DE1765961B2 - Electronic charge control suitable for at least one electric storage heater - Google Patents

Description

Electric storage heating inserts are used during off-peak times, for example During the night, electrical energy in the form of heat is available at a low tariff so that it can be used for room heating during high tariff times, for example during the day can be. The charging of a storage heater during each low tariff period must be dependent on controlled by the outside temperature, so in times with relatively high outside temperatures not uselessly much energy is stored

The invention relates to an electronic charge control device, the for at least one electric! Storage heater is suitable and the daily shift at least one charging period causes the end of a low tariff period (time-shifting Charge control device). This electronic charge control device also includes a Switching amplifier and a temperature-dependent resistor, which is influenced by the outside temperature is exposed.

The postponement of the start of the charging time is desirable because the storage heater is charged If possible, it should not end until the end of the low tariff period, so that the period of time from the end charging until the end of the low tariff period, in which the storage heater through its insulating jacket uselessly a portion of it releases stored heat, is as short as possible.

An electronic charging device with shifting a charging period against that The end of a low tariff period is known (German Auslegeschrift 1250027). It contains a DC voltage measuring bridge with an outside temperature dependent resistance and a variable resistance, whose resistance value is changed by an electric clock during the low tariff period. In the measuring diagonal (zero branch) of the DC voltage measuring bridge is a switching amplifier that switches on the electric heater that charges the electric storage heater causes when the bridge imbalance of the DC voltage measuring bridge is a certain amount, namely exceeds the response threshold of the switching amplifier. By applying them together the external temperature-dependent resistance and of the adjustable resistor in the DC voltage measuring bridge is achieved that the Charging of the storage heater starts later within the low tariff period, the higher the Outside temperature. Such a postponement of the start of charging towards the end of a low tariff period is possible because the remaining from the beginning of the charging period to the end of the low-start period The higher the outside temperature, the shorter the charging time.

The known electronic charge control device described is like all other charge control devices with postponement of a charging period towards the end of a low tariff period with a clock or another engine. This represents a significant cost factor, which comes in the order of magnitude of the entire remaining charge control device without the clock. The watch therefore represents a considerable burden for the buyer of such a charging control device, which is why such charging control devices have only prevailed to a limited extent so far could, namely in particular in heating systems with a large number of storage heaters.

The object of the invention is to make the electronic charging control device referred to above cheaper and simplify. The object is achieved according to the invention in that the in the electronic Charging control device included switching amplifier with an electrical charge storage device so electrically is linked to the onset of charging

of the storage heater is effected when the charging or discharging current or the voltage of the electrical charge storage device represents the response threshold of the switching amplifier Value exceeds or falls below the value, with circuitry ensuring that the temperature dependency of the outside temperature contained in the electronic charge control device pending resistance either that stored by the charge store or the maximum that can be stored Charge or the response threshold of the switching amplifier or the charging or discharging speed of the Charge storage device is so dependent on the outside temperature that charging begins with increasing outside temperature is postponed to the end of the low tariff period.

From the magazine "Electronics" 1967, issue 7, pages 207 to 212, are electronic long-term members bekannl that work with a combination of capacitor and resistor as a time-determining element. Here it is described on page 209 that when using field effect transistors, far cheaper ones Results can be achieved.

For example, a capacitor with a high leakage resistance or a capacitor can be used as the charge storage device Secondary element, for example an accumulator, are used. The charging or discharging current of the Charge storage flow across such a large resistance that the charge or discharge extends at least over the period of the low tariff period.

It is desirable that a linear shift of the beginning as the outside temperature increases linearly de »charging period takes place towards the end of the respective low tariff period. This requirement seems to be initially not achievable by the charge control device according to the invention, since the Charge or discharge current or the charge or discharge voltage of a charge storage device at a constant Charge or discharge resistance has a non-linear relationship with time. An advantageous one Further development of the subject matter of the invention eliminates these difficulties in that the temperature dependency of the temperature-dependent resistance is so non-linear that with a linear change in the outside temperature the shift of the charging period is also essentially linear. As a lot of temperature-dependent resistances anyway have a non-linear resistance-temperature characteristic, this measure can be used usually just do this without further ado by choosing the correct temperature-dependent resistor. Where this is not possible, the resistance-temperature characteristics can be implemented in series or Parallel connection of temperature-independent and / or temperature-dependent resistors to the aforementioned ternperafurependent resistance can be changed in a known manner.

