DE2528200A1 - Storage heater with fan and direct acting radiator - control ensures that energy consumed in high tariff period is less than in low tariff - Google Patents

Abstract

Control of storage heater which includes a heat accumulator with radiators (1), a fan (2) and an auxiliary direct-acting radiator (3) is carried out by heating the heat accumulator in the low-tariff period only for as long as temp. is below nominal room temp. When a given first difference occurs between nomonal and actual room temp, the fan is switched on. In the high-tariff period, the fan is switched on for as long as temp. is below nominal room temp. The direct-acting radiator is switched on in the high-tariff period only when a given second difference occurs between nominal and actual room temp. which is less than the first difference. The max. energy consumed by the direct-acting radiator in the high-tariff period is less than that consumed by the heat accumulator or its radiators in the low-tariff period.

Description

Control of a storage heater The invention relates to the control a storage heater with a heat accumulator provided with radiators, a Fan and an additional direct heating element.

Such storage heaters are dimensioned so that the during The heat stored in the heat storage tank during the low tariff period is available all year round Space heating is sufficient. Switching on the additional direct heating element is only necessary makes sense if, for example in the transition period, only a partial amount of heat is present in the heat storage tank.

The economy of storage heaters is known to be based insist that the electricity supply companies operate during periods of low traffic grant the pantograph a favorable tariff. Since such nicer tariff times, however only last a few hours, the heat accumulator must be dimensioned so large that he can also cover the heat demand during the high tariff period. This means that the The heating element of the heat accumulator and the heat accumulator have a high connected load itself has a relatively large volume. Overall, this leads to high purchase costs.

and a considerable space requirement of a storage heater.

The trend in tariffs for domestic and foreign El.ostriz ity utilities have recently started the macimale Connected load is limited by storage heaters and a 24-hour base load is required will. These requirements are with the known controls for storage heaters not to meet.

The object of the invention is to provide a controller for a storage heater of the above type to propose a downsizing of the electrical Connection value is possible without affecting the economy of the storage heater is lost, whereby the heat storage tank and its radiator are designed to be smaller than this for year-round room heating in storage mode during the low tariff period would be necessary.

According to the invention, the above object is achieved in that the heat accumulator is only heated during the low tariff period, as long as the target room temperature is fallen short of that in the low tariff period, if a bestw-th difference I occurs between the target room temperature and the actual room temperature The fan is switched on, that the fan is switched on during the high tariff period, as long as the room temperature has fallen below, that the direct radiator only in the high tariff period in addition to the fan works if a certain difference II occurs between the target room temperature and the actual room temperature, which is smaller than the difference I, and that from the direct radiator during the high tariff period The maximum electrical energy consumed is less than that of the heat accumulator or its radiators in the low tariff time maximum consumed electrical energy and the sum of these amounts of energy corresponds to the max.

Heat requirement.

To heat the heat storage tank exclusively during the low tariff period, as long as the target room temperature is not reached, it is favorable because the temperature is not reached the target room temperature is a criterion that can be evaluated using simple circuitry is. It is also beneficial to which in itself in the present Case in which only the sum of the heat accumulator or its radiators and the The amount of energy consumed by direct radiators corresponds to the maximum heat requirement, obvious The storage tank is also not heated during the high tariff period, as this is in addition to the Direct heating required at high tariff time also - uneconomical at high tariff time - memory charging. Conversely, the invention also achieves that the direct heating element is not switched on during the low tariff period, so that the connection value at the low tariff period is not undesirably caused by switching on of the direct heating element is increased. Overall, therefore, is the maximum connection value in the low tariff time due to the connected load of the heating elements of the heat storage tank and specified by the direct radiator during the high tariff period. Of course in addition, the connected load of the fan, which is not significant.

The room heating in the low tariff period takes place exclusively with the invention via the heat accumulator. During the high tariff period, the room is heated from the storage tank and if there is a shortfall despite the storage tank being discharged when there is a large heat demand the setpoint temperature, with the direct heating element switched on.

It is also advantageous that whenever the direct radiator is switched on, the fan is already running. The direct radiator can therefore place in the airflow of the fan, thereby lowering its maximum surface temperature is made possible, which leads to a cheaper direct radiator.

The difference I between the target room temperature and the temperature, at which the fan switches on during the low tariff period is preferably 4 K. the target room temperature at 20 OC, then the fan switches during the low tariff period, so at 16 OC, a.

