DE2441529B2 - METHOD AND DEVICE FOR MONITORING A CHARGING CONTROL DEVICE FOR A STORAGE HEATING SYSTEM CONSISTING OF MULTIPLE STORAGE HEATING DEVICES - Google Patents

Description

The invention relates to a method of the type specified in more detail in the preamble of claim 1 as well as a device for carrying out the method.

There are numerous storage heating systems known, for example from DT-PS 17 65 984, in which the entire system is controlled depending on the outside temperature and the time and this Central control an individual depending on the respective conditions on the individual storage heater

regulation is superimposed.

In the charging control for one or more connected to a common control device night storage heaters, there is a risk daP in the connecting lines by a Witteri, _ngs .F _u h | _he and from the timing element to the central control device interruptions or short circuits can occur as well as in the common central control device; to dei 'individual storage heaters and their charge controllers, which detect the respective residual heat and control the start of the charging process in accordance with the weather component and, if applicable, the time component and the respective residual heat. In the case of the storage heating systems that have become known since then, the associated devices were designed by all manufacturers in such a way that, in the event of a malfunction of the type described above, the storage heaters are fully charged as far as possible (positive interference behavior). Recently, however, efforts have been made in the electricity supply companies to avoid the undesirable heavy load peaks resulting from positive interference and consequently from changes in the charging characteristics. One would therefore like to design the charge control in such a way that it does not cause a charge in the event of a fault (negative interference behavior).

The invention is based on the object of a method and a device of the type mentioned at the beginning Kind of creating a monitoring of the foot all storage heaters provided central control unit and, if necessary, for individual groups of Storage heaters additionally provided group control devices, their wiring and the inputs the charge regulator of the individual storage heaters allows for malfunction and incorrect installation.

The sub-task aimed at creating a method is achieved according to the invention by the im Characteristics of claim 1 specified features solved.

Advantageous further developments of the method according to claim 1 are characterized in claims 2 to 10.

The sub-task aimed at creating a device is achieved according to the invention by the im Characteristics of claim 11 specified features solved.

Advantageous further developments of the device according to claim 10 are given in claims 12 to 17 marked.

The technical progress achieved by the invention results from the solution to the problem.

The invention is explained in more detail below with reference to the drawing. It shows

Fig. 1 shows a storage heating system with several storage heaters, which are combined in groups and are each connected to a monitoring device,

F i g. 2 shows a section from the block diagram according to FIG. 1 with one of the central monitoring device controlled heavy current contactor to which several of their associated group monitoring devices are controlled Power contactors are connected,

F i g. 3 shows a time circuit diagram for changing the control voltage Ust provided there as a control variable, which contains a constant basic voltage component.

4 shows a modified embodiment with a central monitoring device in which the bulls in a central control line serve flowing current components,

F i g. 5 a further, modified embodiment in which the central monitoring device with is assembled and integrated into a central control unit,

F i g. 6 shows a further modified exemplary embodiment in which the monitoring device, in addition to FIG The control variable supplied to the central control unit is fed directly to another control variable which

ίο contains more information on how to recharge For example, information about the line voltage and / or line load, and

F i g. 7 shows a circuit diagram for an exemplary embodiment of a monitoring device which has two Contains threshold value switch and a relay with corresponding output contacts.

In the storage heating system according to FIG. 1, four storage heaters, not shown in detail, are provided, which, depending on their residual heat, can be connected to a high-voltage network with the help of one of the four charge controllers 11, 12, 13 and 14, each assigned to a storage heater, during the low tariff period (NT).

The two charge controllers 11 and 12 and their associated storage heaters are combined to form a first group and are controlled via a first group control unit 15 by a central control unit 19 as a function of the outside temperature and by the timing element 21 in such a way that the start of charging occurs when reverse control is required the later the time after 10 p.m. the higher the outside temperature and the greater the residual heat in the associated storage heater. In the same way, the two charge regulators 13 and 14 belonging to the second group are connected to the output voltage of the second group control device 16. A first group monitoring device 17 is provided for monitoring the output control voltage of the first group control device 15, while a second monitoring device 18 is connected to the second group control device 16. Both group control devices are at the output of the central control device 19, whose output voltage serving as the control voltage Ust for the group control devices 15 and 16 contains two voltage components in the manner customary since then, of which the first through a weather sensor 20 and the second through a smaller as the time progresses will be generated DC voltage component, which is set by the timer 21. The control voltage L / srist taken at the output terminals Z 1 and Z 2 is fed to a central monitoring device 22. This monitoring device, like the two group monitoring devices 17 and 18 connected to the group control devices 15 and 16, contains a threshold value switch not shown in detail. Each of the threshold switches contains one of the three switching arms 24 or 25, 26. These pebbles are each inserted into a release line 28. The release line is energized at the start of the low tariff period. The switching arm 24 of the central monitoring device 22 is connected to a central contactor 31 in series, the switching contacts of which are in the course of a power line 30 and are then opened when due to a fault in the weather sensor 20, in the timer 21, in the central control device 19 or one of the control lines 32 (due to interruption or short circuit) the control voltage

is not within a specified working range according to Fig. 3. For this purpose, the temperature-dependent voltage component supplied by the weather sensor 20 and the time-dependent, time component supplied by timing element 21 adds a basic voltage, which of these two Control variables is independent, but for example on the level of the voltage in the power lines 30 and / or their load may be dependent.