Another or possibly additional way to arrive at a linear relationship between the shift in the start of charging and the outside temperature is to provide means for generating a lay or discharge current of the charge storage device that is essentially constant during the low tariff period. In this way it can be achieved that the voltage of the charge storage device is linearized during charging or discharging. The resources required for this are known from circuit arrangements for sawtooth voltage generators.

With all charging control devices with postponement of a charging period towards the end a low tariff period is an outside temperature-dependent limitation of the Storage core temperature required. The necessity for this arises from the following consideration: For example, when charging is started in the

ίο Storage heater still residual heat from the previous one Discharge time remained and would be limited to an outside temperature-dependent limit Storage core temperature are waived, so it could happen that the storage heater during the charging time would also store a lot of unnecessary heat. That is why besides the time-shifting Charge control device to provide a charge-limiting charge control device. Even with an advantageous development of the invention

The subject of the invention is the inclusion of a charge control device possible, which only depends on the storage core temperature of the storage heater limited by the outside temperature. As a charge-limiting charge control device

* 5 one of the well-known (Austrian patent 261 073) or the only charge-limiting embodiment of an already proposed charge control device (German patent application P 16 90 675.5) are used. Such a charge-limiting charge control device can automatically switched on after the storage heater has started to charge, preferably by a relay will. You can control an electronic charge with one of the outside temperature exposed temperature-dependent resistance can also be in the time-shifting according to the invention Charging control device and in the charge-limiting charging control device contained therein only one temperature-dependent

giger resistance be contained, which by independent Switching, preferably by a relay, before the onset of charging to time-shifting Charge control device and after setting the charge in the charge-limiting charge control device is switched on. In this way We only need one as a temperature sensor for the time difference and the charge limitation kender, temperature-dependent resistor to be provided.

Figs. 1 to 6 contain diagrams of embodiments of a Aufladesteuereinrichtung according to the invention, where the diagrams relating to the operation of the time shifting charge control;

Fi g. 7 shows a circuit diagram for an embodiment of the subject matter of the invention.

In Fi g. 1 is the voltage U at the terminals of a charge storage device, preferably a capacitor with a high leakage resistance, over time t . The charge storage is charged to an outside temperature-independent DC voltage Vl before the start of the low tariff period and discharges from the start r0 of the low tariff period via a temperature-independent resistor, i.e. with a temperature-independent time constant 71. The voltage of the charge storage is continuously fed to the above-mentioned switching amplifier S with the outside temperature dependent resistance and therefore

