BE1025198B1 - SYSTEM FOR MONITORING THE USE OF UTILITIES IN HOUSES OR BUILDINGS - Google Patents

Abstract

System for monitoring the consumption of utilities (1) in houses or buildings, characterized in that a local web server (2) installed in the house or building registers all measured consumption of utilities from consumption meters (6,7a, 7b, 7c, 10, 11,12,17,18,19,20) and stores it locally, and generates from this data web pages (24,30) that can be displayed locally and / or uploaded to another server or computer (4) at a distance.

Description

System for monitoring the consumption of utilities in homes or buildings.

The present invention relates to a system for monitoring the consumption of utilities in homes or buildings.

More specifically, the invention is intended for monitoring energy consumption in the form of electricity, gas, fuel oil, but also for the consumption of other utilities such as water.

It is known that almost every home or building is equipped with a meter for electricity consumption, a meter for gas consumption, and a meter for water consumption.

Traditionally the meter readings are passed on to the suppliers once a year, usually by the residents themselves who transmit the data by telephone or via the internet, or, if the meters are smart meters, they can pass on their meter reading to the suppliers themselves.

A disadvantage of such traditional systems is that they do not make a distinction according to the different consumption points within the home or the building, nor give any history of peaks and troughs during the consumption year.

It is therefore also difficult to identify abnormally large consumers or to get a picture of the consumption at each supply point for the utility in the home.

Another drawback of such traditional systems is that they do not provide information about the instantaneous consumption at any time of the day, i.e. do not provide real-time information about the consumption.

An additional disadvantage is that these traditional systems do not continuously monitor the proper functioning of the meter or the utility provision, which can lead to unexpected and unpleasant consequences.

Classic is the occurrence of a water leak that is only discovered late, because the abnormal consumption on the water meter was not noticed.

For example, unnoticed electricity flows can occur such as leakage currents that cause unexpected meter results.

In homes equipped with solar panels, not only the electricity generated from solar energy is measured, but also energy meters from the energy supplier must often be reversed. The proper functioning of all this is not continuously monitored, which can lead to unforeseen loss of electrical energy.

The present invention has for its object to provide a solution to the aforementioned and other disadvantages in that it provides a system which allows the consumption of utilities to be displayed in more detail and at any time and to be registered automatically.

The invention relates to a system for monitoring the consumption of utilities in houses or buildings, in which a local Web server is arranged in the house or building, registers all measured consumption of utilities of consumption meters and saves them locally, and generates from this data web pages that can be displayed locally and / or uploaded to another remote server or computer.

An advantage of such a system is that the system allows not only to monitor the current consumption of the various utilities, but that its history can also be reconstructed.

The consumption meters preferably comprise one or more consumption meters for electricity and / or gas and / or fuel oil and / or water, so that the total consumption in a home or building can be monitored with this.

The consumption meters can also include one or more socket plugs that measure the local consumption from fixed supply points. These consumption meters are especially useful for monitoring the collection of an individual device or socket.

These socket plugs consist of a measuring module that is plugged into the socket and that measures the amount of electrical energy taken at the socket.

The consumption meters can also include one or more smart meters. Such a smart meter is capable of measuring the offtake for a specific home or building and automatically communicating it to the utility supplier.

The consumption meters can also be one or more meters, which are part of fuses on an electricity board, or part of a meter on an electricity board that itself is connected to analog meters such as a gas volume meter or a water volume meter.

Preferably, the local Web server communicates simultaneously wirelessly and via wiring.

The communication via wiring is done via pulse inputs for connecting energy meters with pulse output, or via a serial connection for connecting, for example, smart meters equipped with a P1 port.

The server's wireless communication runs simultaneously via Wi-Fi with the local network to connect to local tablets and PCs, and via 868MHz radio waves to connect to socket plugs, socket thermostats, radiator thermostats or other components of the monitoring system of consumption.

Preferably, each measuring module connected to the local Web server for measuring consumption is provided with a unique serial number, which is also printed on each measuring module, and with which the local Web server can independently recognize and set all necessary settings and parameters to configure itself. and auto configuration possible.

The local Web server always recognizes the signal strength between the server and the Wi-Fi network on the one hand and between each measuring module and the local Web server on the other, and these signal strengths can be graphically displayed to detect communication problems in a timely manner.

Preferably, the local Web server works according to the master-slave principle as well as the everyone-master principle using the unique serial numbers of the measuring modules.

According to the master-slave principle, the local Web server calls each measuring module one by one as a master via an RF broadcast, each measuring module recognizing its serial number as a slave and sending its measured consumption data back to the local Web server, which then saves the consumption data.

