RU2628929C2 - Water heater - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: water heater with remote thermostat contains a heating element; an I/O unit for receiving a signal representing measured temperature; and a heating element control unit based on the desired temperature and the measured temperature. The control unit comprises a storage for storing the desired temperature of the space to be heated and includes an I/O unit. In this case, the remote thermostat contains: a housing; a temperature sensor that provides a signal representing the temperature; a control panel for entering a desired temperature that is transmitted to the control unit, wherein the control unit, to which the desired temperature is transmitted and which is configured to determine the control action for driving the heating element, is included in the body of the water heater.

EFFECT: ability to control the claimed system by a number of remote thermostats, simplified design of the thermostat.

15 cl, 10 dwg

Description

The present invention relates to a water heater.

Traditional building central heating (CH) systems contain a central boiler in which the burner burns gas. The heat released during combustion is transferred to the water through a heat exchanger. A pump in the boiler pumps hot water through a piping system in the building to the radiators, and these radiators transfer the heat of the water, mainly through radiation and convection, to the room in which the radiator is located. Through the return pipes, the chilled water again reaches the boiler, where the water is heated.

The boiler is controlled by a thermostat. The thermostat is located in one of the rooms, which must be heated. The thermostat contains a temperature sensor and an operating element to set the desired temperature. The thermostat initially consists of a bimetallic switch or a mercury switch that sends an on / off signal to the boiler. Temperature-dependent electronic components are used today as a temperature sensor. Modern thermostats no longer generate an on / off signal, but transmit a modulated signal to the boiler to provide an indication of variable heat consumption. Modern thermostats are often additionally equipped with a clock generator, so that the thermostat can also follow a time-dependent program. For historical reasons, these thermostats, however, are still connected to the boiler via a two-wire connection. Although this is not an insurmountable problem, it imposes a number of limitations. For compatibility reasons, the thermostat must have its own power source (usually a rechargeable battery) and transmit additional information, in addition to heat consumption, via a two-wire connection, which leads to unproductive costs and expenses.

US 2010 / 045470A1 describes a steam distribution system for heating a building with various living spaces. This system is based on remotely controlled steam valves on radiators in residential premises. The work is based on the temperatures measured in the living quarters and sets the temperatures that can optionally be entered through the thermostat in the living quarters. There is a central control system which, in addition to controlling the steam valves, also remotely controls the on and off of the steam boiler. This central control communicates wirelessly with the valves and the boiler through the local network. DE 10229222 A1 in very general terms describes a central control system that controls all the technical installations in a building based on sensor readings in order to minimize energy consumption. It is not formulated exactly how the water heater present in the system is controlled.

The central management of technical equipment in a living room or other building is also described in WO01 / 13577 A2. Management uses networks in the building. Several specific details are described regarding heating and hot water supply. There is, however, a central thermostat that communicates with the water heater through the network.

The present invention aims to take the next step in the development of heating boilers that provide a new range of functionality.

This goal is achieved by providing a water heater comprising: a heating element for heating water; a control unit for controlling the heating element, the control unit comprises a memory for storing the desired temperature of the space to be heated, and an input / output unit connected to the control unit; wherein the input / output unit is adapted to receive a signal representing the measured temperature; and the control unit controls the heating element based on the desired temperature and the measured temperature. The present invention is based on the understanding that the control unit, i.e., the controller from the point of view of control technology, is not located at the location of the temperature sensor, but at the location of the boiler. This, of course, developed historically in this way, since the temperature sensor and controller were a single physical component in traditional thermostats. The introduction of electronic temperature sensors, such as, for example, temperature-dependent resistors, led to thermostats with separate components, on the one hand to detect the temperature, and on the other to determine the control action. Due to the nature of the CH unit, that is, the central point of heat generation, and this heat is then distributed to various locations in the house where there is heat consumption, there is some advantage in having a heat consumption parameter defined in the boiler. Compared to a traditional CH installation, the controller, therefore, must be removed from the thermostat and placed in the CH boiler. In the first case, a traditional thermostat thus relates to a temperature sensor and an operating device. The thermostat determines the deviation based on the measured temperature and the set temperature and passes it to the boiler. In the boiler, the control unit determines the control action associated with the deviation in order to excite the heating element. (In most cases, the heating element is controlled by controlling the rotation speed of the fan, which draws in air through which gas is burned in the burner).