The temperature difference II between the target room temperature and that Temperature at which the direct radiator is used during the high tariff period switched on is preferably 1 K. If the target room temperature is included, for example 20 "C, then the direct heating element switches on at 19 OC during the high tariff period.

A favorable distribution between the maximum connected load and the base load should be obtained from the radiators of the during the low tariff period The maximum amount of electrical energy that can be absorbed is about three times as large as the maximum energy that can be absorbed by the direct radiator during the high tariff period. Amounts to For example, the energy 120 required for maximum daily room heating kWh (corresponding to a heat requirement of 120.3.6 MJ) should then be used during the low tariff period can be heated with 90 kWh and at the high tariff period with 30 kWh. When the low tariff period takes 8 hours, for example, there is a connection value for the heat storage tank of 11.25 kW. Accordingly, the high tariff time then lasts 16 hours.

This means a connected load of about 1.87 kW for the direct radiator. If direct heating were not provided during the high tariff period, it would have to be used during the low tariff period the connected load is 15 kW. It can be seen from the invention on the one hand a reduction in the maximum connection load and, on the other hand, a full-day service Given the basic load on the power grid.

In a preferred embodiment of the invention, the control works with a room thermostat provided with three contacts, the first Contact when falling below the target room temperature, the second when falling below the difference II and the third when falling below the difference I between the actual room temperature and the target room temperature. One of those Room thermostat that closes at different temperatures is in French U.S. Patent 2,043,944.

The controller preferably has a high tariff / low tariff switchover relay on, the one with a changeover contact behind the first contact of the room thermostat and a switching contact behind the second contact of the room thermostat is and on the second changeover contact are on the one hand the radiators of the heat accumulator and on the other hand the fan connected to the third contact of the room thermostat and the direct heating element is on the switching contact.

Control circuits with the same function can be used as electronic Build circuits.

Advantageous embodiments of the invention emerge from the following Drawing description. In the drawing: FIG. 1 shows an exemplary embodiment of the invention and FIG. 2 shows a further exemplary embodiment.

A storage heater has radiators 1 in the heat storage are embedded. A fan 2 is provided, which may be used in the heat accumulator stored heat ir. dissipates the room to be heated. In addition, the storage heater a direct heating element 3, which is located in the air flow of the fan 2. In the one to be heated Room is a temperature associated with a room thermostat 4 at a suitable point sensor 5 angeord @@@. The electrical units, heating element 1, direct heating element 3 and fan 2 are & n the ground pole Mp. Between the ground pole and the low tariff phase RN is the winding 5 of a high tariff / low tariff switchover relay 6. This relay 6 has two switching contacts 7 and 8 and a switching contact 9. At high tariff time the contacts are in the position shown in FIG. In the low tariff period take the lines shown undulation.

The room thermostat switches one after the other when the temperature drops three contacts lo, 11 and 12. The contact 10 is below the target room temperature, for example 20 "C, closed. The contact 11 closes when the difference II between the actual room temperature and the target room temperature, in particular 1 K, i.e. 19 OC in the example. The contact 12 closes when the Difference between the actual room temperature and the target room temperature, in particular 4 K, i.e. 16.0C in the example.

The heating elements 1 are connected downstream of the contact 10 via the contact 8. The direct heating element is connected downstream of contact 11 via contact 9. At the contact 12 is directly the fan 2.

The operation of the circuit described is essential the following: starting from the switching position of the contacts shown in FIG 7, 8 and 9 during the high tariff period, the following results when the room temperature drops: the temperature falls below the setpoint set on the room thermostat 4 for example 20 OC, then the contact 10 closes and the fan 2 starts up. He conveys heat from the heat accumulator into the room to be heated.

If this amount of heat is sufficient to bring the room to the target temperature, then after some time the switch 10 opens and the fan 2 switches again away. If the amount of heat pumped out of the heat accumulator by the fan is not sufficient, the To reach the target room temperature and the room temperature will therefore drop below 19 OC from, then the contact 11 closes and the direct heating element 3 is switched on.

This means that the target room temperature is reached.

During the low tariff period, when the room temperature falls below the set room temperature, contact 10 is also closed. This will make the Charging of the heat accumulator initiated by heating the radiator 1. The fan 2 is not running yet. If the contact 11 closes as a result of further sinking the room temperature, the direct heating element 3 is not switched on now, because the switch contact 9 is open. If the room temperature drops to 16 OC ah, then contact 12 closes and fan 2 starts up. It promotes warmth from the Heat storage until the room temperature has risen above 16 OC again. This relatively low temperature is sufficient for the room heating in the period that coincides with the low tariff period Night time off. If necessary, a stronger temperature can be set by adjusting the room thermostat Space heating can be achieved. The differences I and II between the three temperature values remain constant when the room thermostat is adjusted.