According to the everyone-master principle, each measurement module itself checks whether the communication bus is free and then forwards its current modified measurement values as a master to the local Web server in response to a status change in the measurement values, whereby the local Web server can recognize the sending measurement module by its serial number, and then as a slave can make the changed data visible on the web pages in real time.

A status change in the measured values can consist of a change in flow, power, temperature, switching on or off or other measured values.

The local Web server shows in real time both the signal strength between the local Web server and the Wi-Fi router, and the signal strength between the local Web server and each individual wireless measurement module; and these signal strengths can be used to set the optimal positioning of the local Web server and measurement modules.

With each data recording by the local Web server, the firmware version of each individual RF module is also sent, after which the firmware versions of the measurement modules and of the local Web server itself are compared with the online versions once every 24 hours, so that these firmware versions are automatically or manually if necessary. get an update via wireless way.

The local Web server is preferably used for both the configuration of the system, such as setting up the Wi-Fi network, adding measurement modules, entering energy prices and setting time switches, as well as for the local storage of all measurement data and for the operation of consumers and the visualization of measurement data, ie energy consumption, measurement values, energy costs, graphs with history of energy consumption and energy costs, the real-time EPC number of the building that shows the energy efficiency of the building, or of other measurement data , and all without requiring internet, external software, apps or cloud applications, so that the application software appears platform-independent on the web pages, and is generated in real time in the local Web server itself.

With the insight to better demonstrate the characteristics of the invention, a few preferred applications of the method for monitoring the consumption of utilities in homes or buildings according to the invention are described below with reference to the the accompanying drawings, in which: figure 1 schematically represents a system for monitoring the consumption of utilities according to the invention; Figure 2 represents a web page provided by the local Web server of the system; Figure 3 shows reports of the history of the consumption of utilities.

Figure 1 schematically shows a system 1 for monitoring the consumption of utilities in a home or a building according to the invention. The system consists of a local Web server 2, which is set up in the home or the building, and is connected wirelessly via wifi 3 to the local network and the local tablets and PCs 4 in the home. The local Web server 2 is also wirelessly connected via a radio connection 5 with a radio frequency (RF) of 868 MHz with socket plugs 6, socket thermostats 7a, radiator thermostats on batteries 7b, pulse inputs on batteries 7c and one or more radio frequency access ports 8, also called RF gateways .

The local Web server 2 is also connected via a wiring 9 to pulse inputs of energy meters with pulse output, in this case a water meter 10, a gas meter 11, and an electricity meter 12. The local Web server 2 is also connected via a wiring 13 to a serial connection for connecting to the PI port on a smart or digital meter 14 of a utility network operator. The local Web server 2 is also connected via a USB cable to a source for electricity.

The radio frequency access port 8 is connected to a main measuring module 15, which is connected via a bus connection 16 (RS485 Modbus) to a number of measuring modules 17, 18, 19, 20 on a fuse board, each measuring the electricity consumption of subcircuits or individual large devices in the electrical network of the home or building.

The main measurement module 15 is also connected via a wiring 21 to pulse outputs of consumption meters with pulse output, in this case a gas meter 22 and a water meter 23 and via a serial connection for coupling to the PI port on a smart or digital meter 14 from a utility manager.

Figure 2 shows a web page 24 that is generated by the local Web server 2 and which can be viewed, for example, on a PC 4 of the local network 3. The web page displays the status of each consumption meter or measurement module 25, with its unique serial number 26, and the update status (upgrade) or firmware version 27 of the system. The signal strength of the Wi-Fi network 28 as well as of the measuring modules 29. The web page 24 provides an overview of all measuring modules of the system and of the operational state of all connections, both wireless and wired.

Figure 3 shows a webpage 30 which is generated by the local Web server 2 and which can be displayed, for example, on a tablet of the local network 3.

The web page 30 displays the results of the access port 31 (gateway) with a link to the consumption meters, in this case 32, 33 and 34. In the upper row 35, the individual data is presented per consumption meter. For example, column 32 is a consumption meter for a circuit with a refrigerator and a burner, the status of which is shown in row 35. For example, column 33 is a circuit for a garage with associated lighting and door opener, and for example, column 34 is a circuit which operates a PC printer and a gas meter.

In the second row 36, history of consumption is shown, with an overview 40 of the accumulated consumption being shown for a period of a day, a month and a year of all connected consumption meters according to the column.

In the third row 37, history is shown with the course of consumption. In column 31, in row 37, an overview of a number of consumptions during one day is shown as a function of the hour of the day in the form of colored time blocks. In column 32 a row 42 is shown in row 37 with the consumption of in this case a refrigerator as a function of the days in the month. In column 33, in row 37, an overview 43 of the accumulated consumption is shown for a period of a day, a month and a year for the consumption in the garage in this case.

