DE1953215A1 - Process for the automatic charging of electric storage heating systems and automation for the implementation of the process - Google Patents

Description

Process for the automatic charging of electric storage heating systems and automation for carrying out the method The invention relates to a method for the automatic charging of several heating storage devices autweiseae electric storage heating systems during the low tariff period depending on the outside temperature and the residual heat of the individual heating storage devices.

It is known, the individual storage heaters of electric storage heating systems to be charged at the beginning of the low tariff period. The charging time is determined by the temperature outside of the building in which the heating system is located and through the residual heat, which each individual heating storage device still contains. The disadvantage of one such charging and thus also. of the well-known automatic recharging is that all heating storage devices are switched on at the beginning of the low tariff period.

If one assumes, for example, that the connection value has a Two-family house equipped with electric storage heaters is approx. 30 KW, It is understandable that the electricity works should turn on all of them at the same time Heating storage devices installed in a building because of the considerable load peaks strives to forbid siiid.

Another disadvantage is that in the known charging method the individual storage heaters are already full before the end of the low tariff period are charged and as a result of the imperfect thermal insulation methods that have hitherto been used are used, heat radiation losses occur during the low tariff period, which undesirably heat up the rooms and generate high energy costs. aside from that are the well-known automatic charging systems, which are equipped with mechanical components such as clockworks, "Diagnostic relays, bimetallic relays, etc. work, prone to failure.

The invention is therefore based on the object of a method for automatic charging of electrical storage systems with several storage heaters and to create an automatic charging system, through which the disadvantages mentioned with regard to the load on the supply network, the high heat radiation during the low tariff period and the susceptibility to failure can be avoided.

To solve this problem, it is proposed that the entire system during the low tariff period if a certain outside temperature is not reached is switched to operational readiness with a delay compared to the start of the low tariff period, and that the heating storage devices compared to the start of operational readiness entire system in operation with a delay depending on its respective residual heat be taken.

In a storage heating system operated according to the method according to the invention the outside temperature is first measured from the start of the low tariff period. By this outside temperature is set a certain delay time, the z. B. in an outside temperature range of -180 C to +180 C linearly for about 30 minutes can increase to about 6 hours. After the delay time has elapsed, the entire system switched to ready for operation, d. H. the heat storage devices are now connected to the mains, but are not yet charged. The actual The beginning of the charging of the individual heating storage devices is compared to the beginning of the The operational readiness of the entire system is delayed. This delay depends but now from the residual heat that is still in each pickling storage device. Since this residual heat usually differs from device to device, the The times of the start of charging of the individual heating storage devices are different, so that load peaks in the supply network can no longer occur. The delay time of the heating storage devices cold in a residual heat temperature range of +200 C to + 1000 C from about 1 minute to about 25 minutes, the method according to the invention therefore combines two advantages. Through the first delay becomes the earliest possible start of charging a heating storage device by at least 30 minutes compared to the beginning of the low tariff period and by the second Delay a successive charge first of the more discharged and aann of less discharged heating storage devices.

An electronic automatic charging system for charging electric storage heating systems with several heating storage devices consists of a housing temperature sensor, a Residual heat sensor in each heating storage device and a control device that controls the Evaluates measured values of the outside temperature and dc residual heat sensor and the charging which controls the heating storage devices.

In the known kufladeautomatiken there is the control device from an electronic switching device built into every heating storage device and the charging of the heating storage device assigned to it at the beginning of the low tariff period initiates and determines the charging time, d. H. the charge after reaching the required amount of heat ended.

On the other hand, the electronic automatic charging system stands out for its implementation of the method according to the invention by a central parent device with a delay device for all heating storage devices, which the entire system if a certain outside temperature with a delay compared to the start of the low tariff period switches, * as well as through a daughter device built into a heating storage device a delay device, which each heating storage device falls below a certain residual heat compared to the start of operational readiness of the entire System switches on with a delay.

