NL2006176C2 - HOT WATER DEVICE. - Google Patents

Description

Hot water installation

The present invention relates to a hot water device.

Conventional systems for central heating (central heating) of buildings include a central boiler in which a burner burns gas. The heat released during incineration is transferred to water with the aid of a heat exchanger. A pump in the boiler pumps the heated water through a pipe system in the building to radiators, which radiators transfer the heat from the water to the room in which the radiator is installed, mainly through radiation and convection. The cooled water reaches the boiler again via return pipes where the water is heated.

The boiler is controlled from a thermostat. The thermostat is installed in one of the rooms to be heated. The thermostat comprises a temperature sensor and an operating means for setting a desired temperature. The thermostat originally consisted of a bimetallic switch or mercury switch that sent an on / off signal to the boiler. Nowadays, temperature-dependent electronic components are used as a temperature sensor. Furthermore, modern thermostats 25 no longer provide an on / off signal, but instead transmit a modulated signal to the boiler in order to be able to signal a variable heat demand. Modern thermostats are also often equipped with a clock, so that the thermostat can also follow a time-dependent program. For historical reasons, however, these thermostats 30 still communicate over a two-wire connection with the boiler. Although not an insurmountable problem, it imposes a number of limitations. For compatibility reasons, the thermostat 2 has been condemned to have its own power supply (generally a battery) and sending additional information in addition to the heat demand over the two-wire connection overhead and costs.

The aim of the present invention is to make a next step in the development of heating boilers that offers a new range of functionality.

This object is achieved by providing a hot water device, comprising: a heating means for heating water; a control unit for controlling the heating element, the control unit comprising a memory for storing a desired temperature of a space to be heated, and an input / output unit; wherein the input / output unit 15 is adapted to receive a signal representative of a measured temperature; and wherein the control unit controls the heating member based on the desired temperature and the measured temperature. The core of the present invention is the insight that the control unit, or the controller in control technical terms, does not belong at the location of the temperature sensor, but at the location of the boiler.

Obviously this has grown historically, because in conventional thermostats, the temperature sensor and the controller were a single physical component. With the advent of electronic temperature sensors, such as, for example, temperature-dependent resistors, thermostats with separate components were created for monitoring the temperature on the one hand and determining the control action on the other. Due to the nature of a central heating installation, namely the central generation of heat, which heat is subsequently distributed over the different locations in the house where there is a heat demand, there is something to be said for determining the heat demand at the boiler. to take place. Therefore, compared to a conventional central heating installation, the controller must be removed from the thermostat and moved to the central heating boiler. In the first instance, the traditional thermostat degrades into a temperature sensor and control device. The "thermostat" determines a deviation based on the measured temperature and the set temperature and transmits it to the boiler. In the boiler 10, the control unit determines the control action associated with the deviation to control the heater. (In most cases, the heater is controlled by controlling the speed of a fan that sucks in the air that burns gas in a burner.) However, by going one step further than just physically moving the controller (the control unit) , however, a larger range of options is created. This further step is also to determine the deviation in the control unit (in the boiler). The traditional thermostat thus degrades to just a temperature sensor. The advantages of this are discussed with reference to the embodiments below.

Although it is not strictly necessary to include the control unit in the housing of the hot water device, this is preferred.

The space to be heated is not necessarily limited to a single room. For example, in residential homes, there is traditionally only a single thermostat with which the temperature in a single room is measured, and on which only a single desired temperature can be set. The central heating system in those cases, however, heats more than one room. Although the temperature of the room in which the thermostat is suspended is probably 4 the temperature that is closest to the set desired temperature most of the time, the same thermostat is used to "control" the temperature in the further rooms. By analogy, the concept of space in the present invention should not be read to a limited extent as a single room. A room can comprise one or more rooms. In some cases, a space may even comprise only a part of a room, for example in the case of a long corridor with a great deal of heat loss, in which both ends of the corridor are heated by an own radiator with its own control circuit.

The measured temperature does not necessarily have to be the temperature in a room. In so-called weather-dependent temperature controls use is made of an outside thermometer and a forward-coupled control circuit (feed forward controller). The forward-linked control circuit determines the control action on the basis of the outside temperature, a known (assumed) effect of the disturbance (outside temperature) and a known (assumed) effect of the control action (the operation of the heater).