However, taking a step further than simply physically moving the controller (control unit), a larger range of options is created. This additional step is also the determination of deviations in the control unit (in the boiler). A traditional thermostat therefore only refers to a temperature sensor. The advantages of this are discussed with reference to embodiments below.

Although there is no strict need to integrate the control unit into the heater body, this is recommended.

The space to be heated is not necessarily limited to one room. Traditionally, for example, there is only one thermostat in residential premises, with which the temperature is measured in one room, and on which only one desired temperature can be set. In these cases, the CH unit, however, heats more than one room. Although the temperature of the room in which the thermostat is hung may be the temperature closest to the desired temperature most of the time, the same thermostat is used to “control” the temperature in other rooms. Similarly, the term “space” in the present invention should not be understood as being limited to one room. A space may contain one or more rooms. In some cases, the space may even contain only part of the room, for example, in the case of a long hall with a large loss of heat, while the two ends of the hall are heated by their own radiators with their own control loop. The measured temperature does not have to be the temperature in the room. The so-called weather-dependent temperature controls use an external thermometer and a direct-link controller. The direct communication controller determines the control action based on the outdoor temperature, the (known) known result of the disturbing effect (external temperature) and the (expected) known control result (operation of the heating element).

In a further embodiment, a water heater is provided in which the input / output unit is adapted to receive operating instructions from at least one operating device connected to the input / output unit, and the control unit is adapted to control the heating element based on the received operating instructions. The operating instructions on the basis of which the device is controlled by the user can thus be formed remotely from the water heater.

In a further embodiment of the water heater according to the invention, the control unit may be adapted to store received operating instructions in memory. The program of temperatures desired for a certain period can, for example, be thus saved.

In order to prevent the heater from shutting down in the unlikely event that the connection between the I / O unit and the operating unit is interrupted, it is recommended that a predetermined desired temperature or a predefined program for the desired temperature be stored in memory and that the control unit be adapted to control the heating element based on, respectively, a predetermined temperature or a predetermined program, when the operating instructions are Twenty, not accepted or not saved. The control unit thus has a configurable control algorithm, whereby the water heater can operate independently based on the stored standard settings (default), although the control configuration can be modified through an operating device that communicates with the input / output unit.

In a specific embodiment, the input / output unit comprises a two-pin input / output for two-way communication with an operating device with an integrated temperature sensor. The input / output unit is adapted to send and receive messages via two-pin input / output according to a protocol suitable for two-way communication over a two-wire connection and for multiplexing messages from an operating device and a temperature sensor. In an alternative embodiment, the input / output unit is adapted such that two physically separate one-way connections are used. In another alternative embodiment, the input / output unit is adapted such that two physically separate connections are used for the temperature sensor and the operating device. In another alternative embodiment, the input / output unit is adapted such that three physically separate one-way connections are used: one for inputting messages from the temperature sensor, one for inputting messages from the operating device, and one for outputting messages from the operating device.

In a further embodiment, a water heater is provided in which the input / output unit further comprises a network communication unit for exchanging data over the network. By combining the network communication unit into an input / output unit, it is possible to connect components, such as, for example, a temperature sensor or an operating device, to the control unit via a network connection, for example, a pre-existing home LAN or office LAN. Such a LAN is preferably based on TCP, UDP, and IP over Ethernet.