The mother device expediently contains one with the outside temperature sensor connected analog-to-digital converter that works on a pulse counter whose Counting is evaluated by a pulse evaluator for actuating a relay, that is in the charging power supply network.

The sensor measuring the outside temperature, e.g. B. a temperature dependent Resistance is continuous during the delay time from the start of the low tariff period in function. A voltage that changes due to the outside sensor is generated in the analog-digital converter converted into needle pulses. The number of pulses per unit of time is changing Voltage proportional. The pulse counter gives a defined pulse as a trigger pulse via the pulse evaluator to the relay. The working contact then closes of the relay in the charging power supply network.

The mother device is supplied with constant DC voltage, taken from the grid via a transformer and a rectifier circuit will.

Each daughter device can have one connected to the residual heat sensor Analog-digital converter included, which works on a pulse evaluator, from which a relay is actuated, which the charging circuit of the respective Heizepeichergerätes closes.

Another problem with storage heating systems is that the insulating materials used for the heating storage devices are not the ones provided Meet requirements. With the usual insulating materials that are made of exist, and which are used in porm of panels, a surface temperature arises of about 120 ° C. On the other hand, if you use aluminum plates, wipe them there is a frame made of rock wool through which the panels are spaced apart are kept, the thermal insulation ii rest, however, exclusively by the there is air between the plates, so can the Reduce the surface temperature to around 600 C. The heat losses and thus also the unwanted discharge of the Heizspeicbergerätes are thereby to a minimum decreased. This in turn is important for the required charging time, since this decreased.

This in turn makes it possible to reduce the charging time to a greater extent Delay measures compared to the beginning of the low tariff period.

There are usually fans in every electrical storage device, the two known devices switched on and off by means of a thermostat will. Usually, such fans are tangential fans with a gap. pole squirrel cage motors. A completely uniform ventilation and thus a To achieve a uniform temperature, the performance or the speed of the motor is controlled depending on the temperature to be regulated. This control is expediently achieved by means of a differential amplifier, the changes in the to determined by a temperature-dependent resistance responsive to a regulating variable, d. H. the controlled variable with the setpoint using compares a potentiometer and amplifies the difference between the two quantities The analog value is then converted into needle pulses, the number of which per unit of time de> analog value is proportional. The pulses then become a power control part supplied that controls the voa motor to be consumed electrical power. Through this a variable-dependent, stepless speed control of the fan motor can be used achieve, which also has the advantage that no overheating of the motor winding as can occur with a voltage or current control.

The speed of the fan and thus the heat output of a storage heater is therefore the positive setpoint deviation over a certain range (speed-O-max.) proportional.

In Figures 1 to 10 of the drawings, the subject of the invention is shown on the basis of exemplary embodiments and explained in more detail below. It FIG. 1 shows a block diagram of an electric storage heating system according to FIG Invention; Fig. 2 is a block diagram of a mother device of the invention; Fig. Figure 3 is a delay diagram of the parent device of Figure 2; Fig. 4 is a block diagram a daughter device according to the invention; Fig. 5 is a delay diagram of the child device FIG. 4 FIG. 6a schematic circuit diagrams of the mother device; FIG. 6b Fig. 7 is a schematic Circuit diagram of a daughter device Fig. 8 is a block diagram of a speed controller for a Liiitermotor; 9a is a schematic circuit diagram of a speed controller 9b according to FIG. 8 and FIG. 10 shows a perspective illustration of an insulating plate of a heating storage device.

As FIG. 1 shows, there is a sheet metal storage heating system according to the invention from heat storage devices 11, each of which has a daughter device 12, a residual heat sensor 13, a thermal relay 14 and a heating register 15 contains. In addition, all heating storage devices are available for use a mother device 16 is provided with an outside temperature sensor 17 and a Main relay 18 cooperates.

