DE4034635C1 - Operating electric throughflow heater - setting desired temp. by thermostatic valve in by=pass of heating block contg. elements switchable in power stages by control - Google Patents

Abstract

A throughflow electric water heater has a number of heating elements (2-6) in a block controlled by a regulating circuit to match the heating to the requirements as set by the control tap (25). A by-pass (22) feeds cold water to the mixer tap and has a flow sensor (29). If cold water is added to the mixer tap the regulating circuit reduces the heating by one step. The heating is in discrete steps, starting with a low setting. A differential pressure switch (10) monitors the flow and controls the regulating circuit. ADVANTAGE - Optimised heating effect by simple control.

Description

The invention relates to a method for operating a electric instantaneous water heater with several radiators in a heating block by means of a control device can be switched in several heat output levels, with one Differential pressure switch for switching on a first one Heating power level, as well as with a bypass to the heating block, where a thermostatic valve the flow of the bypass to Reaching a set temperature, and with a throttle lying in line in the waterway to the heating block.

Such a water heater is in DE 23 55 988 C2 described. The heat output levels are there in Dependence on that at the differential pressure switch in each case falling pressure over several switch positions switched. The adjustment of the switch positions is complex.

The object of the invention is in a water heater the power switched on the water flow easy way to customize.

According to the invention, the above task is for one Water heater of the type mentioned in the introduction solved that at the start of a tap the throttle bridging switching valve is closed, and by the Choke the flow pressure loss in the water path of the heating block is increased and a first by the differential pressure switch Heating power level is switched on after a certain time after the start of the dispensing process Switching valve from the electronic control device is opened that as long as no sensor Cold water flow through the bypass is detected  electronic control device one after another Heating power levels turns on, and that at one of Sensor detected cold water flow through the bypass electronic control device no further Switches on the heating output levels.

The differential pressure switch is designed so that it responds even when a minimum flow rate increases Start of a tap process flows over the throttle. By the opening of the switching valve then increases Flow rate so that the differential pressure switch remains switched on, even if bypassed Water flow takes place, the water flow over the Differential pressure switch or the heating block reduced. The Differential pressure switch only switches off when the Water flow falls below the minimum flow rate.

The water flow through the bypass is controlled by the thermostatic valve controlled so that to reach a set Set temperature that exits from the heating block Hot water is mixed in according to cold water. The The sensor in the bypass only detects whether there is cold water through the bypass or no cold water flows. No flow through the bypass Cold water, then this is a sign that the Setpoint temperature with the set heating output has not been reached. Accordingly, in switching on at certain intervals in succession further heat output levels. As soon as cold water flowing through the bypass is a sign that the target temperature has been reached. Further Heating output levels are then no longer activated.

The heating power switched on depends on the respective target temperature in a simple manner adjusted each water flow. This will make the The temperature of the water in the heating block is not unnecessarily high. This reduces and increases the calcification in the heating block  the lifespan of the radiators. The structure of the Instantaneous water heater is comparatively simple because tried and tested components and a comparatively simple one electronic control device are sufficient.

The one that flows through the instantaneous water heater during operation Water quantity is essentially just from the setting of the nozzle connected to the instantaneous water heater dependent. The instantaneous water heater itself does not lead to considerable fluctuations in the water flow rate because then when the switching valve is open, an increase in Flow rate through the bypass to lower the Flow through the heating block.

In an embodiment of the invention, the Control device after a certain period of time one additional heat output level each, as long as none Cold water flows through the bypass. For example each after a period of 1 s to 2 s next higher heat output level switched on when the previous heat output level did not result in via the thermostatic valve or the bypass cold water is added to reach the target temperature.

In a further development of the invention, the control device the other heat output levels depending on from the flow rate flowing through the heating block turn on.

In an embodiment of the invention, the Control device with decreasing flow rate through the Heating block the heat output levels one after the other. This ensures that when the bypass flowing through flow is not sufficient that Hot water from the heating block to the set temperature  bring, the heating power is reduced. This can be measured by a flow meter at the heating block, since the flow rate at the heating block decreases when the Flow through the bypass increased.

In a further development of the invention, the switching valve closes then when even at the highest, turned on Heat output level no cold water through the bypass flows, causing the throttle to take effect again. Thereby is achieved that, even if at the highest, activated heating power level the target temperature remains below that which flows through the heating block The amount of water is reduced so that afterwards - albeit with reduced flow rate - the desired Target temperature is reached.