In a further embodiment, a hot water device is provided, wherein the input / output unit is adapted to receive operating instructions from at least one operating device connected to the input / output unit. In a specific embodiment, the input / output unit comprises a two-contact input / output for two-way communication with a control device with integrated temperature sensor.

The input / output unit is adapted to send and receive messages via the two-contact input / output according to a protocol suitable for two-way communication on a two-wire connection and for multiplexing messages from the control device and the temperature sensor. In an alternative, specific embodiment, the input / output unit is arranged such that use is made of two physically separate one-way connections. In yet another alternative, specific embodiment, the input / output unit is arranged such that use is made of two physically separate connections for the temperature sensor and the operating device. In yet an alternative, specific embodiment, the input / output unit is arranged such that use is made of three physically separate one-way connections: one for input of messages from the temperature sensor, one for input of messages from the operating device, and one for output of messages from the operating device.

In a further embodiment, a hot water device is provided, further comprising the input / output unit comprising a network interface unit, for exchanging data over a network. By including a network coupling unit in the input / output unit, it is possible to connect components, such as for example the temperature sensor or the operating device, to the control unit over a network connection, for example an already existing home LAN or office LAN.

Such a LAN is preferably based on TCP, UDP and IP protocols over Ethernet.

In a further embodiment, the present invention provides a hot water device, further comprising a web server for providing a user interface for operating the hot water device via the network interface unit. In yet a further embodiment, the invention provides a hot water device, wherein the user interface made available by the Web server 6 is accessible via the network interface unit. In yet a further embodiment, the invention provides a hot water device, wherein the user interface 5 is adapted to have the user perform at least one of the following actions: entering a desired temperature; entering a program for a desired temperature; viewing a measured temperature; viewing status information regarding the hot water device; viewing maintenance information; viewing fault messages; viewing performance data; and adjusting the hot water device. By means of the built-in Web server, it is possible to browse, for example, the browser from a smartphone to the Web server of the hot water device. The user is then shown a user interface, with which the user can operate, program or view information on the hot water device. For example, it is possible to view the measured temperature of the connected temperature sensors, to enter or change a desired temperature for a room, to enter or change a temperature change program during the day or week, to enter a holiday program set or activate, read status information or maintenance information.

The obvious way to enable operation via a network from a prior art installation would be to provide a traditional thermostat (with temperature sensor, control and controller integrated) with a network interface and a built-in Web server.

7

A further embodiment according to the invention provides a hot water device, wherein the input / output unit comprises a wireless communication device. In a specific embodiment, the communication device uses one of the WiFi protocols. The communication device can serve as a WiFi access point. Alternatively, however, the communication device is a WiFi client that connects to an existing WiFi access point. In this configuration, the hot water device forms part of the LAN to which the WiFi access point belonged and temperature sensors and operating devices can be connected to the hot water device via the existing LAN.

In yet alternative embodiments, WiFi Ad Hoe or Direct WiFi is used to connect the temperature sensors and control devices.

In yet a further embodiment, the invention provides a hot water device, wherein the operating device can be connected to the control unit via the wireless communication device 20. The operating device is hereby not limited to specialized, dedicated operating devices, but also mobile telephones with a "dedicated" application installed, mobile telephones which, as described above, make contact with their web browser with a Web server built into the hot water device, and personal computers that make contact with the Web server via a web browser.

The invention further provides a hot water device, wherein: the memory is arranged to store a desired temperature for two or more spaces to be heated; and the control unit is arranged to control the heating element on the basis of the desired temperature in the two or more spaces to be heated and the measured temperature. In this embodiment, the control unit has two or more target temperatures (the desired temperatures) and a single measured temperature and a single measured value. The single measured value can be the temperature in one of the spaces for which a desired temperature is specified, however, it is also possible that the measured temperature is a different temperature, such as for example an outside temperature in the case of a weather-dependent temperature control. Furthermore, there are two or more target temperatures here. In the case that the hot water appliance has several independent hot water circuits and each of the desired temperatures substantially corresponds to its own hot water circuit, it is relatively easy to control each hot water circuit separately to realize the different desired temperatures. If this is not the case, the control unit will have to realize a form of compromise, for example by allowing a tolerance at the desired temperature, or instead of operating with desired temperatures, with desired temperature ranges. Alternatively, a weighting can be used to indicate a preference between the desired temperatures. In addition, if there are more desired temperatures than measured temperatures, it is necessary for the control unit to be able to estimate with a certain degree of reliability the actual temperature of the spaces for which the desired temperature is entered, but no measured temperature is available.