In a further embodiment, the present invention provides a water heater further comprising a web server to make the user interface accessible through a network communication unit for controlling the water heater. In yet another embodiment, the invention provides a water heating device in which a user interface made available through a web server is accessible via a network communication unit. In yet another embodiment, the invention provides a water heater in which a user interface is adapted to enable a user to perform at least one of the following actions: enter a desired temperature; enter a program for the desired temperature; view the measured temperature; view status information related to the water heater; View maintenance information View error messages View operational data and regulate the water heater. Using the integrated web server, it is possible to navigate to the web server of the water heater using, for example, a smartphone browser. The user is then shown the user interface with which the user can control or program the water heater or view information. Thus, it is possible, for example, to view the temperature measured by the connected temperature sensors, enter or change the desired temperature for the space, enter or change the program to change the temperature during the day or week, set or activate the weekend program, read the status information or information about maintenance.

An obvious way to enable network operation from a prior art installation would be to provide a traditional thermostat (with integrated temperature sensor, operating tool and controller) with a network interface and an integrated web server.

An additional embodiment according to the invention provides a water heater in which the input / output unit comprises a wireless communication device. In a specific example, the communication device uses one of the WiFi protocols. The communication device can serve as a WiFi access point. Alternatively, the communication device is, however, a WiFi client that connects to an existing WiFi access point. In this configuration, the water heater forms part of the LAN with which the WiFi access point is associated, and temperature sensors and operating devices can be connected via the existing LAN to the water heater. In other alternative embodiments, WiFi Ad Hoc or Direct WiFi is used to connect temperature sensors and operating devices.

In yet another embodiment, the invention provides a water heater in which an operating device can be connected through a wireless device to a control unit. The operating device is not limited to specialized dedicated operating devices here, and mobile phones with a specialized application installed, mobile phones which, as described above, communicate via their web browser with a web server integrated in the water heater, and personal computers can also be considered. that establish a connection through a web browser to a web server.

The invention additionally provides a water heater, in which: the memory is adapted to store the desired temperature for two or more spaces that must be heated; and the control unit is adapted to control the heating element based on the desired temperature in two or more spaces to be heated and the measured temperature. In this embodiment, the control unit has two or more target temperatures (desired temperatures) and one measured temperature and one measured value. One measured value may be the temperature in one of the spaces for which the desired temperature is specified, although it is also possible for the measured temperature to be a different temperature, such as, for example, the outside temperature in the case of weather-dependent temperature control. There are also two or more target temperatures. In the case where the water heater has many independent hot water circuits, and each of the desired temperatures essentially corresponds to a separate hot water circuit, then it is relatively easy to control each hot water circuit separately in order to realize the various desired temperatures. If this is not the case, the control unit will have to compromise, for example, by allowing tolerance at the desired temperature, or using ranges of desired temperatures instead of the desired temperatures. Alternatively, weighting may be used to indicate preference between the desired temperatures. If there are more desired temperatures than the measured temperatures, it is also necessary for the control unit to be able to evaluate with a certain degree of certainty the actual temperature of the spaces for which the desired temperature is entered, but for which the measured temperature is not available.

In yet another embodiment, the invention provides a water heater in which: an input / output unit is adapted to receive two or more signals, each of which represents a measured temperature; and the control unit is adapted to control the heating element based on the desired temperature in the space to be heated, or the desired temperatures in two or more spaces to be heated, and two or more measured temperatures. In a specific embodiment, the temperature signals are provided to the input / output unit via a wired connection. In a specific alternative embodiment, the temperature signals are provided wirelessly to the input / output unit. In yet another specific embodiment, temperature signals are provided through both wired and wireless connections.

In a further embodiment, a water heater is provided in which: the control unit determines a deviation between the desired temperature in the space to be heated or two or more spaces to be heated and the measured temperature or temperatures and applies weighting to the deviations in order to control the heating element. This is particularly recommended when there are more spaces with associated desired temperatures than there are independent hot water circuits. By weighing, it is possible to give priority to the particular desired temperatures, since the actual realized temperatures in spaces with the corresponding temperature are independent of each other.

