DE2442924A1 - Control for electrically heated windscreen - measures current through embedded heating wires and switches it off when it exceeds threshold value - Google Patents

Abstract

The glass screen with its embedded heating wires is connected across a 220V AC supply, in series with the primary of a transformer and a heavy duty switch which consists of a triac. An RC circuit is connected in parallel with the triac. The secondary of the transformer is connected to a rectifier network, which supplies DC to a system of capacitors and resistors, some of which are variable. There is a second transformer in parallel with the heated glass screen connected to a voltage divider. When the current passing through the heating wires reaches a predetermined limiting value, the triac is switched off.

Description

Electrically heated glass pane with a heating current regulating it Switching device The invention relates to an electrically heatable pane of glass with one or more electrical heating resistors and one regulating the heating current Switching device that depends on the temperature-dependent change in resistance of the heating resistors is controlled.

The regulation of the stimulation current is particularly important in the case of transparent heating panels Made of laminated glass important to prevent damage to the thermoplastic interlayer as a result to avoid overheating. The heating resistors are namely within or next to the thermoplastic intermediate layer, and overheating of this intermediate layer can lead to permanent streaks or other defects such as blistering, peeling etc., which interfere with the review. On the other hand, it can also be used with other heating disc systems, in which the heating resistors are not within a thermoplastic intermediate layer are arranged, but directly on the glass surface itself, in some cases a regulation of the heating current must be extinguished in order to reduce energy consumption or to avoid overheating.

It is known in the case of laminated glass panes with inserted resistance wires to provide a control device for the stimulation current, which, as in. the known Bridge circuits, from the temperature-dependent change in resistance of the Her wires is controlled (DD-PS 907 971).

Measurement and control systems of this known type with the aid of a bridge circuit to measure the electrical resistance require a relatively complicated Construction and are correspondingly expensive. In practice, therefore, other temperature control systems have proven enforced, all of which are constructed so that an additional temperature sensor is provided, which is used to control the control device.

Electric heating disks of this type are z. See, for example, U.S. Patent 2,932 710, and in the DU-OS 2 221 o55, 2 248 o94 and 2 350 404.

Heating discs with an additional temperature sensor as a neuter limb for the control loop, however, they are not without their disadvantages. So disturbs z. B. that the Temperature sensors usually sit inside the glass pane. If for any reason Tear off the connecting wires or if the temperature sensor itself is damaged and loses its functionality, the control function can usually not be restored because the temperature sensor cannot be removed or repaired without that the glass is destroyed.

Based on the principle mentioned above, for temperature measurement a heated glass pane no additional wet member to provide, but the To use the change in resistance of the heating resistor itself as a measured variable, lies the invention is based on the object to provide a control device that is simple and robust in construction, and is consequently inexpensive to manufacture, operationally reliable, and can be used for the various heating disc systems.

According to the invention, this object is achieved in that the Switching device regulating the heating current is an electronic circuit that controls the heating resistors The current flowing through is measured when it falls below an adjustable limit value turns off the heating current, and includes an electronic clock timer, the when the heating current is switched off, the heating current is briefly set at predetermined time intervals switches on and periodically restarts the measurement and control process.

By turning away from the actual resistance measurement of the heating resistors the complicated bridge circuit becomes through a much simpler current measurement replaced by the change in the heating current flowing through the heating resistor the temperature of the heating wires is inferred. When switched off, then the heating current is switched on periodically for a short time, then remains switched on, when the temperature of the heating resistor has fallen below the set value and switches off again after a short time if the temperature is set Has not yet fallen below the setpoint.

In an expedient embodiment of the invention are used to measure the The current flowing through the heating resistors is connected to one in series with the heating resistors switched resistance proportional to the changes in the heating current occurring Spcamiungszüge for the control of the disconnection of the heating current Operational amplifier.

The measuring voltage, after rectification, becomes the in-uerting Input of the operational amplifier zugefunrt while on the non-inverting Input of the operational amplifier is a fixed voltage.

It is also useful that the measurement voltage is connected to the inverting input of the operational amplifier with the interposition of a voltage divider where the voltage divider is used as a setting element for the maximum setpoint temperature the pane of glass is used.

With the current measurement that can be used, it is not just the changes in resistance that work the heating resistors, but also voltage fluctuations in the supply network in the Measurement a. This disadvantage can be eliminated by reducing the supply voltage is stabilized. In order to avoid the effort required for this, in particular advantageous development of the invention of the operational amplifier switched so, that its tilting behavior changes depending on the network voltage fluctuations, so that the effects of current fluctuations caused by mains voltage fluctuations be compensated by shifting the tipping point.

Further details of the invention emerge from the following Description of a preferred embodiment for a heating disk control according to the invention.

The exemplary embodiment is explained using two circuit diagrams. 1 shows the block diagram of the new heating disk regulator, and FIG. 2 the electronic circuit diagram of the actual control part in a detailed representation.

The electrically heated glass pane 11, which is shown in the circuit diagrams is only shown schematically, is normally a transparent laminated glass pane made of two panes of silicate glass and one between them thermoplastic intermediate layer, usually made of polyvinyl butyral.

There are thin resistance wires in this thermoplastic intermediate layer inserted as heating elements, which may be combined in groups via common busbars, and are connected to the power supply at terminals 12, 13. Instead of clear Glass panes can of course also be opaque glass panes, for example bathroom mirrors or traffic mirrors. Always when It is important to electrically heat a glass surface from a layer of moisture or to keep clear of atmospheric precipitation such as rain, ice or snow, the invention is applicable. The heating conductors do not necessarily need to be used to be arranged within the thermoplastic intermediate layer, but can also sit on a surface of the pane of glass itself. Or it can be used instead Conductive metal or semiconductor layers are also provided for by resistance wires be.

