DE3436140C2 - - Google Patents

Description

The invention relates to a hot water run with a channel through which water flows pointing housing, in which the wall of the channel a material that does not conduct electricity exists and in one section of this channel one of arranged electrical heating coil and with a lack of water safety device, which depend on the electrical conductivity of the water contained in the flow channel the heating current controls the heating coil, whereby to detect the elec trical conductivity a sensor is provided, the comprises two electrodes lying in the water flow, from which one of the two electrodes is the heating coil is.

In the known devices of the type in question, for example a device according to DE-Gbm 79 16 786, the heating current of the heating coil is switched on with the help of a water-pressurized, under which Water pressure deformable membrane and one of these ge controlled switching element. With such hot water However, the heating current of the heating coil becomes instantaneous heaters switched on even if there is gas or air bubbles and the heating coil is not or is not completely in the water flow. this leads to very rapid overheating and destruction the heating coil. The creation of such gas or air blowing is primarily based on shutting off water wiring harnesses on the occasion of assembly or repair work on the water pipe system.  

As has become known from DE-OS 15 65 130, tried to counter the disadvantage mentioned by: provided a water shortage safety device by the electrical conductivity of the water to be heated is controlled. To this end, it has been proposed parallel to that of the heating coil and from Water flowing through an additional water-carrying pipe Provide pipe that has a much smaller interior has diameter and as a bypass above the am highest point of the heating coil or a lot number of heating coils is arranged. One of the two Sensor electrodes for recording the electrical conductivity speed of the water is the heating in the upstream end spiral behind the bypass junction and the second sensor electrode in the end area of the bypass tube at its highest Place arranged. The conductivity is thus measured a relatively large or long water bridge, which due to the air pockets in the narrowing area of the bypass inlet is to be interrupted in order to to operate the water shortage safety device.

With the interruption of the water bridge, this also takes place the interruption of the heating current. To ensure, that the interruption of the heating current at least as long lasts like the air inclusions flowing past the Heating coil, is in addition to reducing the cross-section at the bypass entrance downstream behind the bypass junction a throttle is provided and the inner surface of the bypass roughened to delay the flow in the bypass.

In addition to the complicated structure of the known water deficiency safety device using a Bypasses is another major disadvantage of  that the air bubble gets stuck at the bypass entrance, so that the water bridge between the two sensor electrodes Duration is interrupted. Regardless, that's again switching on the heating current even with less electricity well-conducting types of water are not guaranteed.

The invention has for its object a water deficiency Safety device for hot water instantaneous water heater to create the type in question known kind in such a way that even in If gas or air bubbles leak inside the destruction of the current system Heating coil is avoided with certainty and a through conditional heating current shutdown is only brief, so that reliable operation of the device in question is guaranteed over a long period of time.

This object is achieved according to the invention by the features of claim 1 solved.  

Further refinements of the hot water instantaneous water heater designed according to the invention emerge from the subclaims. In the following description of a preferred embodiment shown in FIGS . 1 to 3 of the drawing, the invention is explained in more detail. It shows

Figure 1 is a schematic representation of the hot water instantaneous heater.

Fig. 2 is a block diagram of the electrical control circuit of the water shortage protection device, and

Fig. 3 shows a section through a section of the housing in the area where the electrodes of the sensor of the lack of water protection device are located.

The instantaneous hot water heater has a housing 11 in a manner known per se, in which a channel 12 through which water flows is arranged. In part 13 of this channel 12 there is an insulating tube 14 , in which a heating coil 15 is arranged. When flowing through the insulating tube 14 , the water is immediately heated or heated by the heating coil 15 through which current flows.

At the outlet end of the insulating tube 14 is in the vicinity of the heating coil 15, one electrode 16 of the sensor 17 of the lack of water protection device 18 ( FIG. 2), with which the conductivity of the second electrode formed between the electrode 16 and the heating coil 15 Sensor 17 located medium can be determined. Due to the fact that the tap water has a certain conductivity and the conductivity of gas or air is practically zero, the conductivity of the media between the electrodes 15 and 16 can be used in a very simple manner as a criterion for switching the heating current on and off the heating coil 15 can be used.

This is done with the aid of the circuitry shown schematically in FIG. 2 of the control circuit of the water shortage safety device 18 . The individual elements of this control circuit are attached to a circuit board provided with predetermined conductor tracks.

As is apparent from Fig. 2, the control circuit of the water shortage safety device 18 has four contacts 21, 22, 23 and 24 . The connection contacts 21 and 22 are connected directly to the two network terminals 25 and 26 . The power terminal 25 is preferably connected to the live conductor and the power terminal 26 to the non-live conductor. The contact 23 of the control circuit is connected to one end of the heating coil 15 , the other end of which is led to the non-live power terminal 26 . The terminal contact 24 is finally connected via a conductor 27 to the elec trode 16 of the sensor 17 .

The DC operating voltage required for operation is supplied by a power supply part 28 which has a transformer T 1 which is connected on the input side to the connecting contacts 21 and 22 . On the output side, this transformer T 1 is connected to a four-way rectifier G 1 , the direct voltage of which is supplied to a charging capacitor C 1 via a diode D 1 . With a view to stabilization against mains voltage fluctuations, the voltage lying on the charging capacitor C 1 is fed via a voltage regulator U 1 to a further charging capacitor C 2 , from which a stabilized operating voltage of 12 volts can be removed.