outside temperature-dependent response threshold, in the lower outside temperature range lower, for example t / 11, 1/12, 1/13, whose resistance changes in terms of amount shows than in the upper range. Height falls with increasing outside temperature δ , Fig. 4 relates to a further embodiment. The switching amplifier S conducts, preferably in the form, with the charge storage only being connected to a relay or contactor, after the absolute value of the start of the low tariff to an outside temperature falling below the response threshold t / 11, t / 12 or dependent - preferably by a voltage time / 13 by the voltage U of the charge storage unit the ler /? 3 to A4 with the outside temperature charging of the storage heater. If there is exposed, temperature-dependent resistance R3 to an outside temperature #, which corresponds to the response generated - DC voltage, for example t / 41, threshold UH or i / 12 or 1713, i ° 1/42 or t / 43, is set and during of the Niedie charge at the time / 11 or / 12 or / 13. the tariff time charges. The voltage U of the charge-The temperature-dependent resistor can be the same as a switchover, preferably one with a negative temperature, with a fixed response threshold 1/4 coefficient. Such a resistor has namely supplied and the switching amplifier conducts, preferably mostly such a non-linearity of its temperature via a relay or contactor, according to the magnitude-resistance characteristic that its use is limited by moderately exceeding the response threshold t / 4 Easily such a non-linear decrease through the voltage U of the charge storage unit depending on the response threshold on the temperature outside temperature #, for example at one of the can achieve that the time shift of the charging times / 41, / 42 or / 43, the charging of the start of storage approximately linearly from the outside temperature of the heater. The DC voltage must depend on. for example t / 41, t / 42, 1/43, to which the La-F i g. 2 refers to a different execution storage device at time / 0, with increasing form, in which the charge storage device only decreases in terms of amount with outside temperature #.
Beginning / 0 of the low tariff time to a fixed constant. Finally, FIGS. 5 and 6 relate to a voltage 1/2 and are related to another advantageous development during the low tariff period, with the charging tariff time charging, with the voltage t / des Charge storage, preferably a secondary element, running at the same time as said only at the beginning / 0 of the low tariff period for on-switching amplifier S with outside temperature-dependent charge to a fixed DC voltage 1/6 or resistance and therefore outside temperature-dependent for discharging a fixed charging DC voltage Anspreohschwelle, for example t / 21, t / 22, 1/23, 3 <> 1/5 is brought starting, which is supplied with the. The switching amplifier conducts, in turn outside temperature # increasing time constant 761, preferably via a relay or contactor, after the 762 or 763 of the charging or the time constant Uli, Uli, t / 23 due to the voltage U. of the charge 751, 752, 753 of the discharge of the charge storage tank at times / 21, / 22 or / 23, 35 by inserting the charging of the storage heater based on the outside temperature. In this case, a temperature-dependent resistor must be set, in which the response threshold must increase in magnitude with the external charging or discharging circuit depending on the temperature. Outside temperature is changeable. The on this in I- ig. 3 shows the voltage curve in a form generated during the low tariff period, in which the charge storage 4 ° temperature-dependent and time-dependent voltage U rather, preferably a capacitor with a high discharge, is switched off during the low tariff conduction resistance, before the start of the Low tariff period, fed in advance to a switching amplifier with a fixed pull-in via a voltage divider Rl to Rl with a set response threshold t / 60 or t / 50, to which the outside temperature is exposed to temperature, preferably via a relay or contactor, according to the dependent resistance Rl, on an outside temperature 45 the amount-related exceeding or falling below the! temperature-dependent voltage, for example I'M, 1/32, response threshold 1/60 or 1/50 through the frame / 33, is charged from the beginning / 0 of the lowering U of the charge storage, the charging of the tariff time via a temperature-independent Initiates storage heater, depending on the j resistance, i.e. with a constant time constant ent- outside temperature, for example at the time point, the voltage U of the charge storage 50 th / 61, / 62, / 63 or / 51, / 52, / 53.

At the same time, a switching amplifier with fixed voltages t / 11 to t / 43 and the time cone set response threshold t / 3 is fed. constants 751-763 are derived discrete, as examples ge-The switching amplifier, preferably via a re-selected values of continuous functions of the '■ relay or contactor, according to the amount-lower outside temperature #, so that values tread at the threshold 1 / 3 by the voltage correct, associated outside temperatures # 11 to voltage U of the charge storage, the charging of # 43 and # 51 to # 63 occur.
Storage heater. The initial As from the distribution of the response threshold voltage, for example 1/31, 1/32, t / 33, the La- Uli, 1/12, 1/13, Uli, Uli, Uli or the initial dung memory with the Outside temperature grow. voltages 1/31, t / 32, 1/33 or the final voltage Um a linear relationship between the 60 gen 1/41, 1/42, i / 43 or the time constant 751, outside temperature # and the associated switch-on 752 , 753, 761, 763 and the desired lineapoints / 31, / 32, / 33, nrit which the charging of the ren distribution of the associated switch-on times storage heater begins to get, the ill to / 63 of the charge can be derived from the charge voltage to Charging of the charge storage described embodiments a nonh'nearer chers are tapped in a particularly advantageous manner at the response threshold or the initial or final voltage level λ2, which has a relationship between the outside temperature and positive temperature coefficients, when this is in the open or There are time constants so that when the temperature range is used there is a change in the outside temperature # each

ίο

Desired tfnear shift of the beginning of the charging, i.e. the switch-on times, takes place.