In yet another embodiment, the invention provides a water heater further comprising a notification element for sending a notification via a communication means. The notification may, for example, contain an error message. The notification, for example, contains an email message or an SMS message.

In an embodiment according to the invention, a water heater is provided in which the device comprises a CH boiler or a combination boiler.

Additional advantages and options for implementation are discussed below in this document with reference to the accompanying drawings, in which:

Figure 1 shows a water heater with a thermostat according to the prior art.

Figure 2 shows an alternative water heater with a thermostat according to the prior art.

Figure 3 shows a water heater according to the present invention.

4 shows an additional embodiment of a water heater according to the present invention.

5 shows another embodiment of a water heater according to the present invention.

6 shows an alternative embodiment of a water heater according to the present invention.

7 shows a further alternative embodiment of a water heater according to the present invention.

Fig. 8 shows another alternative embodiment of a water heater according to the present invention.

Fig.9 is a schematic representation of the control unit and the heating element of the water heater in Fig.8.

10 is a flowchart showing how a water heater is controlled.

The water heater 10 (FIG. 1) according to the prior art comprises a water supply pipe 22. Water circulates in the hot water circuit through pump 24. Water is pumped through heat exchanger 26, where it is heated. Hot water leaves the water heater 11 through an opening 28 for discharging water. Water in the heat exchanger 26 is heated by means of a burner 30. The burner 30 contains an air / gas mixture from a mixer 32 (for example, a venturi). Air is sucked in by the fan 34 through the air supply pipe 36 and is blown into the mixer 32. Gas from the gas supply pipe 38 reaches the mixer 32 through the gas plug 39.

Fan 34 and pump 24 are controlled from an external thermostat 50 located elsewhere. The thermostat 50 is connected through a cable 42 to a water heater 10. Cable 42 is typically a two-wire connection. The thermostat 50 includes a temperature sensor 52, which generates a signal to the controller 54. The controller 54 is additionally connected to the control panel 56. The desired temperature can be entered and the program can be set via the control panel. The control panel is usually provided with a display screen on which the measured temperature is displayed. The display screen usually also displays information to facilitate entering the desired temperature or program.

Some prior art water heaters 10 are provided with a dual conduit to allow for the implementation of two hot water circuits. The hot water circuit 10 in FIG. 2 shows a first water supply pipe 22a in which water is pumped by the first pump 24a, after which water flows through the first heat exchanger 26a to the water outlet 28a. The first hot water circuit is thus supplied with hot water. A second hot water circuit supplies water to the second water supply line 22b. Water is pumped through the second pump 24b and goes through the second heat exchanger 26b to the second water outlet 28b. Two separate hot water circuits are implemented in this way. Otherwise, it is useful to combine the first and second heat exchanger 26a, 26b into one heat exchanger.

In both the water heater 10 in FIG. 1 and the water heater 10 in FIG. 2, the temperature controller is located in the thermostat 50. The controller determines the deviation between the temperature measured by the temperature sensor 52 and the desired temperature entered through the control panel 56. Based on this deviation, an indication is given via cable 42 that there is heat consumption and, in the case of a modulated signal, how much heat consumption is.

The water heater 100 (FIG. 3) according to the present invention substantially corresponds to the prior art water heater 10. Water is supplied through a water supply pipe 122 and circulated by a pump 124. Water is pumped through a heat exchanger 126 to a water outlet 128. The water in the heat exchanger 126 is heated by the burner 130. The burner burns the air / gas mixture. Air is sucked in through the air supply conduit 136 through a fan 134 and injected into the mixer 132. Gas moves from the gas supply conduit 138 through the gas plug 139 to the mixer 132, where it is mixed with air. A controller or control unit 154 that controls the fan 134 and pump 124, however, is now integrated not in the thermostat 50, but in the water heater 100 itself. This controller 154 contains a memory 153 in which the desired temperature can be stored, and an input / output unit 155 (Fig.9). The housing 150 is connected through a cable 42 to the input / output unit 155 of the controller 154 in the water heater 100. The housing 150 no longer includes a controller 54, but contains only a temperature sensor 152 that provides a signal representing the temperature. In addition, the control panel 156 is housed in the housing 150. Through this control panel 156, the desired temperature can be entered, which is transmitted via cable 42 to the controller 154 in the water heater 100 and stored in the memory 153. Other operating instructions, for example, on and off times in accordance with with the program entered through the control panel 156, can be transmitted via cable 42 to the control device 154, which stores them in the memory 153. Two signal lines are extended in the cable 42. They, however, are not necessarily two physically separated lennye conductors. Depending on the embodiment, this may, for example, also be a data bus.