At the beginning of the low tariff period, the flutter device 16 actuates after one Delay, which depends on the temperature measured by the temperature sensor 17, the main relay 18 and thus applies the Netzspaxtung to the various heating storage devices 1 . However, this means that the heating registers cannot start charging, since the relay 14 must first be actuated for this purpose. This is done using the Subsidiary devices 12, which are in operation immediately after the first delay time has elapsed be taken. The daughter devices evaluate the values supplied by the residual heat sensors 13 Measured values and determine the delay time, after which the relay 14 be operated.

Fig. 2 shows the block diagram of the parent device, which is an analog-to-digital converter 19 contains, which is connected to the outside temperature sensor 17 and which on a linpulse counter works. The change in outside temperature is detected by sensor 17 transmitted in the form of a voltage change to the analog-digital converter 19 and in this converted into impulses. The number of pulses per unit of time is the changing voltage proportionally.

When a certain sweet temperature is reached, i. H. at a certain Number of pulses per unit of time, the number of which is counted by a pulse counter 20 will, an x-th pulse is emitted by a pulse evaluator 21, which actuates the main relay 18, whereby the daughter devices are put into operation.

The analog-digital converter 19 is fed via a transformer 22 with a rectifier circuit and a voltage stabilizer 23 of the same Network with which the entire storage heating system is operated. The by the flutter device The delay achieved results approximately from the delay diagram in FIG.

At a temperature of -1.80 C the delay time is approximately 30 minutes and then increases to a temperature of + 18 ° C for 6 hours at.

As soon as the daughter devices are put into operation, they begin with the evaluation of the measured values supplied by the residual heat sensors 13. The evaluation takes place in a similar way to the mother device by means of an analog-digital converter 24 (Fig. 4), which generates pulses, the pulse sequence of which is that supplied by the residual heat sensor 13 Voltage is proportional.

The pulses are in turn evaluated by a pulse evaluator 25, which actuates the relay 14 by means of the first pulse, so that the charging circuit the heating register 15 is closed and charging can begin. The feeding of the analog-digital converter 24 takes place via a transformer 26 and a rectifier circuit again from the same network that supplies the entire storage heating system.

FIG. 5 again shows a delay diagram to which the delay time it can be seen, after the expiration of which a daughter device 12 is a relay 14 of a heating storage device 11 is actuated and its charging circuit closes. the Delay Time is about 1 minute at a measured residual heat temperature of +200 C and increases up to a temperature of 1000 C for 25 minutes.

FIGS. 6a and 6b show schematic circuit diagrams of the mother device. The outside temperature sensor 13, a PTC resistor, measures the outside temperature and determines the charging time of the capacitor C1, which is directly proportional to the outside temperature is. As soon as the charging voltage of the capacitor C1 reaches a certain value has, the UniJunction transistor T1 gives a via the amplification transistor T2 Impulse to the downstream flip-flops m (1 to FL 6 onwards.

At the same time, the capacitor C1 is discharged. This process is repeated constantly. The pulse evaluation takes place via the diode gate D1 to D6 and over the flip flops. At the xth pulse, the transistor T3 is switched through. In order to the bistable multivibrator T4, T5 tilts and switches the relay 18.

The entire system is now ready for operation.

7 shows a schematic circuit diagram of a daughter device. Of the Residual heat sensor 13, an NTC resistor, controls transistor T6. The charging time of the capacitor C2, which is determined by the transistor T6, is the residual heat directly proportional. As soon as the voltage of the capacitor C2 has reached a certain value reached, the UniJuCktion transistor T7 sends a pulse to the bistable Multivibrator T8, T9, which switches relay 14, so that the heating register is charged can begin.

FIG. 8 shows the block diagram of one indicated at 27 in FIG. 1 Speed controller, which is used to steplessly adjust the motors to each heating storage device to regulate the associated fan. The speed controller consists of a transducer 28, which records the temperature. The actual value is in the downstream differential amplifier 29 compared with the setpoint set and the resulting Difference is amplified. The output signal is sent to an analog pulse converter 30 in which the analog value of the difference is converted into needle pulses, the number of which per unit of time is proportional to the analog value. The impulses are supplied to the power control part 31, which the electric power of the fan motor 33 determined. A radio interference suppression device is located between the power control part 31 and the motor 33 32 switched. The speed controller is made up of a transformer 34 and a rectifier circuit fed from the network, which also supplies the rest of the system.