Further advantageous embodiments of the invention result from the other subclaims. An embodiment of the invention is shown below explained in more detail with reference to the drawing. The figure shows a block diagram of an electrical Instantaneous water heater.

A water heater has a heating block ( 1 ) in which five radiators ( 2 to 6 ) are arranged. The radiators ( 2 to 6 ) can be connected to the three phases (L 1 , L 2 , L 3 ) of the three-phase network. The radiators ( 2, 3, 6 ) are star connected at the star point (Y). Switching contacts ( 7, 8, 9 ) are located between the phases (L 1 , L 2 , L 3 ) and the radiators ( 2, 3, 6 ) and can be actuated simultaneously by a differential pressure switch ( 10 ). A triac ( 11 ) is located between the switch contact ( 7 ) and the radiator ( 2 ). A triac ( 12 ) lies between the switch contact ( 8 ) and the heating element ( 3 ). In addition, a triac ( 14 ) is connected between the switch contact ( 8 ) and a connection point ( 13 ) of the radiators ( 4, 5 ). On the other hand, the connection point ( 13 ), the radiator ( 4 ) with the radiator ( 3 ) and the radiator ( 5 ) is connected to the switch contact ( 8 ).

The triacs ( 11 , 12 , 14 ) can be switched individually by an electronic control device ( 15 ).

A choke ( 17 ) is connected downstream of a cold water inlet ( 16 ). This is a switching valve ( 18 ) connected in parallel, which can be controlled by the control device ( 15 ) by means of a magnetic drive ( 19 ).

The throttle ( 17 ) is followed by a Venturi nozzle ( 20 ) in the water path, to which the differential pressure switch ( 10 ) is connected. A flow meter ( 21 ) is located in the water path between the Venturi nozzle ( 20 ) and the heating block ( 1 ).

A bypass ( 22 ) is also connected to the cold water inlet ( 16 ). In this a thermostatic valve ( 23 ) is arranged as a mixing valve, into which a hot water outlet ( 24 ) of the heating block ( 1 ) opens. The thermostatic valve ( 23 ) can be adjusted to a target temperature by means of an actuator ( 25 ).

A temperature sensor ( 26 ) of the thermostatic valve ( 23 ) detects the water temperature at the mixed water outlet ( 27 ). The thermostatic valve ( 23 ) adjusts itself as a function of the set target temperature and the temperature reached at the mixed water outlet ( 27 ) in such a way that a quantity of cold water is mixed into the hot water from the hot water outlet ( 24 ) via the bypass ( 22 ), with which the desired target temperature is reached becomes. The mixed water outlet ( 27 ) can be connected to a tap fitting ( 28 ). In the bypass (22), a sensor (29) is disposed, which detects whether the bypass is flowed through (22) of cold water. The sensor ( 29 ) is connected to the control device ( 15 ).

Overall, a circuit of six heating power levels is possible with the arrangement described. The control device ( 15 ) is designed in such a way that it switches via the triacs ( 11 , 12 , 14 ) approximately as follows:
7.3 kW at 5.9 l / min on, at 1.6 l / min off;
10.5 kW at 7.1 l / min on, at 2.4 l / min off;
13.5 kW at 7.9 l / min on, at 3.0 l / min off;
17.1 kW at 8.5 l / min on, at 3.8 l / min off;
21.3 kW at 9.0 l / min on, at 4.8 l / min off.

The indicated flow rates relate to the flow rates detected by the flow meter ( 21 ).

The mode of operation of the instantaneous water heater described is something like this:

If the tap fitting ( 28 ) is opened, the switching valve ( 18 ) is initially closed and the cold water flow to the heating block ( 1 ) only flows via the throttle ( 17 ), the flow pressure loss, ie flow resistance, of which is significantly greater than that of the switching valve ( 18 ) - in its open state -. At a minimum flow rate of about 3.4 l / min, the differential pressure switch ( 10 ) responds so that the three switch contacts ( 7 , 8 , 9 ) close. A first, lowest heat output level of, for example, 4.3 kW is now switched on. The triacs ( 11 , 12 , 14 ) are still locked. The thermostatic valve ( 23 ) is closed as long as the target temperature has not been reached. The control device ( 15 ) detects the start of the dispensing process via the flow meter ( 21 ). After a certain time it opens the switching valve ( 18 ), whereby the flow rate through the heating block ( 1 ) increases considerably, for example to 5 l / min.

