WO2019162243A1

WO2019162243A1 - Actuating value reduction in accordance with the desired value

Info

Publication number: WO2019162243A1
Application number: PCT/EP2019/054022
Authority: WO
Inventors: Michael Grobe
Original assignee: Stiebel Eltron Gmbh & Co.Kg
Priority date: 2018-02-20
Filing date: 2019-02-19
Publication date: 2019-08-29
Also published as: DE102018001315B4; DE102018001315A1

Abstract

The present invention relates to a method for operating a continuous flow heater, comprising a control of an actuating threshold value for a volume flow through the continuous flow heater based on a target value temperature.

Description

Switch-on value reduction depending on the setpoint

The present invention relates to a method for operating a water heater and a water heater.

A water heater is used for heating water, which feeds a tapping point with warm water. In larger facilities, such as an airport, often several consumers respectively taps are arranged side by side, each of which is powered by its own water heater.

The supply of water is carried out by means of a common supply line from which is branched off to the water heater. The instantaneous water heater is controlled as a function of a predetermined switch-on threshold, which corresponds to a minimum volume flow. Only when a minimum volume flow is detected, the water is heated by means of a heating section of the water heater. This serves to avoid damage to the heating section, if it can come to an evaporation of a heating element of the heating due to the low flow rate. Too low a volumetric flow occurs, for example, when a plurality of consumers, which depend on a common supply line, are open at the same time, so that the respective instantaneous water heater is supplied with a volumetric flow lying below the switch-on threshold value. This circumstance is countered by manually lowering the switch-on threshold. However, this involves the risk that the switch-on threshold causes a control of the water heater, although the volume flow is not sufficiently large to avoid gas bubble formation in the heating section.

The present invention is therefore based on the object to provide a method for operating a water heater and a water heater, whereby a safe operation of the water heater is ensured even at low flow rates.

This object is achieved by a method for operating a water heater and a water heater.

According to claim 1, a method for operating a water heater is proposed, comprising controlling a Einschaltschwellwertes for a flow rate through the water heater based on a setpoint temperature. By controlling the switch-on threshold value as a function of the setpoint temperature, it is possible to prevent a flow rate which is too low for a preset setpoint temperature, at which the flow heater nevertheless starts to heat, from damaging the flow heater by, for example, gas bubble formation in the heating section. A change in the setpoint temperature is accompanied by a change in the switch-on threshold due to the proposed control. Thus, when the setpoint temperature is reduced, the switch-on threshold value is lowered at the same time. As a result, an operation can be realized even with only low volume flows without the risk of gas bubble formation.

According to a development, a power stage for operating a heating section of the water heater can be selected based on the setpoint temperature. With the adaptation of the switch-on threshold to lower volume flows may be accompanied by an adjustment of the power control, whereby the heating section is exposed to a lower load and power consumption when heating the water.

Furthermore, based on the switch-on threshold value, a triggering of at least one heating element of a heating section having a plurality of heating elements can be carried out. The heating section of the water heater may comprise at least two, preferably four heating elements, which are individually or in pairs controllable. Thus, in a heating section with four heating elements, two heating elements of the total volume flow can be supplied, while the other two heating elements only a proportionate volume flow is supplied in each case. Accordingly, the control of the heating elements can be selected so that first the heating elements are controlled, where the total volume flow is supplied, while the other two heating elements are driven at a later time. This can be the case, for example, with an increase in the volume flow and / or a higher setpoint temperature.

In particular, the setpoint temperature can be set variably by means of a setting device. This allows a user to specify a setpoint temperature that will initially govern the operation of the water heater.

According to one embodiment of the invention, a request for adjusting the setpoint temperature can be signaled when falling below the Einschaltschwellwertes. This allows the user to adapt the switch-on threshold to prevailing operating conditions if, for example due to frequent parallel control of several consumers, a connection of a water heater is regularly supplied with a volume flow which is below the switch-on threshold.

According to a further embodiment, at least one characteristic curve for the switch-on threshold value can be stored in a control device for operating the instantaneous water heater. The storage of at least one characteristic in the control device allows adaptation to different operating situations. Preferably, several characteristic curves are stored, so that a selection is made possible.