The electrode 16 of the sensor 17 is connected via the connection contact 24 to the central connection point of an existing from the resistors R 1 and R 3 existing voltage divider, which is applied via the connection contacts 21 and 22 to the mains voltage applied to the terminals 25 and 26 . In parallel with the resistor R 3 there is another resistor which is formed by the conductivity of the medium between the electrode 16 and the heating coil 15 . The AC voltage present at the connection point between the two resistors R 1 and R 3 is fed via a resistor R 4 to a first voltage comparator U 2 , which is fed with the voltage present at the charging capacitor C 2 . This first voltage comparator U 2 is connected on the output side via a resistor R 5 to the central connection point of an RC element consisting of a resistor R 6 and a capacitor C 3 , which receives the operating voltage applied to the charging capacitor C 2 with its external contacts. The switching elements R 5 , R 6 and C 3 are dimensioned such that, following the response of the first voltage comparator U 2, a switch-on delay of a certain duration, for example about 0.5 sec, comes about. The voltage present at the center connecting point of the RC element R 6 , C 3 is fed to a second voltage comparator U 3 , to which the operating voltage applied to the feed capacitor C 2 is fed.

The four-way rectifier G 1 of the power supply part 28 is additionally connected on the output side via a resistor R 2 and a light-emitting diode D 2 connected in parallel to the windings of the two relays K 1 and K 2 , which have their second connection contacts via a conductor 29 to the second voltage comparator U 3 are connected. The voltage comparator U 3 is constructed in such a way that when it responds, a low-resistance connection of the conductor 29 leading to the windings of the relays K 1 , K 2 with the conductor connected to the connection contact 22 and having an essentially earth potential is brought about, so that the latter Way the two relays K 1 and K 2 are made to respond.

Parallel to the windings of the two relays K 1 and K 2 , a free-wheeling diode D 3 is additionally provided, with which the voltage peaks resulting when the relay windings are switched off are suppressed. The two relays K 1 and K 2 are provided with two mutually parallel working contacts k 1 and k 2 , by means of which the heating coil 15 is applied to the power terminals 25 and 26 , so that the heating coil 15 is then flowed through by a heating current.

The functioning of the circuit arrangement described is as follows: When the hot water instantaneous water heater is put into operation, which happens, for example, by opening a shut-off element, water flows through the channel 12 in the instantaneous water heater. With the help of a pressure switch, not shown, two contacts are closed, whereby the mains voltage is applied to the terminals 25 and 26 . This network is voltage then reacted with the help of the group consisting of the elements T 1, G 1, D 1, C 1, D 1 and C 2 power supply 28 into an AC stabilized ized DC voltage of about 12 volts, which in the charging capacitor C 2 for feeding of the two voltage comparators U 2 and U 3 and the RC element R 6 , C 3 is available. In addition, the DC voltage occurring at the output of the four-way rectifier G 1 is available for feeding the windings of the two relays K 1 and K 2 .

The mains voltage applied to the mains terminals 25 and 26 is likewise supplied via the connection contacts 21 and 22 to the voltage divider consisting of the two resistors R 1 and R 3 . The values of the resistors R 1 and R 3 of this voltage divider are chosen such that in the presence of a gas or air bubble in the area between the electrode 16 and the heating coil 15 of the sensor 17 , ie in the presence of an essentially infinite resistance between the two electrodes 15 and 16 the resulting at the common connec tion point of the two resistors R 1 , R 3 AC voltage is so high that activation of the first voltage comparator U 2 does not come about via the resistor R 4 . However, if there is no air bubble between the electrode 16 and the heating coil 15 , ie the space between them is filled with water, it gives a certain ter, relatively low resistance value due to the conductivity of the water, which means that at the connection point between the two Resistors R 1 and R 3 applied AC voltage drops and the resistor R 4 activates the first voltage comparator U 2, it follows.

The control voltage supplied to the second comparator U 3 is determined by the values of the resistor R 6 and the capacitor C 3 of the RC element R 6 , C 3 and thus has a high voltage value after switching on. After the response of the first voltage comparator U 2 , however, there is a low-impedance connection between its output and the line connected to the connection contact 22 , which is at ground potential, so that the capacitor C 3 is discharged via the resistor R 5 is coming. This in turn leads to the fact that the voltage applied at the connection point between the two resistors R 5 and R 6 drops with a time delay determined by the capacitance of the capacitor C 3 such that the second voltage capacitor U 3 with a time delay of approximately 0 , 5 sec after the first comparator U 2 has also responded. Because of this time delay, it can be ensured that the flow conditions within the insulating tube 14 following the elimination of any gas or air bubbles present could stabilize to such an extent that the occurrence of further gas or air bubbles cannot be expected.