In an alternative embodiment (FIG. 4), there are even two temperature sensors 152a, 152b connected to the control unit 154 in the water heater. The first temperature sensor 152a is housed in the same housing 150a as the control panel 156a, and is connected to the water heater 100 via a first cable 42a. The second temperature sensor 152b is housed in the second housing 150b and connected to the water heater 100 through a second cable 42b. In a specific embodiment, the first housing 150a with the first temperature sensor 152a is located in a room that is heated and whose temperature needs to be adjusted. The first temperature sensor measures the temperature in the room. The difference from the desired temperature set via the control panel 156a is also a deviation that must be eliminated by the control unit 154. A second housing 150b with a second temperature sensor 152b is placed externally. The second temperature sensor 152b thus senses the outside temperature. The controller 154 thus uses the signal from the first temperature sensor 152a to eliminate, through feedback, deviations detected in the internal temperature, while the controller 154 uses the signal from the second temperature sensor 152b to respond in advance to temperature changes outside by direct communication. In other embodiments, the second temperature sensor 152b, for example, is also located inside, but in a room other than, the temperature sensor 152a. It is very likely in this case that another control algorithm will also be needed.

In another embodiment (FIG. 5), the water heater 100 is adapted to supply hot water to two hot water loops. The water heater 10 comprises a first water supply pipe 122a. From the first water supply pipe 122a, water is pumped through the first pump 124a through the first heat exchanger 126a to the first water outlet 128a. This part forms part of the primary hot water circuit. From the second water supply pipe 122b, water is pumped through the second pump 124b through the second heat exchanger 126b to the second water outlet 128b. This part forms part of the second hot water circuit. Otherwise, it is useful to combine the first heat exchanger 126a and the second heat exchanger 126b into one heat exchanger with two separate water supply lines.

In this embodiment, as in the previous one, two temperature sensors 152a and 152b are connected to the water heater. The first temperature sensor 152a is placed in a first space that is heated by the first hot water circuit. A second temperature sensor 152b is placed in a second space that is heated by a second hot water circuit. Controller 154 now also has two separate control loops. The first uses the temperature measured by the first temperature sensor 152a and compares it with the first desired temperature set for the first space. Based on the deviation, this control loop controls the primary hot water pump 124a (and fan 134). The second control loop uses the temperature measured by the second temperature sensor 152b. It is compared with the second desired temperature set for the second space. The second hot water second pump 124b (and, of course, fan 134) is controlled based on the measured and desired temperature.

In a further embodiment (FIG. 6), the connection between the second temperature sensor 152b and the water heater 100 takes on a wireless form, for example via a Direct WiFi connection. The second housing 150b is provided for this purpose with a WiFi network transmitter / receiver 158b. The water heater 100 is also provided with a transmitter / receiver 168 of the WiFi network. Thus, no extra cables are needed.

In yet another embodiment (FIG. 7), the first housing 150a is provided with a control panel 156a. The control panel is connected to the transmitter / receiver of the WiFi network, similarly located in the first housing 150a. Via this WiFi network transmitter / receiver, the control panel communicates with the WiFi network transmitter / receiver 168 in the water heater 100. Messages sent from the control panel 156a to the water heater 100 mainly contain information about the buttons that have been pressed. Messages in the opposite direction mainly contain information that is displayed on the screen associated with the control panel 156a. In an embodiment, the control panel 156a is part of a specialized operating device (wireless remote control). In an alternative embodiment, the housing 150a is a mobile telephone housing that launches a dedicated application to communicate with the water heater 100 via a Direct WiFi connection.