In yet a further embodiment, the invention provides a hot water device, wherein: the input / output unit is adapted to receive two or more signals, each of which is representative of a measured temperature; and the control unit is arranged to control the heating element on the basis of the desired temperature in the space to be heated or the desired temperatures in the two or more spaces to be heated, and the two or more measured temperatures. In a specific embodiment, the temperature signals are presented to the input / output unit via a wired connection. In a specific alternative embodiment, the temperature signals are supplied wirelessly to the input / output unit 10. In yet a further specific embodiment, the temperature signals are offered via both wired and wireless connections.

In a further embodiment a hot water device is provided, wherein: the control unit 15 determines a deviation between a desired temperature in the space to be heated and the two or more spaces to be heated and the measured temperature or temperatures and applies a weighting to the deviations for controlling of the heating member. This is particularly preferred if there are more spaces with associated desired temperatures than there are independent hot water circuits. The weighting makes it possible to give priority to specific desired temperatures, since the actual realized temperatures in the spaces with a corresponding temperature are not independent of each other.

In yet a further embodiment, the invention provides a hot water device, further comprising a notification device, for transmitting a notification via the communication device. The notification may, for example, include an error message. The notification comprises, for example, an e-mail message or an SMS message.

10

In an embodiment according to the invention, a hot water device is provided, wherein the device comprises a central heating boiler or a combi boiler.

Further advantages and embodiments are discussed below with reference to the accompanying figures, in which:

Figure 1 shows a hot water appliance with thermostat according to the prior art;

Figure 2 shows an alternative hot-water appliance with thermostat according to the prior art;

Figure 3 shows a hot water device according to the present invention;

Figure 4 shows a further embodiment of a hot water appliance according to the present invention; Figure 5 again shows a further embodiment of a hot water appliance according to the present invention;

Figure 6 shows an alternative embodiment of a hot water appliance according to the present invention;

Figure 7 shows a further alternative embodiment of a hot water appliance according to the present invention; and

Figure 8 shows yet another alternative embodiment of a hot water appliance according to the present invention.

A hot water appliance 10 (Figure 1) according to the prior art comprises a supply pipe 22 for water. The water is pumped around the hot water circuit by a pump 24. The water is pumped through a heat exchanger 26 where it is heated. The hot water leaves the hot water appliance 10 via the water outlet 28. The water in the heat exchanger 26 is heated by a burner 30. The burner 30 receives an air / gas mixture from a mixer 32 (e.g. a venturi). Air is drawn in by a fan 11 via an air supply 36 and the mixer 32 blown in. Gas from a gas supply 38 reaches the mixer 32 via a gas block 39.

The fan 34 and pump 24 are controlled from an external thermostat 50 located elsewhere.

The thermostat 50 is connected to the hot water device 10 via a cable 42. The cable 42 is typically a two-wire connection. The thermostat 50 comprises a temperature sensor 52 which outputs a signal to a controller 54. The controller 54 is further connected to a control panel 56. Via the control panel a desired temperature can be entered, programs can be set. The control panel is usually provided with a display screen on which the measured temperature is displayed. In addition, information is usually displayed on the display screen to facilitate entering a desired temperature or program.

Some hot water appliances 10 according to the prior art are provided with a double pipe in order to be able to realize two hot water circuits. The hot water appliance 10 of Figure 2 shows a first water supply 22a, in which the water is pumped through a first pump 24a, whereafter the water runs via a first heat exchanger 26a to the water drain 28a. The first hot water circuit is hereby provided with hot water. The second hot water circuit supplies water to the second water supply 22b. The water is pumped through the second pump 24b and runs via the second heat exchanger 26b to the second water outlet 28b. Two separate hot water circuits are realized in this way. Incidentally, it is advantageous to integrate the first and second heat exchangers 26a, 26b into a single heat exchanger.