F i g. 7 shows the circuit diagram of an embodiment of the electronic charge control device. To this end, it must first be noted that most storage heaters available today contain a so-called charge controller 8, which has two temperature sensors 2, 9. One (9) of these temperature sensors is exposed to the influence of the temperature of the storage core of the storage heater 4, while the other (2) can be heated by an additional heater 1. The heating of one of the temperature sensors in each case causes a stroke of a lifting element 10, which is contained in the charge controller 8. The strokes, which are due to the action of a temperature sensor, add ^: e ^r ** n to a total stroke. When this total stroke reaches a certain size, electrical contacts 11 are interrupted by the lifting element 10, via which the current flows to the heating elements S, 6, 7 of the storage heater. The overall stroke leading to the interruption of the contacts 11 is reached at a lower temperature of the storage core, the more the temperature sensor 2, which can be heated by the additional heating element 1, is actually heated. By heating this temperature sensor 2 to different degrees it can be achieved that the contacts 11 in the power supply to the radiators 5, 6, 7 are opened at different storage core temperatures. This mechanism is used to limit the temperature to which the storage core is heated, depending on the outside temperature ϋ , in that the additional heating element 1 heats the temperature sensor 2 assigned to it the more the higher the outside temperature & is. One of the known or already proposed, charge-limiting charge control devices can be used to control the current through the auxiliary heating element 1. A charge-limiting charge control device is now also contained in the exemplary embodiment shown in FIG. 7. In Fi g. 7, the temperature sensor 2 of the charge controller 8 of a storage heater 4 assigned to the additional heater 1 is shown on the right. In the storage heater are the radiators 5, 6, 7, which get the charging of the storage heater 4 with thermal energy. These radiators are connected to the phases R, S, T and to the neutral conductor Mp via the contacts dr, ds, dt of the contactor D. The contacts mentioned are closed during the charging period.

The circuit arrangement shown contains an exemplary embodiment a previously described, time-shifting charge control device and a Corresponding to advantageous further development - using common components - a charge-limiting one Charge control device, which is controlled according to that controlled by the first-mentioned charge control device Beginning of the charging period together with the charge controller contained in the storage heater 4 takes care of the charge limitation. The embodiment relates to a charge control device with outside temperature-dependent response threshold of the switching amplifier, with charging of the charge storage outside the low tariff period and discharge of the charge storage during the low tariff period according to Fig. 1. The time constant of the Discharge must be measured in such a way that a discharge that extends over the duration of the low tariff period charge results.

Essential. Components of the circuit arrangement are the charge storage, a capacitor C with a ho hem leakage resistance, the temperature-dependent Wi resistance R12, which is exposed to the influence of the Außenentem temperature ö , and the switching amplifier 5, the essential components of which are the transistors Tl Tl, Γ3, the with the RC combination ver

ίο tied transistor 7 * 1 is one with high input resistance. The switching amplifier S is controlled by its input terminal E. The input of the switching amplifier ι * ι through the resistor RlI high resistance. By adding de ", external tempera-

* 5 temperature-dependent resistance R 12 in the switching amplifier S , its A'-sensor threshold depends on the outside temperature. Depending on whether the potential at the input terminal E exceeds or falls below the response threshold of switching amplifier 5, current

so fiuß prevented or caused by the relay winding B. Correspondingly, the contact arms bl unc 62 assume the position shown or the opposite position.