The control device ( 15 ) then interrogates the sensor ( 29 ) at certain time intervals, for example every 1 to 2 s. As long as this does not report any cold water flow, the control device ( 15 ) gradually increases the heating output via the triacs ( 11 , 12 or 14 ).

When the thermostatic valve ( 23 ) opens, ie the target temperature is reached, the sensor ( 29 ) detects a flow of cold water. As a result, the control device ( 15 ) interrupts a further upshifting of the heating power levels.

If the target temperature is exceeded, the thermostatic valve ( 23 ) approaches its fully open state. This reduces the water flow through the heating block ( 1 ). This flow reduction is detected by the flow meter ( 21 ) and the control device ( 15 ) then switches the heating power back in accordance with the table given above.

If, despite switching on the highest heating output level (21.3 kW) with a very high flow rate, e.g. 9.0 l / min, the set target temperature is not reached, the thermostatic valve ( 23 ) remains closed, so that the sensor ( 29 ) does not determine any water flow . The control device ( 15 ) then closes the switching valve ( 18 ), as a result of which the water flow to the heating block ( 1 ) takes place via the throttle ( 17 ) and is thus reduced, so that the heating power switched on is sufficient to achieve the desired temperature.

If the flow rate of the tap fitting ( 28 ) when it is opened is greater than 3.4 l / min, for example 5.9 l / min, the instantaneous heater switches on with a correspondingly higher heating output level, for example 7.3 kW.

The described switching of the heating power levels takes place without any problems even if the tap fitting ( 28 ) is adjusted or the pressure of the water network fluctuates.

Claims (7)

1.Method for operating an electrical flow heater with several radiators in a heating block, which can be switched in several heating power levels by means of a control device, with a differential pressure switch for switching on a first heating power level and with a bypass to the heating block, a thermostatic valve controlling the flow of the bypass A set temperature is reached, and with a throttle lying in series in the water path to the heating block, characterized in that at the start of a tapping process, a throttle ( 17 ) bridging the switching valve ( 18 ) is closed and the throttle ( 17 ) reduces the flow pressure loss in Water path of the heating block ( 1 ) is increased and a first heating power level is switched on by the differential pressure switch ( 10 ), that after a certain time after the start of the tapping process, the switching valve ( 18 ) is opened by the electronic control device ( 15 ), as long as one Sensor ( 29 ) no Cold water flow through the bypass ( 22 ) is detected, the electronic control device ( 15 ) switches on further heating power levels in succession and that when the cold water flow through the bypass ( 22 ) is detected by the sensor, the electronic control device ( 15 ) switches on no further heating power levels. 2. The method according to claim 1, characterized in that as long as the sensor ( 29 ) detects no cold water flow through the bypass ( 22 ), the switching on of a further heating power level takes place after a certain period of time. 3. The method according to claim 1 or 2, characterized in that as long as the sensor ( 29 ) detects no flow of cold water through the bypass ( 22 ), the further heating power levels are each switched on depending on the flow rate flowing through the heating block ( 1 ) . 4. The method according to any one of the preceding claims, characterized in that the control device ( 15 ) switches off the heating power stages in succession when the flow through the heating block ( 1 ) decreases. 5. The method according to any one of the preceding claims, characterized in that when the sensor ( 29 ) does not detect the bypass ( 22 ) flowing cold water even at the highest heating power switched on, the switching valve ( 18 ) is closed. 6. The method according to any one of the preceding claims, characterized in that the throttle ( 17 ) before the differential pressure switch ( 10 ) is flowed through by cold water. 7. The method according to any one of the preceding claims, characterized in that the differential pressure switch ter ( 10 ) of the water heater via switching contacts ( 7 , 8 , 9 ) is switched on all poles to the three-phase network (L 1 , L 2 , L 3 ) and that means the control device ( 15 ) the Schaltkon contacts ( 7 , 8 ) downstream triacs ( 11 , 12 , 14 ) are switched through or blocked for switching the further heating power levels.