9a and 9b show a schematic circuit diagram of the speed controller of Fig. 8. The transducer 28 records the room temperature. Once the room temperature is greater than the target temperature, controls the transistors TlO and Til containing Differential amplifier 29 on the transistor T13. This increases the charging frequency of the capacitor C3. The unijunction transistor T14 generates needle pulses that over the transformer U to be carried to the triac T15, which controls the output power. The number of pulses per unit of time is proportional to the output power. the Choke L and capacitor C4 are used for radio interference suppression.

The insulating plate of Fig. 10 consists of two aluminum plates 35, which are kept at a distance from one another by means of a Steimrolle frame.

Claims (9)

P a t e n t a n t a n p r ü c h e 1. Procedure for automatic top-up of electrical heating systems with multiple heat storage devices during the low tariff period depending on the outside temperature and the residual heat of the individual heating storage devices, by the fact that a) the entire system during the low tariff period when the outside temperature falls below a certain level compared to the beginning of the low tariff period is switched ready for operation with a delay and that b) the heating storage devices opposite the start of operational readiness of the entire system depending on its respective residual heat can be put into operation with a delay. 2. The method according to claim 1, characterized in that g e k e n n z e i c h -n e t that the delay time, after which the entire system is ready for operation is, in a. Outside temperature range from about -18 ° C to +180 C for about 30 minutes up to about 6 hours. 3. The method according to claim 1 or 2, characterized in that g e k e n uz e i c h n e t that the delay time after which the heating storage devices are charged in a residual heat temperature range of + 20 ° C to 1o C for about 1 minute up to about 25 minutes. 4. Electronic automatic hoofloader to carry out the procedure according to one of claims 1 to 3, consisting of an outside temperature sensor, a Residual heat sensor in every heating storage device and a control device, which evaluates the measured values of the outside temperature and the residual heat sensor and the Charging of the heating storage devices is controlled by a central mother device (16) with a delay device for all heating storage devices (11), that the entire system when falling below a certain outside temperature switches to ready for operation with a delay compared to the beginning of the low season, and ae a daughter device (12) built into a heating storage device (11) with a delay device, each heating storage device (11) when the residual heat falls below a certain level switches on with a delay compared to the start of operational readiness of the entire system. 5. Automatic system according to claim 4, characterized in that g e k e n n z e i c hn e t, that the mother device (16) has an analog-digital converter connected to the outside temperature sensor (17) Contains (19), which works on a pulse counter (20), the counting of a Pulse evaluator (21) for actuating a relay (18) is evaluated, which is in the charging power supply network lies. 6. Automatic system according to claim 4 or 5, characterized in that it is e k e n nz e i c h n e t that each daughter device (12) is connected to a residual heat sensor (13) Contains analog-digital converter (24) which works on a pulse evaluator (25), from which a relay (14) is actuated, which the charging circuit of the respective Heizapeichergerätes (11) closes. 7. Automatic system according to one of claims 4 to 6, characterized g e k e n r. z e i c h n e t that the charging current path one of each heating storage device (11) via a from the mother device (16) actuated Uauptrelais (18) and one of the slave device (12) actuated relay (14) leads to the heating storage device (15), and that the supply line of the mother device (16) before the main relay (18) and the of each daughter device (12), behind the main relay to the charging current path of the Heating storage device (11) is connected. 8. Insulation plate for thermal insulation of heating storage devices, g e not shown, by means of two plates made of aluminum, which by means of a frame made of rock wool are kept at a distance from each other. 9. Speed controller for fans of heating storage devices, g e k e n n z e i c h e t by a transducer (28), a differential amplifier (29), an analog pulse converter (30), a power control part (31), and a radio interference suppression device (32).