The mode of operation of the circuit shown

arrangement is as follows:

Outside the low tariff period, phase R is de-energized , so relay winding A is de-energized! and the contacts al, al assume the position shown. The voltage divider RS bis / 76 is connected to the

DC voltage terminals + and -, and its voltage divider tap leads via the contact al to the charge storage, the capacitor C. This wire is charged to the voltage specified by the voltage divider ratio of the voltage divider RS to Rt during the low tariff period. The Transistorer 71, 7 * 2 and 73 are de-energized, since the Spannungszufuhi is chen from the terminal + through contact Al unterbro. The relay winding B is also de-energized so that the contacts Bl and bl the position shown

take treatment. (The contact bl is on the voltage divider tap of the voltage divider Rl to RfL.) The relay winding D, whose contacts dl, dr, ds are in the position shown, is also de-energized, so that the power supply to the relay winding D

and - starting from the mains voltage terminals RS, T - the power supply to the radiators S, 6, "1 of the storage heater 4 is interrupted. The storage heater is therefore not charged outside of the low tariff period.

With the beginning of the low tariff period, the time-shifting charge control device comes into operation. Voltage is now applied to terminal R ' , relay winding A has current flowing through it, contact a \ closes sieve, whereby switching amplifier S nil is supplied with direct voltage; the contact öffnei al, so that the capacitor C is now able to discharge · when the adjustable resistor R9 and a series circuit of resistors AE10, R12 and the base-emitter path of the transistor Tl, the resistors R9 and RIO are extremely high impedance. The transistor 7 * 1 conducts after the closing of the contact al and its response threshold, ie seir base potential value at which it changes from the conductive ir to the blocking state, is determined by the ir

the emitter lead contained, outside temperature-dependent resistor R 12 is determined. The collector potential of the transistor 71 is fed to the base of the transistor 72 via the resistor A13.

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while the emitters of both transistors are directly connected. Therefore, the transistor Tl is in the blocking state as long as the transistor Tl conducts. The resistor All is only used to limit the current. When the transistor Tl blocks, the tap of the resistor RIA and thus through resistor RlS the base is of the transistors Γ3 at the potential of the DC voltage terminal +. There is therefore no voltage between the base and the emitter of the transistor Γ3, so that the latter also blocks. Relays B and D therefore initially remain in the state shown even after the low tariff period has started.

The state just described, which exists from the beginning of the low tariff period, is maintained until the capacitor C has discharged so far that the potential at terminal E has fallen below the response threshold of the switching amplifier 5. From this moment on, the base potential of the transistor Tl is so low that it blocks. As a result, a voltage occurs between the base and the emitter of the transistor T2 , which causes it to conduct. Likewise, due to the now existing voltage drop across resistor R14, a voltage occurs between the base and emitter of transistor Γ3, so that this also conducts. The resulting flow of current through the relay winding B causes the switching of the contact oil and the closing of the contact fe2. After switching over the contact bl flows from the terminal Mp via the contact bl, the contact dl and the relay winding D current to the terminal R '. The relay contact dl therefore switches over so that current can now flow from the connection terminal R ' via the relay winding D and the contact dl to the connection terminal Mp located next to the connections R, S, T. This has the effect that the relay winding D from now on is continuously traversed by the current, even if the contact should return to the position shown. When the contact dl is switched over, the contacts dr, ds, dp are closed at the same time, whereby the heating elements 5, 6, 7 contained in the storage heater 4 are connected to the mains connection terminals R, S, Γ. This starts the heating (charging) of the storage core contained in the storage heater 4. At the same time, current can flow from the mains connection terminal R through the second auxiliary heating element 3 via the contact bl to the terminal Mp . The second auxiliary heating element 3 is geometrically in the immediate vicinity of the temperature-dependent resistor R12, that is to say with it, for example in a common housing, in the open air, where both are exposed to the outside temperature ϋ. (The geometric proximity of R12 is indicated by dashed lines.)