In Figure 2, an electronic circuit is shown, its mode of operation is the same as the circuit described. The corresponding parts are in both Figures are provided with the same reference numerals. The switching contacts 10, 11 and 12 are each replaced by a circuit in which a transistor, T 10, T 11 or T 12 a triac Tr 10, Tr 11 or Tr 12 ignites. The bases of the transistors T 10, T 11 and T 12 are connected to the collector of a transistor T 4, the base of which is connected to a voltage divider, consisting of a temperature-dependent resistor representing the temperature sensor 5 and a setting resistor R 4 is located. Depending on the ratio of actual Room temperature to the set room temperature is at the collector of transistor T 4 more or less high tension.

The transistors T 10, T 11 and T 12 are in their resistance values staggered emitter resistors R 10, R 11 and R 12.

These resistors are dimensioned so that the associated transistors become conductive when a corresponding voltage value at the collector of the transistor T 4 is present.

The transistor T 10 becomes conductive and thus the TriacTr 10 is ignited, as soon as the room temperature falls below the target temperature. This is the high tariff time the fan 2 or, during the low tariff period, the heating element 1 of the heat storage tank is switched on.

As soon as the room temperature has risen from the target room temperature by the difference value II deviates, when contact 9 is closed at the high tariff time, the transistor T 11 conductive and the triac ignited. The direct heating element 3 is now switched on.

Occurs in the low tariff period between room temperature and the set room temperature the difference I a, then the transistor T 12 is conductive and ignites the Triac Tr 12. The fan 2 is switched on.

The invention can also be implemented in other circuits.

For example, it is possible to use a differential amplifier with three Provide outputs, with the different switching temperatures between the outputs corresponding voltage values are present at contacts 10, 11 and 12, which in terms of potential according to the deviation of the actual temperature from the room temperature be moved. The output signals of the differential amplifier can be switched over Evaluate switching transistors that are followed by switching relays, for example.

Claims (7)

Claims 1. Control of a storage heater with a radiator Heat storage, a fan and an additional direct heating element, as characterized by, that the heat storage is only heated during the low tariff period, as long as the target room temperature is not reached that in the low tariff period, if a certain difference I between the. Set room temperature and the actual room temperature occurs, the fan (2) is switched on so that the fan is switched on during the high tariff period is, as long as the room temperature has fallen below, that the direct radiator (3) works exclusively in the tIoclltarifzeit in addition to the fan (2), if a certain difference II between the target room temperature and the actual one Room temperature occurs, which is smaller than the difference I, and that of the direct heating element (.3) The maximum electrical energy consumed during the high tariff period is less than the maximum absorbed by the heat storage tank or its radiator (1) during the low tariff period Is energy and the sum of these amounts of energy corresponds to the maximum heat demand. 2. Controller according to claim l, characterized in that the temperature difference I 4 K - amounts to 0 3. Control according to claim 1 or in particular claim 2, there - through characterized in that the temperature difference II is 1 K. 4. Control according to claim 1, characterized in that the in the Low tariff time of the radiators (1) of the heat storage tank maximum that can be absorbed electrical energy is about three times as large as that in the high tariff period of that Direct heating element (3) maximum electrical energy that can be absorbed. 5. Control according to one of the preceding claims, characterized in that that this control has a room thermostat (4) with three contacts (10, 11, 12), is given away, the first contact (io) when falling below the Set room temperature, the second contact (all) when falling below the difference II and the third contact (12) when falling below the difference I between the actual Room temperature and the target room temperature closes. 6. Controller according to claim 5, characterized in that the controller has a high tariff / low tariff switchover relay with a switchover contact (8) behind the crest contact (10) of the room thermostat and a switch contact (9) is provided behind the second contact (all) of the room thermostat, and that the changeover contact (8) on the one hand from the radiators (1) of the heat accumulator and on the other hand to the fan (2) which is connected to the third contact (12) of the room thermostat is connected, and that the direct heating element (3) is on the switching contact (9). 7. Control according to claim 5 and / or 6, characterized in that the contacts each through a transistor triac (T 10 to T 12, Tr 10 to Tr 11) are formed. o. Control according to one of the preceding claims, characterized in that that the Dircktheizkör by (3) is in the air flow of the fan (2).