The invention relates in a further aspect to a water heater.

To achieve the object set out above, a continuous flow heater is proposed having at least one heating section, a control device, a flow sensor and a temperature sensor, characterized in that the control device is set up to control a switch-on threshold value for a volume flow through the instantaneous water heater based on a setpoint temperature. If the detected volume flow is below the switch-on threshold, activation of the flow heater is prevented. By changing the setpoint temperature, the switch-on threshold is controlled in such a way that damage to the flow heater, in particular the heating section by gas bubble formation, is avoided.

For this purpose, at least one characteristic curve for the switch-on threshold value can be stored in the control device. To respond to different operating situations to be able to store several characteristic curves, which in addition to a linear course of the characteristic also have exponential and / or logarithmic progressions.

According to a further embodiment, the heating section can have at least two heating elements which can be activated by the control device. In this case, an individual control of the at least two heating elements is conceivable.

In particular, an adjustment device can be provided for setting and changing the setpoint temperature. The adjustment device allows the user to adjust the setpoint temperature in order to effect a control of the heating path, even at low flow rates, to heat the water. For this purpose, the adjusting device can be designed as an input device such as buttons or a control panel on the water heater, which is connected by signal technology with the control device.

Furthermore, a temperature upper limit can be specified. The default can be performed by means of the adjustment, which is associated with the water heater. Alternatively, a mechanical adjustment may be provided to the water heater to specify the upper temperature limit can. This may be, for example, one or more jumpers or DIP switches, which are preferably arranged on a circuit board of the control device. By setting the upper temperature limit, scalding free operation can be ensured. Starting from this upper temperature limit, a reduction of the switch-on threshold can be carried out in accordance with regulated.

According to a further embodiment, a plurality of power stages can be stored in the control device, which can be selected as a function of the setpoint temperature for controlling the heating section. The operation of the instantaneous water heater can be based on the switch-on threshold, so that a lower power level can be selected for lower volume flows than for larger volume flows. Based on the selected power level, the heating section is controlled.

Furthermore, the control device may be connected to a display device. By means of the display device, the current setpoint temperature can be displayed to a user. Furthermore, the user can be informed by the display device that in the case of too low a volume flow adjustment of the setpoint temperature is necessary in order to adapt the switch-on threshold to the situation. For this purpose, a corresponding input can be carried out by means of the input device. According to a further embodiment, the control device may comprise a communication interface. By means of the communication interface can be entered through a communication infrastructure, such as a local network or the Internet, with the control device of the water heater in communication, for example, to change settings remotely or to transfer characteristics to the control device. Likewise, the provision of the communication interface allows a data exchange of several, in particular in close proximity to each other, water heaters among themselves, which are operated under comparable operating conditions.

Furthermore, the control device can be set up for a specification of a maximum temperature in an emergency operation. If, for example, the failure of the temperature sensor causes that the setpoint temperature can not be reached, the control device activates the heating path in accordance with a switch-on threshold value which is set as a function of the predetermined maximum temperature.

In the following, further advantages and preferred embodiments of the invention will be described with reference to the attached figures. Show it:

Fig. 1 is a schematic representation of a water heater;

Fig. 2 is a schematic representation of the structure of a heating section of a

flow heater;

FIG. 3 shows characteristic curves of a switch-on threshold value of a water heater in dependence on a setpoint temperature; FIG.

Fig. 4 is a diagram of a control of a water heater according to the invention;

Fig. 5 shows a relationship between an adjustment of a power control of a water heater due to the change of the Einschaltschwellwertes.

1 shows a schematic representation of a continuous flow heater 1 comprising a heating section 2, at least one fluid flow sensor 3, at least one temperature sensor 4, a control device 5, an adjusting device 6 and a display device 7. The inlets and outlets are not shown in the schematic view of water and the fluid line through the flow heater. 1

The control device 5 is signal-connected to the at least one fluid flow sensor 3 and the at least one temperature sensor 4. At least a measured values are provided to the control device 5 for evaluation, a fluid flow sensor 3 and the at least one temperature sensor 4. The control device 5 controls the heating section 2 based on these measured values. The adjusting device 6 makes it possible to change operating parameters of the water heater 1. Thus, by the adjusting device 6, a setpoint temperature, ie a desired outlet temperature of the heated water, adjustable or changeable.