The effect of heating the temperature-dependent resistor R12 is described in the following, but it must first be explained what happens when the contact & 2 closes: When the capacitor voltage has dropped to the response threshold of the switching amplifier 5, it responds, causing the contact bl is closed. As a result, the input terminal E is connected directly to the tap on the voltage divider Rl to R8 . Since the resistor R8 has a low resistance, the potential at the input terminal E is reduced by closing the contact bl and the capacitor C is recharged to the voltage given by the voltage divider ratio of the voltage divider R7 to Λ8. By lowering the potential! at the input terminal E of the switching amplifier S it is effected that after the first response, ie after the transistor Tl has been blocked, this state will definitely retain this state for some time.

In the state that has now occurred, the circuit arrangement shown represents a charge-limiting one Charge control device, with largely the same components as for the inclusive Time-limiting charge control device used up to the start of charging will. Switching from the time-shifting

* 5 on the charge-limiting charge control device has only been implemented by Koniakt bl

As a result of the heating of the outside temperature-dependent resistor RIl by the auxiliary heating element 3 after switching over the contact fei with the start of charging, the resistance of RU drops. As a result, the voltage drop across RIl, which is caused by the current passed by the transistor Tl, also decreases. As the voltage drop across RU drops, the response

»5 threshold of the switching amplifier S. After some time of the heating of Λ12 by the auxiliary heater 3, the response threshold of the switching amplifier S has dropped to the potential present at the voltage divider tap of the voltage divider Rl to Ä8, so that this potential at the input terminal E in turn becomes the response threshold of the Switching amplifier 5 surpasses. This has the consequence that the switching amplifier S switches over, ie that the transistor Tl becomes conductive and the transistors Tl and Γ3 block.

This interrupts the flow of current through the relay winding ß, and the contacts fei and fe2 return to the position shown. As a result, on the one hand, the flow of current through the auxiliary heating element 3 is interrupted, while, on the other hand, the input terminal E is no longer directly connected to the voltage divider tap of the voltage divider Rl to /? 8. The latter has no effect, since the capacitor C maintains the voltage that it has assumed through the charge reversal via λ8 for a long time. When the contact fei returns to the position shown, current flows from the mains connection terminal R via the contact dr, through the auxiliary heater 1, via the contact fei to the terminal Mp. In this way, the temperature-dependent resistor RIl is no longer heated by the auxiliary heater 3 , but the temperature sensor 2 of the charge controller 8 contained in the storage heater 4 is heated by the auxiliary heater 1. The outside temperature-dependent resistor RH therefore cools down while the temperature sensor 2 of the charge controller heats up, which results in a stroke of the lifting element 10 contained in the charge controller 8.

By cooling the temperature-dependent

Resistor R12 increases its resistance value, so that the response threshold of the switching amplifier is raised again. After it has reached the voltage across the capacitor C, which is still almost identical to that at the voltage divider tap of the

6 $ voltage divider Rl to R8 , the switching amplifier switches again, that is, the transistor Tl blocks, the transistors TL, Ti conduct, the relay winding B is traversed by the current,

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and the contacts bl, bZ switch to the position not shown.

There now follows again yes heating of the temperature-dependent resistor R12 through the auxiliary heater 3 while the heating of the temperature sensor is interrupted by the auxiliary heater 1 second

As a result of the alternating heating and non-heating of the temperature-dependent resistor R12 , the switching amplifier 5 constantly switches alternately from one state to the other. In this way, either the temperature-dependent resistor R12 is alternately heated by the auxiliary heating element 3 or the temperature sensor 2 of the charge controller 8 is heated by the auxiliary heating element 1. The temperature sensor 2 is heated the longer the shorter the temperature-dependent resistor RU, which is located outdoors together with the auxiliary heating element 3, needs to be heated in order to achieve a decrease in the response threshold of the switching amplifier until it is switched, i.e. the higher the outside temperature is . Due to the more intensive heating of temperature sensor 2 with increasing outside temperature i? the charging of the storage heater 4 is limited by means of the charge controller 8 depending on the outside temperature, in that the lifting element 10 has to perform a growing stroke due to the increasing outside temperature and increasing heating of the temperature sensor 2, whereby the state of the charge controller 8 approaches its switch-off point with increasing outside temperature. The circuit arrangement shown has thus taken over the function of a charge-limiting charge control device from the start of charging.