In another embodiment (FIG. 8), the water heater 100 is provided with a web server 169. The web server has a (wireless or wired) connection, for example, to a home network 210 via a network card. The mobile phone or tablet computer 150a (with a keyboard and screen 156a) is equipped with a WiFi network chip and communicates wirelessly with the home network 210. The address of the web server 169 is accessed via an Internet browser on the mobile phone or tablet 150a. The web server presents the user interface for controlling the water heater 100 to the user of the mobile phone or tablet 150a. For example, the user has the ability to change the desired temperature, modify the program, view the measured temperature (via temperature sensor 152b), view the temperature change during the day, view information about state of the water heater 100 (for example, the number of hours the burner burns per day) and view error messages. If the home network 210 allows connections from the Internet, the technician is even given the opportunity to request help from the web server 169 via the Internet using his personal computer in order to repair malfunctions or, for example, perform an online combustion check.

In yet another embodiment (FIG. 9), the web server on which the user interface can be obtained is an external server, and the control unit 154 communicates with the web server via the Internet 210. The control unit 154 then only needs to have an IP address, so that it can be accessed via the Internet. The functions built into the water heater 100 are limited here to the actual control of the pump 124 and the fan 134. By providing a user interface on an external web server, it can be modified in a simple manner without the operations that must be performed for this purpose on the water heater 100. The user interface can, thus be improved and supplemented when new technical options become available. The control unit 154 on the water heater 100, which should contain only minimal hardware and software in order to be able to perform most of the basic functions, even when the connection to the outside world is lost, can then be reconfigured at any time when the user interface is modified.

In this embodiment, the control unit 154 has two operating modes; the first mode, in which the control is based on work instructions entered via the user interface and transmitted via the Internet to the input / output unit 155, and the second mode, in which the control is based on the desired temperature stored in the memory 153. This can be one temperature or previously a specific temperature program at certain points in time of the day. The first mode is the normal operating mode, while the second mode is the exception mode. This last mode serves only to guarantee the continuous operation of the water heater 100 in the unlikely event that the operating device 154 has not accepted any operating instructions, for example, due to a network failure to which the input / output unit 155 is connected. In both modes, the actually measured temperature coming from the temperature sensor 152 is used as a guide. In order to provide the possibility of implementing both operating modes, the actual control part 157 of the control unit 154 contains two operating programs, which are shown schematically here; an extensive normal operating program 162, which operates on the basis of work instructions received through the input / output unit 155, and a much more limited emergency program 161, which operates on the basis of information stored in the memory 153.

10 shows schematically how the control unit 154 switches between two operating modes. After the control cycle has begun at block 201, a check is performed at block 202 as to whether the input / output unit 155 receives signals that may contain operating instructions.

When this is the case, these instructions are read in block 203 and, among other information, the value T _{gew of the} desired temperature is obtained from them. The measured temperature T is then read in block 205. This measured temperature is then compared in block 206 with the desired temperature T _gew . If it follows from this comparison that the desired temperature has been reached, the control unit does not need to take any additional control action, and the program returns to check for the presence of input signals in block 202. If, on the other hand, it follows from the temperature comparison in block 206, that a control action is required, control signals for pump 124 and fan 134 are generated in block 207. The program then returns to block 202.

When it is determined in block 202 that the I / O block 155 does not accept (or did not accept) any work instructions, a switch to the emergency program is performed. The desired temperature value T _gew , which is stored in the memory 153, is then read in block 204. The program then continues to read the measured temperature in block 205. All additional program steps are identical to those taken when an input signal is detected.