The switching arm 25 of the group monitoring device to 17 is in series with a first group contactor 33, its switching contacts in the closed state the storage heaters belonging to the charge controllers 11 and 12 Supply with heavy current during the NT period. In the same way, the switching arm 26 is the second Group monitoring device 18 connected to a second group contactor 34, which is connected to the storage heaters the charge regulator 13 and 14 leads. The two group contactors 33 and 34 work in parallel to each other, as shown in FIG. 2 and are in series with the switching contacts of the central contactor 31.

While in the charge control according to FIG. 1 and 2, the control variable to be monitored is used in the form of a control voltage, is shown in the exemplary embodiment according to FIG. 4 is used as the variable to be monitored for the control current Ist flowing in each case in the control lines 32. The weather-dependent current component supplied by the outside sensor 20 is here a current component determined by the timing element 21 which, for example, becomes smaller as the time progresses, and a third direct current component independent of these two is superimposed. If the sum of these current components falls below a predetermined lower threshold value or exceeds an upper limit value, the monitoring device 36 responds, its switch 37 opening and the downstream central contactor 38 dropping out, thereby centrally interrupting the supply of night power to the storage heaters.

In the modified embodiment shown in FIG. 5, a central monitoring device 39, which either has to monitor the control voltage Ust like the monitoring device 22 or the control current Ist like the monitoring device 36, is structurally combined with the central control device 19. This results in a smaller space requirement and the same protective effect as with an embodiment in a separate housing. In the illustrated embodiments according to FIG. 1 to 5 it is provided that the monitoring devices 17, 18, 22 or 36 and 39 switch the entire system to negative interference behavior in the event of the smallest disturbance occurring in the control system, because they then connect the power line 30 to the charging regulators 11 to 14 and their associated storage heater by opening the contacts of the contactors 31,33,34,38 and 40 interrupt. Then the storage heater cannot be charged in the event of a malfunction. With the monitoring devices, however, additional functions can optionally or alternatively be triggered, for example full charging in the event of positive Störverhaltcn, triggering of a warning signal, e.g. B. a lamp or a buzzer, also an emergency operation of the Spcichcrhcitgcrätc in the manner described above. ' ¹ p

In Fig. 6 is the weather sensor 20, the central control unit 19 and the Zcitglicd 21 together with the Stcucrlcitung 32 and the common monitoring device 22 shown.

Additional information about the mains voltage is sent to the monitoring device via additional terminals and / or the network load entered. This can, for example, depend on the oil temperature of the Local transformer dependent size. It can also be a reference variable dependent on the current transformer this second input of the monitoring device 22 are fed. The monitoring device 22 has thus at least two inputs, of which the first input is led by the central control unit 19 and the second and possibly further additional inputs through additional information for charging can be influenced.

The monitoring device shown in Figure 7, for example, consists of two threshold switches and has a common input Zl, which is fed via a high-resistance resistor R 3 to the first threshold switch, which consists of the transistors T1 and T2 with the resistor and diode combinations R 1 R 2 , D 1 and R4, R5 and R 6. The second threshold switch comprises the operational amplifier OPX and the resistor-diode combination RX, R 2, DX and the tap of the potentiometer P1 connected to the non-inverting input of the operational amplifier, as well as the resistors R 10, Ä9 and Λ 8, from where the resistor Λ10 is connected to the common plus line 50 fed by a transformer Tr and a diode D 4, whereas the Vv'kici stood /? 8 is connected to the common minus line 51. The resistors R 4 and R 10 of the first and second threshold value switches are used for positive feedback and lead to a sudden switching through of the threshold value switches. Like the second threshold switch described above, the first threshold switch can be designed as an operational amplifier and, like the second operational amplifier, can be constructed discretely. It is also conceivable that both threshold switches are constructed directly or in the form of operational amplifiers. One of the two threshold switches is used to define the first limit of the valid work area, whereas the other defines the second limit of the work area.

In the embodiment shown, the first bridge comprises a first branch RX, R 2, DX and a second branch R 10, R 9, P1 and R 8 and is used to determine the lower limit of the intended working range. The second bridge comprises a first branch R 1, R 2 and D 1 and a second bridge branch of R 4, R 5, R 6, and serves to define the upper limit of the working range. Both bridges have a common voltage divider, which consists of RX, R2 and Dl. The inserted diode DX is used to compensate for the temperature response of the Zener diode D 3 of the mains voltage supply by appropriate design of the resistors RX and R 2 and to make the circuit independent of ambient temperature fluctuations.

When the specified working range is left, the relay Rc / drops and interrupts, for example, the power supply to the charging contactor of the storage device, which is now connected to the relay contact r 1. When the relay has dropped out, the relay switches to the normally closed contact rl , to which a signaling device, which is not shown, is connected for issuing a fault message.