When the charge controller 8 contained in the storage heater 4 has interrupted charging after a sufficient charging time that depends on the outside temperature, the interplay of the changeover contact bl continues, whereby the temperature-dependent resistor R12 continues to be heated cyclically. The auxiliary heater 1, however, no longer flows through current because the charge controller has opened its contacts 11. The heating of R12 has no effect on the charging of the storage heater, unless the charge regulator 8, the contacts 11 of which are in the supply lines to the radiators 5, 6, 7, cool down at least one of them before the end of the low tariff period Temperature sensor again allows recharging, which in turn is limited by the charge-limiting charge control device as a function of the outside temperature.

ao For the temperature-dependent resistance Ä12 a so-called NTC (resistor with negative temperature coefficient) is expediently chosen because of the non-linear resistance-temperature characteristic such resistance from

"5 Fig. 1 comes closest to recognizable requirement, namely that the resistance value changes greatly with temperature changes in the low temperature range as a function of the temperature and less in the higher temperature range. If this requirement is met in the manner recognizable from FIG with a linear increase in the outside temperature ■ & a linear shift in the start of charging of the storage heater 4 takes place.

1 sheet of drawings

Claims (14)

Patent claims: 1. Electronic charging control device suitable for at least one electric storage heater, which effects the shifting of at least one charging period towards the end of a low tariff period (time-shifting charging control device), with a temperature-dependent (outside temperature-dependent) resistor exposed to the influence of the outside temperature and a Switching amplifier, characterized in that this (S) is electrically linked to an electrical charge storage device (capacitor C) in such a way that the onset of charging of the storage heater (4) is effected when the charging or discharging current or the voltage of the electrical charge storage device ( Capacitor C) exceeds or falls below a value representing the response threshold of the switching amplifier (5), with circuitry ensuring that, due to the temperature dependence of the outside temperature-dependent resistor (12), either that of the charge storage device (condens tor C) stored or max. storable charge or the response threshold of the switching amplifier (S) or the charging or discharging speed of the charge storage device (capacitor C) is so dependent on the outside temperature that the start of the charging period as the outside temperature increases (ϋ) to the The end of the niece tariff period is postponed. 2. Charging control device according to claim 1, characterized in that the temperature dependence of the temperature-dependent resistor (12) is non-linear in such a way that with a linear change in the outside temperature (ϋ) the shift of the start of the charging period is also essentially linear. 3. Charge control device according to claim 1 or 2, characterized in that it contains a charge control device which only limits the storage core temperature of the storage heater (4) as a function of the outside temperature (■ &) (charge-limiting charge control device). 4. Charge control device according to claim 3, characterized in that the charge limiting Charge control device automatically after the storage heater (4) has started to charge, is preferably switched on by at least one relay contact (62). 5. Charge control device according to claim 4, characterized in that the charge-limiting charge control device operating after the onset of charging of the storage heater (4) is an electronic charge control device with a temperature-dependent resistor (12) exposed to the outside temperature (■ &). 6. charging control device according to claim 5, characterized in that in the time-shifting Charge control device and in the charge-limiting charge control device only a single temperature-dependent resistor (12) is included, which by switching automatically, preferably by at least one relay, before the onset of charging in the time-shifting Charge control device and after the onset of charge in the charge limiting Charge control device switched on is. 7. Charge control device according to one of the preceding claims, characterized in that the charge storage device, preferably a capacitor (C) with a high leakage resistance, is charged to an outside temperature-independent direct voltage (i / l) before the start (fO) of the low tariff period, from the beginning (rO ) the off-peak period discharges via a temperature-independent resistor, whereby the voltage ( U) of the charge storage device is continuously fed to a switching amplifier (S) with the outside-temperature-dependent resistor (12) and therefore outside-temperature-dependent response threshold (Uli, t / 12, 1/13) and that the switching amplifier (S), preferably via a relay (B) or contactor, initiates the charging of the storage heater (4) after the amount falls below the response threshold (Uli, t / 12, t / 13) due to the voltage (U) of the charge storage device . 