Thus, it is possible to optimally use the capabilities of the Internet or other external resources in order to make user-friendly work available with a large number of options without having to perform an extensive modification of the hardware for this purpose in the water heater. In addition, the operational reliability of the water heater is always guaranteed, thus, even when the communication facility fails.

The described embodiments and embodiments shown in the drawings are only exemplary embodiments by way of illustration of the invention. The invention is not limited to these embodiments. One skilled in the art will recognize that many variations and modifications in the shown embodiments are possible within the scope of the invention. Instead of storing the desired temperature, another control parameter can also be stored in the memory of the control unit, for example, a table with on / off times. The I / O unit should then receive a time signal instead of a temperature signal. Thus, it is also possible to seamlessly combine the features of various embodiments in order to form new embodiments without departing from the invention. The embodiments shown are therefore not limiting on the scope of the desired protection. The scope of protection is defined solely by the following claims.

Claims (36)

1. A water heater (100) with at least one remote thermostat, comprising: heating element for heating water; an input / output unit adapted to receive a signal representing a measured temperature; and a control unit (154) for controlling the heating element based on the desired temperature and the measured temperature, the control unit (154) comprising a memory (153) for storing the desired temperature of the space to be heated and comprising an input / output unit (155) for the control unit; wherein at least one remote thermostat contains: case (150); a temperature sensor (152) that provides a signal representing the temperature; a control panel (156) by which a desired temperature is entered, which is transmitted to the control unit (154), moreover, the control unit (154), to which the desired temperature is transmitted and which is configured to determine the control action for exciting the heating element, is included in the water heater body (100). 2. The water heater according to claim 1, wherein the input / output unit is adapted to receive operating instructions from at least one operating device connected to the input / output unit, and the control unit is adapted to control the heating element based on the received operating instructions. 3. The water heater according to claim 2, wherein the control unit is adapted to store the received operating instructions in memory. 4. The water heater according to claim 2 or 3, in which a predetermined desired temperature or a predetermined program for the desired temperature is stored in memory, and the control unit is adapted to control the heating element based on, respectively, a predetermined temperature or a predetermined program when work instructions, respectively, were not accepted or retained. 5. The water heater according to any one of the preceding paragraphs, in which the input / output unit further comprises a network communication unit for exchanging data over the network. 6. The water heater according to claim 5, further comprising a web server configured to present access to a user interface via a network communication unit for controlling the water heater. 7. The water heater according to claim 6, wherein the user interface, accessible via a web server, is accessible through a network communication unit. 8. The water heater according to claim 6 or 7, wherein the user interface is adapted to provide the user with the ability to perform at least one of the following actions: - entering the desired temperature; - entering a program for the desired temperature; - viewing the measured temperature; - viewing status information related to the water heater; - view service information; - view error messages; - viewing operational data; and - adjustment of the water heater. 9. The water heater according to any one of the preceding paragraphs, wherein the input / output unit comprises a wireless communication device. 10. The water heater of claim 9, wherein the operating device may be connected via a wireless communication device to a control unit. 11. A water heater according to any one of the preceding paragraphs, in which: the memory is adapted to store the desired temperature for two or more spaces that must be heated; and the control unit is adapted to control the heating element based on the desired temperature in two or more spaces to be heated and the measured temperature. 12. A water heater according to any one of the preceding paragraphs, in which: an input / output unit is adapted to receive two or more signals, each of which represents a measured temperature; and the control unit is adapted to control the heating element based on the desired temperature in the space to be heated, or the desired temperatures in two or more spaces to be heated, and two or more measured temperatures. 13. A water heater according to any one of the preceding paragraphs, in which: the control unit determines the deviation between the desired temperature in the space to be heated, or two or more spaces to be heated, and the measured temperature or temperatures, and applies weighting to the deviations in order to control the heating element. 14. The water heater according to claim 9, further comprising a notification element for sending a notification via a wireless device. 15. A water heater according to any one of the preceding claims, wherein the water heater is a CH boiler or a combination boiler.

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