In the illustrated circuit example, the heatable glass pane is 11 connected to the AC mains of 220 V. The heating current is with the help of the electronic Bite switch 14 automatically switched on and off.

As is apparent from Fig. 1, the electronic circuit comprises the following parts, the structure and function of which are described in detail below: the power section A, the voltage supply section B, the control section. C, the control group for triac D, as well as the actual control part E.

The power section A, connected in series with one another, has the heating disk 11, the Priinrwickl.aiig 15 a choke, and the electronic circuit breaker 14 in the form of a triac.

Parallel to the electronic circuit breaker 14 is one from the Resistor 16 iind the capacitor 17 existing RC element as overvoltage protection arranged for the electronic circuit breaker 14. The one between the clamps 18, 19 of the primary winding 15 of the choke occurring voltage drop in the circuit the heating disk is proportional to the current flowing in each case, which in turn is proportional to the instantaneous resistance of the heating elements and thus the temperature of the Heating disk depends.

Instead of a choke with primary and secondary windings, the one Galvanic isolation from the electric circuit of the heating panel is allowed, if necessary a simple choke or a shunt can be provided. Requirement when using a Throttle is, however, that the working range, seen in terms of magnetization, is in the linear range lies.

The measured at terminals 20, 21 of the secondary winding 22 of the choke Voltage is directly related to the heating current.

Via the downstream rectifier 23 together with the sieve chain, the AC voltage rectified. The rectified Neßspannung is over the Voltage divider 24 and the resistor 25, the inverting input 4 of the operational amplifier 27 of type TAA 761 supplied. I) he voltage divider 24 serves as an adjusting element for the temperature adjustment, i.e.

it can be used to set the temperature at which the heating disc should be operated.

Via the non-inverting input 3 is the operational amplifier 27 through the resistors 28, 29, 31 and the adjustable resistor 30, a setpoint value given. Now decreases as the heating panel heats up as a result increasing the electrical resistance of the heating conductor increases the voltage at the inverting one Input 4 so that it becomes lower than the setpoint at the input 3, then occurs at output 7 of the operational amplifier, which was previously at zero potential lay, a voltage which is supplied to the logic module 34 in the control part C as a control signal is, via the logic module 34 and the control group D is consequently the electronic circuit breaker 14 switched off in the form of a triac, and thereby the heating circuit interrupted.

The dividing ratio of resistors 29, 30 and 31 on the non-inverting one The input in connection with the supply voltage U5 or Vc determines the breakover threshold of the operational amplifier. Since the breakover threshold is fixed, it results an automatic shift of the breakover threshold according to the net voltage fluctuations, whereby the changes in the Measurement voltage at input 4 of the operational amplifier can be compensated. It can In this way, mains voltage fluctuations of + 10% of the nominal value can be accepted, without the accuracy of the temperature measurement and control suffering. With With the help of the adjustable resistor 30, the switching point is set to the desired value set.

The switching hysteresis of the operational amplifier depends on the Divider ratio of resistors 28 and 32 and resistors 29, 30 and 31.

The control part C has an electronic timer 35, the at constant time intervals via the amplifier 35 and the ignition relay 37 the auxiliary switch 14 turns on for a short period of time. The cycle time can be changed using the Set resistance 38. The electronic timer 35 is, for example designed so that the circuit breaker is switched on at intervals of about 10 seconds will. Is the heating resistor still too warm, so the circuit breaker will be 14 directly, i.e. in fractions, via the regulation and control section described above a second, turned off again.

After a further 10 seconds, the circuit breaker is switched on again 14, and the cycle of periodic temperature polling repeats until the The temperature of the heating resistor has fallen below the set value, and the power switch 14 remains on as a result.

The voltage supply part B is used to control part E and the Control part C including the control group D for the triac with the necessary operating voltage to supply.

With the help of the transformer 41, the supply voltage is the Taken from the mains and rectified via the rectifier 42.

The operational amplifier is controlled via the controllable voltage divider 43 27 driven with the non-stabilized voltage to, as mentioned above, the to compensate measuring voltages caused by network fluctuations. The control part and the electronic clock timer, on the other hand, are via the voltage stabilizer 44 is supplied with a constant voltage of 15 V.

Claims (5)

Claims 1. Electrically heated pane of glass with one or more electric Heating resistors and a switching device regulating the heating current, which is controlled by the temperature-dependent change in resistance of the heating resistors is controlled, d a d u r c h g e k e: n n z e l c h n. e t that the switching device regulating the heating current an electronic circuit that controls the current flowing through the heating resistors measures and switches off the heating current if it falls below an adjustable limit value, as well as an electronic clock timer, which when the heating current is switched off turns on the heating current briefly at predetermined time intervals and the wet and periodically restarts the control process 2. Electrically heated glass pane with Schairvarrichtung according to claim 1, characterized in that ,. that; for measurement of the current flowing through the heating resistors at one in series with the heating resistors The set resistance is proportional to the changes in the heating current that occur Voltage changes for controlling an operational amplifier that causes the shutdown to serve 3. Electrically heatable glass pane with switching device according to claim 1 and 2, characterized in that the measuring voltage, possibly after rectification, is fed to the inverting input of the operational amplifier, while on the non-inverting input of the operational amplifier is a fixed Tension lies. 4. Electrically heatable glass pane with switching device according to claim 3, characterized in that the measuring voltage the inverting Input of the operational amplifier with the interposition of a voltage divider is supplied, the voltage divider as a setting element for the maximum setpoint temperature the pane of glass is used. 5. Electrically heatable glass pane according to claim 1 to 4, characterized by an operational amplifier, the tilting behavior of which depends on the mains voltage fluctuations changes, so that by the mains voltage fluctuations The effects of the current fluctuations caused by this can be compensated for. L e r s e i t e