8. Charge control device according to claim 7, characterized in that the temperature-dependent resistor (12) is one with a negative temperature coefficient (NTC) . 9. Charging control device according to one of claims 1 to 6, characterized in that the charge storage device, preferably a capacitor with a high leakage resistance, is only applied to a fixed DC voltage (t / 2) at the beginning ((0) of the low tariff period) and during the Charging off-tariff time, the voltage ( U) of the charge storage device is simultaneously continuously fed to a switching amplifier (S) with an outside temperature-dependent resistance and therefore an outside temperature-dependent response threshold (t / 21, t / 22, t / 23) and that the switching amplifier, preferably via a relay or Contactor initiates charging of the storage heater after the response threshold ( t / 21, t / 22, t / 23) has been exceeded by the voltage (U) of the charge storage device. 10. Aufladesteuereinrichturg according to one of claims 1 to 6, characterized in that the charge store, preferably a capacitor with a high leakage resistance, before the beginning (rO) of the low tariff period, preferably via a voltage divider (Rl to RZ) with the temperature-dependent resistance exposed to the outside temperature ( R2), is charged to an outside temperature-dependent voltage ( t / 31, t / 32, t / 33), is discharged from the beginning (fO) of the low tariff period via a temperature-independent resistor, with the voltage (U) of the charge storage device running at the same time as a switching amplifier with a fixed response threshold (t / 3) and that the switching amplifier, preferably via a relay or contactor, initiates the charging of the storage heater after the voltage (U) of the charge storage device has fallen below the response threshold (t / 3). 11. Charging control device according to claim 10, characterized in that the charging voltage (C / 31, t / 32, 1/33) for charging the charge storage device at a resistor with posi tive temperature coefficient (PTC) is tapped, which in the temperature range used shows smaller changes in resistance than in the upper range for temperature changes in the lower outside temperature range. 12. Charging control device according to one of claims 1 to 6, characterized in that the charge storage device, preferably a capacitor with a high leakage resistance, is only connected to an outside temperature dependent - preferably by a voltage divider (R3 to i? 4) at the beginning (/ 0) of the low start time. - DC voltage generated with the temperature-dependent resistor (A3) exposed to the outside temperature ( t / 41, t / 42, t / 43) and is charged during * 5 of the low start time, the voltage ( U) of the charge storage being continuously fed to a switching amplifier with a fixed response threshold (t / 4) and that the Switching amplifier, preferably via a relay or contactor, initiates the charging of the storage heater after the response threshold (t / 4) has been exceeded by the voltage (U) of the charge storage device. 13. Charging control device according to one of ^S 5 claims 1 to 6, characterized in that the charge storage device, preferably a secondary element, is only applied to a fixed DC voltage (t / 6) for charging or discharging at Beginr (fO) of the low time is brought from a fixed DC charging voltage (US) , the time constant (Γ61, T62, Γ63; TSl, 752, T53) of the charging or discharging of the charge storage device by inserting the temperature-dependent resistor exposed to the outside temperature into the charging or discharging circuit in Dependence on the outside temperature (0) is variable and that the outside temperature-dependent and time-dependent voltage ( U) of the charge storage generated in this way during the low tariff period is continuously fed to a switching amplifier with a fixed response threshold (t / 60; USO) during the low-level period, which , preferably via a relay or contactor, after the response has exceeded or fallen below the amount h threshold (t / 60; t / 50) initiates the charging of the storage heater through the voltage (U) of the charge storage device. 14. Recharge control device according to one of the so preceding claims, characterized by means for generating a during the low tariff period substantially constant charging or discharging current of the charge storage device. 55