The illustration of FIG. 2 shows a schematic representation of the structure of a heating section 2 of a water heater 1. Through an inlet 8, water, for example, a line connection, enters the heating section 2. Through an outlet 9, the heated water exits for use. After the inlet 8, the water passes through the fluid flow sensor 3, which detects the entering volume flow. The fluid flow sensor 3 can be designed as a combined temperature and volume flow sensor, which at the same time detects the water temperature in the inlet 8 of the heating section 2. The water is passed through the heating section 2 along a flow path 10. The flow path 10 comprises a plurality of flow channel sections 1 1, 12, 13, in which heating elements 14, 15, 16 are arranged.

In the illustrated embodiment, a first flow channel section 1 1 is provided, in which a first heating element 14 is located. This is followed by a second flow channel section 12 connects. The second flow channel section 12 has two parallel strands 12a, 12b, which divide the volume flow into two partial volume flows. In each of the strands 12a, 12b, a second heating element 15 is arranged in each case. The second flow channel section 12 is adjoined by a third flow channel section 14, in which the two partial volume flows are brought together again. In the third flow channel section 14, a third heating element 16 is arranged. The third heating element 16 is followed by the temperature sensor 4, which detects the temperature of the liquid flowing at this point.

The heating elements 14, 15, 16 of the heating section 2 are designed as heating resistors and are each driven by a power electronic switching element 17. The power electronic switching elements 17 may be formed, for example, as triacs or thyristors. The power electronic switching elements 17 are cooled, for example, by the water before passing through the heating section 2.

The control of the heating section 2 is based on the volume flow supplied to it, which must pass a switch-on threshold, ie a minimum volume flow. Setting the switch-on threshold prevents the water from reaching the Heating elements 14, 15, 16 is heated so that it starts to boil, causing blistering. The occurrence of bubbles in the water within the heating section 2 can lead to overheating of the heating elements 14, 15, 16 until their destruction.

By passing the switch-on threshold value, first of all the activation of the first and third heating elements 14, 16 in the first and third flow channel sections 11, 13 can take place, through which the total volume flow flows. The activation of the second heating elements 15 in the strands 12a, 12b of the second flow channel section 12 can take place at a later time depending on the detected volume flow or a set higher setpoint temperature.

In order to be able to heat the water nevertheless in situations in which the flow heater 1 supplied volume flow does not pass the Einschaltschwellwert, the regulation of Einschaltschwellwertes for a flow rate through the water heater 1 is provided based on the setpoint temperature. By controlling the switch-on threshold value as a function of the setpoint temperature, it is avoided that a flow rate that is too low for a specific setpoint temperature leads to damage to the flow heater 1 due to the formation of bubbles. For this purpose, various courses of the switch-on threshold value are stored in the control device 5.

FIG. 3 shows various exemplary characteristic curves 18, 19, 20 of FIG

Switch-on threshold value of the instantaneous water heater 1 as a function of the setpoint temperature. In addition to a linear curve 18, an exponential and a logarithmic curve 19, 20 are shown. The selection of a specific characteristic can be done depending on the operating situation.

The illustration in Fig. 4 illustrates the control according to the invention. 4 shows a curve 21 of the switch-on threshold value as a function of the setpoint temperature. As the setpoint temperature increases, the switch-on threshold for the required volume flow increases.

In Fig. 5, the relationship between an adjustment of a power control due to the change of the Einschaltschwellwertes is shown. The lowering of a first switch-on threshold value 23A, for which a first volume flow 22A is required, to a lower second switch-on threshold value 23B results in a lower second volume flow 22B being required for controlling the instantaneous heater 1. At the same time is the lowering of the Einschaltschwellwertes the Power control is adjusted by lowering from a higher first power level 24A to a lower second power level 24B.

