DE2803951A1 - Electrical flowing water heater - has resistance element exposed uninsulated to water and monitors conductivity of water for safety - Google Patents

Abstract

The flow heater, for water, monitors the electrical conductivity of the water it is heating by using two electrodes (13, 14) in the channel (9) through which the water is flowing. The water is heated with a resistance element exposed to it, i.e. not electrically insulated from it. A d.c. voltage derived from the mains (R) is applied across the electrodes. One electrode (13) is connected to a comparator that compares the resistance between the electrodes with a reference and switches off the heating current at a given point, protecting users in those areas where the mains water has esp. high conductivity.

Description

Electric water heater with at least one

Bare wire heating element The invention relates to an electric water heater with at least one bare wire heater and at least one water-carrying channel.

The current-carrying bare wire heater is located in such instantaneous water heaters without electrical insulation in the water.

The water itself is under tension, so that a leakage current in it flows according to its electrical conductivity. To the user not too endanger are walls with high insulation resistance and a water supply section and a water run-off section with non-conductive walls is provided.

There are applications in which tap water is particularly high electrical Has conductivity. In spite of the leading and trailing lines, this can be used Cases the user will be at risk if he is in contact with the electrically strong conductive water comes. The user cannot take any precautions on his own initiative hit, because even if he knows the function of the water heater, the can hardly determine the specific electrical water resistance.

Provide specific instructions to the water heater installer would have the disadvantage that compliance with them can only be monitored poorly and that, by the way, the specific electrical resistance of the tap water offered after installing the water heater.

The object of the invention is therefore to provide an electric water heater in which the electrical conductivity of the tap water is monitored will.

According to the invention, the above object is achieved in that in the channel two electrodes are arranged, the distance between which forms a resistance path that A direct voltage derived from the mains voltage of the heater is applied to the electrodes is placed and that one electrode is connected to an electronic comparison circuit, that when the resistance value of the resistance path falls below a minimum value emits a shutdown signal. Between those in the water lying electrodes flees an auxiliary current, the size of which depends on the specific electrical resistance of the respective water. As soon as the resistance falls below a minimum value, a shutdown signal is triggered. This can either be an optical signal or a shutdown of the continuous heater.

In a simple embodiment of the invention, an electrode can be connected to ground lie. The auxiliary flow increases the total discharge flow of the flow heater. If the permissible leakage current is exceeded as a result, they are preferred Embodiment of the invention, the electrodes derived from one of two phases of the network DC voltage connected. In this case, that between the electrodes increases The auxiliary current flowing does not affect the leakage current.

In a preferred embodiment of the invention, the electrodes are in the flow line of the water heater arranged. This puts them in front of the corrosive Influence of the bare wire heating element protected.

Further advantageous refinements of the invention emerge from the following description. In the drawing: FIG. 1 shows a flow heater schematically in section and FIG. 2 shows a circuit for monitoring the specific electrical resistance of the water in the water heater according to FIG. 1.

In a housing 1 of the water heater are three chambers 2, 3 and 4 formed, in which bare wire heating elements 5, 6 and 7 are arranged. These lie on the one hand at the phases R, S, T and on the other hand at the ground pole Flip.

The chambers 2 and 3 are connected to one another via a channel 8 at the top. The chamber 3 opens at the bottom into an annular channel 9 which leads into the chamber 4 at the top. A water supply line 10 is connected to the bottom of the chamber 2. Out of the chamber 4 leads a water supply line 11.

The walls of the feed line 10, the follow-up line 11 and the Channels 8, 9 are made of an electrically non-conductive material. The channels 8 and 9 extend the water path between the chambers and thus set the to the Voltage poles of the bare wire heating elements 5, 6, 7 possible electrolytic erosion down. The lengths of the feed line 10 and the follow-up line 11 are dimensioned so that that in the case of water they have a typical specific electrical resistance of Reduce the potential at the end of the line 10 or 11 so that there is a risk of the user is excluded.

In the housing 1 is an electrode carrier 12 with two electrodes 13 and 14 screwed in. The electrodes 13 and 14 are located in the annular channel 9.

