond to the respective influencing factors.

This is possible by evaluating the influencing factors accordingly. The more precisely the evaluation is adapted to the transfer function for the influencing variables is, the more precisely they are compensated. The evaluation can be linear or non-linear take place.

By suitable selection of the essential compensation for influence any regulation that satisfies the respective response can be achieved. As influencing factors e.g. outside temperature (with one or more measuring points), load situation (e.g.

at the feed point, energy focus), manual control via remote control, (energy supply), time-dependent influence (time of year, Time).

All evaluated influencing variables are converted into proportional direct current signals transformed, which are combined into a signal in a summing element.

In the second module, the DC control signal is converted into a converted to form suitable for transmission. In particular, the equilibrium will flow expensive size through pulse frequency modulation into a frequency proportional pulse train converted, which in turn is a triangular function with constant amplitude and constant rise and fall triggers, creating a triangle burst function, which after mixing with a frequency of e.g. 1 kHz via a power amplifier is coupled to the control line with a connected low-pass filter. In particular are used to convert the DC control variable into the triangular burst function in well-known way connected operational amplifiers combined appropriately.

Further assemblies are in themselves in any number and the same Manned storage units, which are located directly in the area to be heated are arranged. The electrical power of the memory is approximated by a Thyristor zero crossing control steplessly changeable up to the maximum. the The switch-on times of the heating current supply depend both on the core temperature of the storage tank as well as from the one formed in the assembly 2 and via the control line to all Control units distributed control variable dependent. The control of the switch-on times takes place by comparing a signal "like temperature" and the signal of the control line in a diode discriminator whose output signal is used to control the thyristors is fed to the thyristor gates via a transformer. The capture of the Core temperature is, in particular, by a differential transformer, softer from a temperature detection element is changed, possible.

The known one used for this electric storage heating system Storage type has a controllable dynamic heat release, but the power is the storage units can be continuously changed according to the control system and enables an exact adaptation to the respective load situation.

This is an effective charging time over the rigid night charging time given out. The saving in storage material is therefore particularly great. In particular wall mounting is possible due to the small and light construction, to increase of security and convenience, the storage unit is e.g.

with safety temperature limiter and automatically working bypass flap Can be equipped to keep the temperature of the outlet air constant. Because of the The interaction of the control variable and the mains frequency at the thyristor is pulse-shaped HoiSatromserlaures is the application of a storage material with a high heat penetration rate particularly suitable.

1 shows the block diagram of the entire electric storage heating system, Fig. 2: the pulse plan, Fig. 3: the pulse conversion, Fig. 4: the memory unit with thermocouple, Fig. 5: the storage unit with differential transformer.

In blocks 1; 2; 3; 4 are examples of possible wind river sizes shown. 1 is the influence of a remote control of the energy supply, 2 a Mf3 temperature recording, 3 a time program, 4 the load status recording at the entry point. All influencing variables are converted into proportional direct current signals reshaped. These signals are weighted in linear or non-linear terms 5 so that that their course at the output of the members 5 exactly the dependence of the storage energy of the respective influencing factor. The one formed from the sum of all signals The DC control signal is converted into a frequency-proportional one in the voltage-time converter 6 Converted to pulse train. The modulator 7 forms therefrom with a triangular burst function amplitude-modulated 1 kk sine wave. The information content is in the Length of each limited triangular pulse. In the amplifier 8 is the resulting The multi-complex control signal is amplified so that it is transmitted via the lines 9 to all storage devices can be given and on each storage device still the power to control the Thyristors is available. Each storage device consists of the diode discriminator 10, the thyristors 30, the memory 13, the Ileizelemente 11 and the temperature detection device, e.g. the thermocouple 14, which measures the core temperature of the memory. In the discriminator 10, the multi-complex control signal and thermal voltage of the thermocouple 14 compared. The resulting difference signal controls the thyristors 30, which the Electric energy from the network via line 12 to the heating elements 11 rules.

In the timing diagram of FIG. 2, 15 denotes the direct current control signal, 16 denotes the Pulse length modulated signal formed in the voltage-time converter 6, 17 the triangle burst signal, left in the Sigur for higher and right for lower outside temperatures.