12

In both the hot-water appliance 10 of Fig. 1 and the hot-water appliance 10 of 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 via the control panel 56. On the basis of this deviation, it is signaled via the cable 42 that there is a heat demand and, in the case of a modulated signal, how large the heat demand is.

The hot-water appliance 100 (Figure 3) according to the present invention largely corresponds to the hot-water appliance 10 according to the prior art. Water is supplied via a water supply 122, and pumped around by means of a pump 124. The water is pumped via a heat exchanger 126 to the water outlet 128. The water in the heat exchanger 126 is heated by a burner 130. The burner burns an air / gas mixture. Air is drawn in via an air supply 136 through a fan 134 and the mixer 132 blown in. Gas enters from gas supply 138 via gas block 139 into mixer 132, where it mixes with air. However, the controller 154 which controls the fan 134 and the pump 124 is now not included in the thermostat 50, but in the hot water appliance 100 itself. A housing 150 is connected via a cable 42 to the hot water appliance 100. The housing 150 no longer comprises a controller 54. The temperature sensor 152 provides a signal representative of the temperature. In addition, a control panel 156 is provided in the housing 150. Two signal lines are shown in cable 42. However, these are not necessarily two physically separated conductors.

Depending on the embodiment, this can also be, for example, a data bus.

13

In an alternative embodiment (Figure 4), even two temperature sensors 152a, 152b are connected to the control unit 154 in the hot water appliance. The first temperature sensor 152a is accommodated in the same housing 150a as a control panel 156a and is connected to the hot water appliance 100 via a first cable 42a. A second temperature sensor 152b is included in a second housing 150b and connected to the hot water appliance 100 via a second cable 42b. In a specific embodiment, the first housing 150a with the first temperature sensor 152a is in a room that is heated and where the temperature is to be controlled. The first temperature sensor registers the temperature in the room. The difference with the desired temperature set via the control panel 156a is directly the deviation to be controlled by the controller 54. The second housing 150b with the second temperature sensor 152b is placed outside. The second temperature sensor 152b thus observes the outside temperature. The first temperature sensor 152a dispels observed deviations in the inside temperature by means of a feedback, while the second temperature sensor 152b proactively responds to temperature changes outside by means of a forward coupling. For example, in other embodiments, the second temperature sensor 152b is also placed inside, but in a different room than the temperature sensor 152a. In that case, a different control algorithm is probably also needed.

In another embodiment, the hot water appliance 100 is adapted to provide two hot water circuits with hot water. The hot water appliance 10 comprises a first water supply 122a. From the first water inlet 122a, the water is pumped through the first pump 124a via the first heat exchanger 126a to the first water outlet 128a 14. This part is part of the first hot water circuit. Water is pumped from a second water inlet 122b through a second pump 124b via the second heat exchanger 126b to the second water outlet 128b. This part is part of the second hot water circuit. Incidentally, it is advantageous to integrate the first heat exchanger 126a and the second heat exchanger 126b into a single heat exchanger with two separate water passages.

In this embodiment, just as in the previous one, two temperature sensors 152a and 152b are connected to the hot water appliance. The first temperature sensor 152a is included in a first space that is heated using the first hot water circuit. The second temperature sensor 152b is accommodated in a second space that is heated with the aid of the second hot water circuit. The controller 154 now also has second separate control circuits. The first uses the temperature measured by the first temperature sensor 152a and compares it with a first set desired temperature for the first space. Based on the deviation, this control circuit controls the pump 124a of the first hot water circuit (and the fan 134). The second control circuit uses the temperature measured by the second temperature sensor 152b. This is compared with a second set desired temperature for the second room. Based on the measured and desired temperature, the second pump 124b of the second hot water circuit is controlled (and of course fan 134 again).

In a further embodiment (Figure 6), the communication between the second temperature sensor 152b and the hot water device 100 is wireless, for example via a Direct WiFi connection. To that end, the second house 150b 15 is provided with a WiFi network transmitter / receiver 158b. The hot water appliance 100 is also provided with a WiFi network transmitter / receiver 168. As a result, it is not necessary to draw extra cables.