The electrical circuit of the electrodes 13 is shown in FIG. 2 and 14 shown. The voltage pole R is a capacitor 15 and a rectifier diode 16, as well as a filter capacitor 17 connected downstream. Parallel to the filter capacitor 17 there is a Zener diode 18. These components form a rectifier for the phase R. The electrode 13 is connected to one pole of the Zener diode via a series resistor 19 18. In parallel with the Zener diode 18, there is a voltage divider made up of resistors 20 and 21. The tap of the voltage divider is at one input of an operational amplifier 22, for example an operational amplifier with the type designation RuA 741 is. The electrode 13 is connected to the other input of the operational amplifier 22. At the output of the operational amplifier 22 there is a winding 23 of a relay a switching contact 24. A diode 25 is connected in parallel with the winding 23. aside from that a counter-coupling resistor 26 is provided for the operational amplifier 22. The electrode 14 lies like the resistor 21, the Zener diode 18 and the filter capacitor 17 at the ground pole Mp or at the phase S.

The relay contact 24 is located in the control device, not shown in detail of the water heater that it switches it off. It is beneficial that the switch contact 24 compared to the rest of the circuit is potential-free. With a hydraulic 'means A flow heater controlled by a differential pressure switch can be used by the relay contact 24 be connected upstream of a solenoid valve in a bypass of the differential pressure switch lies.

The circuit described is set so that when the specific electrical resistance of water is in the usual range, between the water resistance occurring between the electrodes 13 and 14 is equal to the resistance 21.

In practice this value will be 1 - 4 kfl. The circuit according to FIG. 2 has no influence on the function of the water heater in this case.

If then the water heater with water with a particularly low specific electrical resistance is used, is that between the electrodes occurring resistance value correspondingly smaller. As a result, the operational amplifier 22 emits a shutdown signal. The contact is made via the relay winding 23 24 closed and the water heater switched off.

During the operation of the water heater flows through the voltage divider 20, 21 and via the resistor 19 and the one between the electrodes 13 and 14 Resistance path current. If the circuit according to FIG. 2 is connected to the ground pole, add this current becomes the leakage current of the device.

If this exceeds the permissible value, the circuit will placed between two phases R and S according to FIG.

The invention is not limited to the illustrated embodiment. If the circuit is between a phase and the ground pole, the electrode 14 from a metal part of the water heater.

An optical signal is sufficient to indicate a particularly low level electrical resistance of the water, then instead of the relay winding 23 a light emitting diode is provided.

Instead of the relay, a triac can also be provided.

Relays or triac can be saved if that is the water heater disconnecting component, for example said solenoid valve, directly to the operational amplifier is connected downstream.

A transformer can also be used to decouple the electrode 14 from the ground pole be provided.

The electrodes can also be arranged in the feed line 10. You are not exposed to fluctuating water temperatures. The electrodes but can also be accommodated in other channels of the water heater.

They will be placed in such a way that they are separated from the voltage poles of the radiators are as far away as possible.

Claims (7)

Claims Electric RIrchlauferheater with at least one Blanlcdraiithei zkörper and at least one water-bearing channel, characterized in that, that in the channel (9) two electrodes (13, 14) are arranged, the distance between them being a resistance path forms that to the electrodes (13, 14) one of the mains voltage (R) of the heater derived direct voltage (15-18) is applied and that an electrode (13) on one electronic comparison circuit (22) is located, which falls below a minimum value at a Resistance value of the resistance path emits a switch-off signal. 2. Electrical water heater according to claim 1, characterized in that that an electrode (14) is on let (Mp). 3. Electric water heater according to claim 1 with three-phase switched brass wire heating elements, characterized in that the electrodes (13, 14) are connected to a direct voltage derived from two phases (R, S). 4. Electrical water heater according to one of the preceding claims, characterized in that the comparison circuit comprises an operational amplifier (22) has, at one input of which is a voltage divider connected to the direct voltage (20, 21) and one at the other entrance Electrode (13) connected is, which is via a series (19) resistor to the one DC voltage pole. 5. Electrical water heater according to one of the preceding claims, characterized in that an indicator lamp at the output of the operational amplifier (22) lies. 6. Electrical water heater according to one of the preceding claims 1 to 4, characterized in that at the output of the operational amplifier (22) a Relay winding (23) or a triac is located. 7. Electrical water heater according to one of the preceding claims, characterized in that the electrodes (13, 14) in the flow line (10) of the Water heater are arranged.