18 is the thermal voltage of the thermocouple 14, 19 the control voltage of the thyristors 30, 20 the turn-on curve of the iieizelemente 11, left for lower and on the right for higher core temperatures of the storage tank.

In the connected operational amplifier 21; 22; 23 according to FIG. 3 takes place the voltage-time conversion such that the DC control signal in a sequence is converted by pulses, the spacing of which is proportional to the control voltage.

The implementation takes place in such a way that one has a free-running sawtooth voltage through the operational amplifier 21; 23 compares with the control signal. Achieved the sawtooth voltage is the value of the DC voltage that the sawtooth generator will turn on o is set and an output pulse occurs via the operation amplifier 22. The other Conversion into the triangle burst signal takes place in the connected operational amplifiers 24; 25; 26th

At the output of operational amplifier 24, a is produced with each pulse Saw tooth which is fed to the operational amplifier 25 and the operational amplifier 26 will. By summing the outputs of the operational amplifiers 24; 26 is created after Cut off the desired Draieck burst function with a diode 34.

A 1 generated in a sin generator passes through the diode 35 kHz frequency for mixing at the input of the operational amplifier 25. The output 36 leads to the power amplifier where the signal is at the required power level is reinforced. The triangular amplitude can be set on the potentiometer 37 Potentiometers 38 the sawtooth slopes are set. At the entrance 39 the DC control signal is fed into the circuit.

In the memory unit of FIG. 4, 9 shows the control line, which all Connects storage units to the central unit. The multi-complex control signal is in the diode discriminator, consisting of diode 27, capacitor 28 and transformer 29 compared with the temperature voltage. This arises in the thermocouple 32 with a subsequent amplifier 31. Via the transformer 29, the thyristors 30 controlled, which are connected to the network via lines 12. 33 is the storage unit itself. The combination amplifier 31 and thermocouple 32 is replaceable by a differential transformer controlled e.g. by an expansion rod 40 41 (FIG. 5) with a downstream rectifier 42.

Claims (7)

Claims: 1. Electric storage heater with controllable dynamic Heat emission and controllable and regulatable through the inclusion of freely selectable influencing variables Heat charging, characterized in that statically changeable or adaptively detected dynamically changing influencing variables according to linear or non-linear evaluation according to their influence on the dependencies of the storage energy (e.g. 3rd outside temperature, Weather, load conditions in the feeding network, program dependency, remote control dependency) to a multi-complex control signal formed in a central unit with for Transmission suitable form, frequency and power are combined, which the connected device services of the peripherally arranged individual storage devices Any number depending on the amount of heat already stored continuously changed in such a way that always an optimal utilization of the momentary given conditions is achieved. 2. Electric storage heater according to claim 1, characterized gekenui- shows that the multi-complex control signal is a sinusoidal oscillation with a corresponding one resulting from the summary of all assessed influencing variables DC control signal length-modulated triangular function with constant amplitude and constant rise and fall is used amplitude modulated. 3. Electric storage heater according to claim 1 and 2, characterized in that that the direct current control signal with the aid of the operational amplifiers wired in a known manner (21; 22; 23) into a length-modulated pulse train and then into the connected operational amplifier (24; 25; 26) transformed into the desired triangular burst function in an amplitude-modulated manner will. 4. Electric storage heater according to claim 1 and 2, characterized in that that the multi-complex control signal in the discriminator circuit, consisting of Diode (27), capacitor (28), transformer (29) with the amplifier (31) amplified, in the thermometer (32) measured core temperature proportional direct current signal compared and the resulting difference signal is used to control the thyristors (30) which control the heating current to the heating elements (33). 5. Electric storage heater according to claim 1 and 4, characterized in that that the combination of amplifier (313 and thermometer (32) is replaced by one adjustable differential transformer (41) with the following Alignment (42). 6. Electric storage heater according to claim 1, characterized in that that metallic materials can also be used economically as storage material. 7. Electric storage heater according to claim 1, characterized in that that any number of simple, maintenance-free control systems on storage devices a central complex data acquisition and evaluation system can be replaced. Blank page