FIG. 6 shows by way of example a power adaptation in the given volume flow 22A by a change of the switch-on threshold value 23A on the basis of a curve 25 of the power received by the heating section 2. The volume flow 22A is below the first switch-on threshold value 23A, so that the heating section 2 of the instantaneous water heater 1 is not activated, so that no power is absorbed by the heating section 2. The lowering to the lower second switch-on threshold value 23B results in that the heating zone 2 is activated in order to operate the heating elements 14, 15, and / or 16 in accordance with a power stage 24B adapted to the second switch-on threshold value 23B. For this purpose, the setpoint temperature is reduced by means of the adjusting device 6, which is accompanied by a reduction of the switch-on threshold value. This thus allows the control of the water heater 1 even at low flow rates, without causing damage to the heating section 2. The operation of the water heater 1 in different power levels 24A, 24B in dependence on the respective switch-on threshold value 23A, 23B also contributes to a reduction of the stress on the heating section 2 or the heating elements 14, 15, 16.

If, as shown by way of example in FIG. 6, a volumetric flow 22A is detected by the fluid flow sensor 3 which lies below the switch-on threshold value 23A set for the predefined setpoint temperature, an indication to a user is output by means of the display device 7 to carry out a manual adjustment of the setpoint temperature , This is done by means of the input device 7.

The control device 5 can be equipped with a communication interface which makes it possible to communicate with other instantaneous water heaters by means of a communication infrastructure, for example WiFi or Internet. This is particularly conceivable for spatially adjacent Durchlauferhitzter operated under similar conditions. In this way, a setting of the setpoint temperature made on a water heater could be transferred to other instantaneous water heaters. The same applies when progressions for switch-on threshold values are transmitted to the control device 5 of the instantaneous water heater 1.

Claims

claims

A method of operating a water heater (1) comprising controlling a turn-on threshold (23A, 23B) for a volume flow (22A, 22B) through the flow heater (1) based on a set point temperature.

2. The method according to claim 1, characterized in that based on the setpoint temperature, a power stage (24A, 24B) for operating a heating section (2) of the flow heater (1) is selected.

3. The method according to claim 2, characterized in that based on the

Einschaltschwellwert (23A, 23B) a control of at least one

Heating element (14, 15, 16) of the heating section (2) is performed.

4. The method according to any one of claims 1 to 3, characterized in that the setpoint temperature is adjusted by means of an adjustment device (7) variable.

5. The method according to any one of claims 1 to 4, characterized in that falls below the Einschaltschwellwertes (23A, 23B), a request for adjusting the setpoint temperature is signaled.

6. The method according to any one of claims 1 to 5, characterized in that for operating at least one characteristic (18, 19, 20) for the Einschaltschwellwert (23A, 23B) in a control device (5) is deposited.

7. instantaneous water heater (1), with a heating section (2), a control device (5), a flow sensor (3) and a temperature sensor (4), characterized in that the control device (5) for controlling at least one Einschaltschwellwertes (23A, 23B ) is arranged for a volume flow (22A, 22B) through the flow heater (1) based on a set point temperature.

8. instantaneous water heater (1) according to claim 7, characterized in that in the control device (5) at least one characteristic (18, 19, 20) for the at least one switch-on threshold (23A, 23B) is deposited.

9. instantaneous water heater (1) according to one of claims 7 or 8, characterized in that the heating section (2) has at least two heating elements (14, 15, 16) which are controllable by the control device (5).

10. instantaneous water heater (1) according to one of claims 7 to 9, characterized in that for setting and changing the setpoint temperature, an adjusting device (7) is provided.

1 1. Water heater (1) according to one of claims 7 to 10, characterized in that a temperature upper limit can be predetermined.

12. instantaneous water heater (1) according to one of claims 7 to 1 1, characterized in that in the control device (5) a plurality of power levels (24A, 24B) are deposited, which can be selected depending on the setpoint temperature for driving the heating section (2) ,

13. flow heater (1) according to one of claims 7 to 12, characterized in that the control device (5) with a display device (6) and an input device (7) is connected.

14. instantaneous water heater (1) according to one of claims 7 to 13, characterized in that the control device (5) comprises a communication interface.

15. instantaneous water heater (1) according to one of claims 7 to 14, characterized in that the control device (5) is set for a specification of a maximum temperature in an emergency operation.