In yet another embodiment (Figure 7), a first housing 150a is provided with a control panel 156a. The control panel is connected to a WiFi network transmitter / receiver also arranged in the first housing 150a. Via this WiFi network transmitter / receiver, the control panel communicates with a WiFi network transmitter / receiver 168 in the hot water appliance 100. Messages sent from the control panel 156a to the hot water appliance 100 mainly contain keys that have been pressed. Messages in the opposite directions mainly contain information which is displayed on the screen associated with the control panel 156a. The control panel 156a is in one embodiment part of a "dedicated" operating device (wireless remote control). In an alternative embodiment, housing 150a is the home of a mobile telephone running a dedicated application to communicate with the hot water appliance 100 via a Direct WiFi connection.

In another embodiment (Figure 8), the hot water device 100 is provided with a Web server 169. The Web server is connected via a network card (wireless or wired) to, for example, a home network 210. A mobile telephone 150a (with a keyboard and display 156a) is provided with a WiFi network chip and communicating wirelessly with the home network 210. The address of the Web server 169 is visited via an internet browser on the mobile telephone 150a. The Web server presents the user of the mobile phone 150a with a user interface to operate the hot water appliance 100. For example, the user 16 is able to change the desired temperature, adjust a program, view the temperature measured by the temperature sensor 152b, view the temperature trend over the day, view status information 5 of the hot water appliance 100 (e.g., number of hours per day) and error messages. If the home network 210 permits connections from the Internet, it is even possible that a technician with his personal computer consults the Web server 169 via the Internet in order to rectify malfunctions, or, for example, to perform an online combustion check.

The described embodiments and the embodiments shown in the figures are only exemplary embodiments to illustrate the invention. The invention is not limited to these embodiments. It is clear to those skilled in the art that many variations on and modifications of the embodiments shown are possible within the invention. Thus, it is without doubt possible to combine features of different embodiments into new embodiments without departing from the invention. The embodiments shown are therefore not restrictive of the requested scope of protection. The scope of protection is only determined by the following claims.

25

Claims (13)

A hot water device comprising: a heating means for heating water; 5 a control unit for controlling the heating element, the control unit comprising a memory for storing a desired temperature of a space to be heated, and an input / output unit; wherein the input / output unit is adapted to receive a signal representative of a measured temperature; and wherein the control unit controls the heating member based on the desired temperature and the measured temperature. 15 Hot water device 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. 20 A hot water device according to claim 1 or 2, further comprising the input / output unit comprising a network interface unit for exchanging data over a network. 25 4. Hot water device according to claim 1, 2 or 3, further comprising a web server for providing a user interface for operating the hot water device via the network coupling unit. Hot water device according to any of claims 1-4, wherein the user interface made available by the Web server is accessible via the network interface unit. 6. Hot water device as claimed in any of the claims 1-5, wherein the user interface is adapted to have the user perform at least one of the following actions: - entering a desired temperature; - entering a program for a desired temperature; - viewing a measured temperature; - viewing status information regarding the hot water device; - viewing maintenance information; 15. viewing fault messages; - viewing performance data; and - adjusting the hot water device. 7. Hot water device according to any of claims 1-6, wherein the input / output unit comprises a wireless communication device. 8. Hot water device as claimed in any of the claims 1-7, wherein the operating device can be connected to the control unit via the wireless communication device. 9. Hot water device as claimed in any of the claims 1-8, wherein: the memory is adapted to store a desired temperature for two or more spaces to be heated; and the control unit is arranged to control the heating element on the basis of the desired temperature in the two or more spaces to be heated and the measured temperature. The hot water device of any one of claims 1-9, wherein: the input / output unit is adapted to receive two or more signals, each of which is representative of a measured temperature; and the control unit is adapted to control the heating element on the basis of the desired temperature in the space to be heated or the desired temperatures in the two or more spaces to be heated, and the two or more measured temperatures. 15 11. Hot water device as claimed in any of the claims 1-10, wherein: the control unit determines a deviation between a desired temperature in the space to be heated and the two or more spaces to be heated respectively and the measured temperature or temperatures and applies a weighting to the deviations for controlling the heating member. 12. Hot water device as claimed in any of the claims 1-11, further comprising a notification device, for transmitting a notification via the communication device. 13. Hot water device, wherein the device comprises a central heating boiler or a combi boiler.