By responding to the second voltage comparator U 3 , a low-resistance connection is established between its output and the line 22 connected to the connection contact, which is essentially at ground potential, so that the four-way rectifier G 1 via the resistor R 2 and the parallel connected light-emitting diode D 2 and the parallel windings of the two relays K 1 and K 2, a current flow in Rich direction of the grounded line connected to the terminal contact 22 comes about. The two relays K 1 and K 2 thus respond, whereby the normally open contacts k 1 and k 2 are closed. In this way, the circuit formed by the network terminal 25 , the connection contact 21 , the two working contacts k 1 and k 2 , the connection contact 23 , the heating coil 15 and the network terminal 26 , so that the heating coil 15 the water flowing through the insulating tube 14 heated. The simultaneous lighting of the LED D 2 indicates the activation of the two relays K 1 and K 2 and thus the operation of the instantaneous water heater.

Are gas or air bubbles during operation of the device in the insulating tube 14 , so with the help of the sensor electrode 16 and the control circuit of the lack of water hedging device 18 of the heating coil 15 supplied heating current is interrupted immediately because the resistance value of the Medium between the sensor electrode 16 and the heating coil 15 changes. The increase in the voltage at the connection point between the two resistors R 1 and R 3 causes a deactivation of the voltage comparator U 2 via the resistor R 4 , which results in a corresponding deactivation of the second voltage comparator due to a rise in voltage at the connection point of the elements R 6 and C 3 U 3 causes. Due to the resulting high-impedance connection in relation to the grounded line connected to the connection contact 22 , the two relays K 1 and K 2 are deactivated, which means that the corresponding work contacts k 1 and k 2 open and thus an interruption in the circuit of the heating coil 15 has the consequence. A renewed switching on of the heating coil 15 can then only take place when stable flow conditions prevail again in the insulating tube 14 .

As can be seen from Fig. 3, the electrode 16 is arranged in the immediate vicinity of the heating coil 15 or its connecting wires, and so far from it that contact is impossible; on the other hand, however, so close that between the projecting into the flow channel 12 , at the end of which the contact screw 31 is located electrodes 32 and the heating coil 15, an electrical resistance of the desired size is present.

If it is proposed to provide two relays K 1 and K 2 connected in parallel, this is done for reasons of greater security. Of course, the arrangement of even a single relay is sufficient to achieve the desired goal.

In summary, it follows that with the help of the provided lack of water safety device a very effective protection against destruction of the heating coil of the hot water instantaneous water heater can be achieved, because whenever gas or air bubbles occur in the area of the heating coil 15 , an immediate one The power supply to the heating coil 15 is interrupted.

Claims (8)

1. Hot water instantaneous water heater with a housing having a water-flowing channel, in which the wall of the channel consists of a material that does not conduct electricity and in a section of this channel a heating coil through which electric current flows is arranged, and with a lack of water safety device which controls the heating current of the heating coil as a function of the electrical conductivity of the water contained in the flow channel, a sensor being provided for detecting the electrical conductivity, which comprises two electrodes lying in the water flow, one of the two electrodes being the heating coil, characterized in that the second electrode ( 32 ) is arranged in the flow channel ( 12 ) at a distance from the heating coil ( 15 ). 2. Continuous-flow heater according to claim 1, characterized in that the electrode ( 16 ) consists of a in the wall of the flow channel ( 12 ) screwed contact screw ( 31 ), the electrode pin ( 32 ) near the heating coil ( 15 ) in the flow channel ( 12 ) protrudes. 3. instantaneous water heater according to claim 1 or 2, characterized in that the second sensor electrode ( 16 ) is part of a line voltage-fed voltage divider (R 1 , R 3 ) which is connected to a voltage comparator (U 2 ). 4. instantaneous water heater according to claim 3, characterized in that the voltage comparator (U 2) on the output side via an RC element (R 6 , C 3 ) is connected to a second voltage comparator (U 3 ) with which the control of a switching relay (K 1 ) takes place, the normally open contact (k 1 ) is arranged in the feed circuit of the heating coil ( 15 ). 5. instantaneous water heater according to claim 3 or 4, characterized in that the supply of the voltage comparator (U 2 ) or the voltage comparators (U 2 , U 3 ) and the RC element (R 6 , C 3 ) with the help of a Transformer (T 1 ), a four-way rectifier (G 1 ), a smoothing diode (D 1 ), a first charging capacitor (C 1 ), a voltage regulator (U 1 ) and a second charging capacitor (C 2 ) existing power supply, and that The switching relays (K 1 , K 2 ) are supplied directly from the four-way rectifier (G 1 ). 6. instantaneous water heater according to claim 4 or 5, characterized in that in parallel with the switching relay (K 2 ) one of the voltage peaks occurring during the shutdown process is provided under pressing free-wheeling diode (D 3 ). 7. instantaneous water heater according to one of claims 4 to 6, characterized in that in parallel to the switching relay (K 1 ) a further relay (K 2 ) is provided, the normally open contacts (k 1 , k 2 ) parallel to each other in the circuit of the heating coil ( 15 ) are arranged. 8. instantaneous water heater according to one of claims 4 to 7, characterized in that in series with the winding of the relay (K 1 ) or the relay (K 1 , K 2 ) a switching state indicating the light emitting diode (D 2 ) is arranged .