The circuit described works intrinsically safe, ie that with the most common sources of error, such as failure of the transformer Tr, the power supply, the relay ReI and the like, the relay ReI drops out, and a fault message is thus issued in the manner described.

The power supply of the monitoring device , consisting of the transformer Tr, the diode D 4, the capacitor C2 and possibly the resistor RIl with the stabilizing diode D3 (Zener diode), can be part of the monitoring device as an integrated power supply, as shown in Figure 7 .

The capacitor C 1 attached between the base and collector of the transistor T2 is used to suppress interference voltage. The arranged as a flip-flop circuit of the transistor T1 and the transistor T2 has the

Task of influencing the operational amplifier OPX, which works as a Schmitt trigger, via the collector resistor R7. The diode D 2 connected to the line 50 in the reverse direction serves as a freewheeling diode for the output of the operational amplifier OPX.

An independent battery can also be used to power the monitoring device will. Furthermore, an embodiment is conceivable that as

ίο Power supply of the monitoring device the Base voltage of the control voltage output by the central control unit is used. It is here too possible, the basic voltage of the central Steuergerä tes to power the charge controller or controllers zi

is use.

For this purpose 3 sheets of drawings

Claims (17)

2441 529 claims: 1. A method for monitoring a charge control device consisting of a central control device, possibly existing downstream group control devices and the charge control devices connected to the central control device or the group control devices for a storage heating system consisting of several storage heaters, the storage heaters being controlled jointly by means of an electrical control variable which contains at least one of the outside temperature weather-dependent component as well as additional components clock, network voltage, network load, transformer oil temperature, Ge by ₅ indicates that the control parameter with an upper and a lower limit value is compared to a predeterminable working area, and that a monitoring command is triggered when the control variable exceeds or falls below one of the limit values of the working range. 2. The method according to claim 1, characterized in that the limit values of the working range are adjusted by means of a further control variable which is independent of the first control variable. $ ₂ 3. The method according to claim 2, characterized in that the further manipulated variable of the Mains voltage and / or the amount of network load of the storage heater (s) supplying network is dependent. 4. The method according to any one of claims 1 to 3, characterized in that as components of the Control variable DC voltages or DC currents are used. 5. The method according to any one of claims 1 to 4, characterized in that when exceeded of the upper limit value the charging power of the storage heater (s) is reduced. 6. The method according to any one of claims 1 to 4, characterized in that when falling below of the lower limit value, the charging power increases, especially in the direction of full charging is increased. 7. The method according to claim 5 or 6, characterized in that the task of a monitoring command is displayed optically or acoustically. 8. The method according to claim 7, characterized in that when a monitoring command is issued is switched to emergency operation. 9. The method according to claim 8, characterized in that in emergency operation only in the first night After a monitoring command has been issued, it is recharged, but then automatically Charging is suppressed. 10. The method according to claim 9, characterized in that a charge after the first night is initiated only for one further night by additional measures, in particular a manually triggered control command. 11. The device for performing the method according to one of claims 1 to 10, with a monitoring device having a threshold value switch, characterized in that the monitoring device further contains an operational amplifier (QPi) , at the output of which a relay (Re!) Is connected, which is in such a way is designed that it enables the power supply to a charging contactor of a storage heater only in the energized state. 12. The device according to claim 11, characterized in that the winding of the relay (ReI) ii series with a resistor (R 10) is connected to eim power supply line (50) so that between the winding and the resistor eir feedback resistor (R 9) branches off , with which a potentiometer (Pi) connected to its tap on the non-inverting input of the operational amplifier (OPl) is connected to the other power supply line (5lf). 13. The device according to claim 12, characterized in that the inverting input (minus input) of the operational amplifier (OP \) is connected to a control line (Zl) via a protective resistor (R 3). 14. The device according to claim 13, characterized in that the base electrode of a transistor (T 11) is connected to the inverting input (minus input) of the operational amplifier (OPi) , which has its emitter electrode at the junction of two resistors (RS, R 6 ) is connected, which together with a further resistor (R 4) form a voltage divider located between the two power supply lines (50, 51), and that the base electrode of a second transistor (T2) is connected to the Koüektorelectrode of the transistor (Ti) , which is connected with its emitter electrode to the second tap of the voltage divider (R 4, R 5, R 6) and on its collector electrode with a resistor (R 8) connected to the second operating current line (51) and the potentiometer in series with it (Pi) is connected. 15. The device according to claim 14, characterized in that the collector electrode of the second transistor (T2) is connected to the resistor (RS) and the potentiometer (P 1) via a series resistor (R 7). 16. Apparatus according to claim 14 or 15, characterized in that a bridging capacitor (Ci) is arranged parallel to the base-collector path of the second transistor (T2). 17. Device according to one of claims 11 to 16, with several monitoring devices, characterized in that each monitoring device contains its own power supply with a rectifier (D4) and a smoothing capacitor (C2) and a stabilization stage, which consists of one in series with one Zener diode (D 3) arranged resistor (R 11) consists.