In the third row of column 34 a graph 44 is shown with the daily consumption of in this case a PC printer as a function of the hour in the day.

In the further rows 38, 39, ... several representations of the consumption can be generated, depending on whether several consumption meters have been configured in the system.

The operation of the system for monitoring the consumption of utilities in homes or buildings 1 is very user-friendly and as follows.

The local Web server 2 is used for the configuration of the system, for the storage of all measurement data, and for the visualization and operation for the benefit of the users.

In a first phase, the local Web server 2 will be positioned at the most suitable localization in the home or building, assisted by the real-time signal strengths that the local Web server 2 detects and displays for each individual measurement module. The local Web server 2 uses the unique serial numbers printed on each measurement module, which allow the local Web server to independently recognize and set all necessary settings and parameters.

The local Web server 2 uses both Wi-Fi wireless connections 3 and radio-frequency 868 MHz connections 5, which can bridge larger distances and multiple wall passages than Wi-Fi. The local Web server 2 can also make use of wired connections 9 to consumption meters with pulse output, whereby the position of the local Web server 2 will be chosen such that this wiring 9 is as short as possible and can be laid as easily as possible.

Subsequently, all measuring modules in the home or building are fitted in the places provided: on the consumption meters of the general utilities electricity 12, gas 11 and water 10, the main measuring module 15 but also the measuring modules 17, 18, 19, 20 on the sub-circuits or isolated devices that can be found on the fuse board at the level of the fuses. Finally, individual socket plugs 6 and socket thermostats 7 can be installed to monitor the consumption at the outlet of the socket.

A radio frequency access port 8 is also installed on the fuse board, which is connected to a main measuring module 15, which itself is connected via a bus connection 16 (RS485 Modbus) to a number of measuring modules 17, 18, 19, 20 on the fuse board. The radio frequency access port 8 ensures the wireless connection between the main measurement module 15 and the local Web server 2.

The local Web server 2 will now recognize all measuring modules by their unique serial number 26, and will configure the system 1 autonomously.

After this auto configuration, the web pages generated by the local Web server 2 can be viewed via a tablet, PC or notebook on the local Wi-Fi network of the local Web server 2.

The web pages provide real-time information about how much consumption there is at each monitored off-take point, but also provide history about the course of consumption as a function of time over hours, days, months and years.

This information allows the user to specifically improve the energy efficiency of his home or building by, for example, switching off too large consumers remotely, or adjusting the temperature remotely, or replacing certain devices with more energy-efficient ones. The system makes it possible to send instructions from the local Web server to the various measurement modules, whereby closing the relevant drain point is possible.

The web pages also provide real-time visual information about the signal strength of each measurement module, so that communication failures come to light quickly and can be corrected in time.

The local Web server 2 finally offers the advantage that no internet, external software, apps or cloud applications are required, and everything is done independently of software in the local Web server 2, which generates the web pages in real time and can display history with the stored measurement data.

The present invention is by no means limited to the embodiment described by way of example and shown in the figures, but a system for monitoring the consumption of utilities in homes or buildings according to the invention can be realized in all kinds of forms and configurations without going beyond the scope of the invention. invention as described in the following claims.

Claims (16)

Conclusions. 1. - System for monitoring the consumption of utilities (1) in houses or buildings, characterized in that a local Web server (2) installed in the house or building registers all measured consumption of utilities from consumption meters (6,7a, 7b , 7c, 10, 11,12,17,18,19,20) and stores it locally, and generates from this data web pages (24,30) that can be displayed locally and / or uploaded to another server or computer (4) remotely. System for monitoring consumption according to claim 1, characterized in that the consumption meters comprise one or more consumption meters for electricity (12), and / or gas (11, 22), and / or fuel oil and / or water (10). , 23). The consumption monitoring system according to claim 1, characterized in that the consumption meters comprise one or more socket plugs (6, 7a) or one or more measuring modules on batteries (7b, 7c) that local consumption from fixed collection points measure. System for monitoring consumption according to claim 1, characterized in that the consumption meters comprise one or more smart meters (14). The consumption monitoring system according to claim 1, characterized in that the consumption meters (17, 18, 19, 20) are one or more measuring modules that form part of fuses on an electrical board and via a bus connection (16) are connected to a main measurement module (15) on an electricity board which itself is connected via wiring (21) to analog meters such as a gas meter (22) or a water meter (23) or to the smart meter of the network operator (14). The system for monitoring consumption according to claim 1, characterized in that the local Web server (2) communicates wirelessly and via wiring simultaneously. System for the consumption monitoring according to claim 6, characterized in that the communication takes place via wiring (21, 9) via pulse inputs for coupling energy meters with pulse output, or via a serial connection (13) for linking, for example, smart meters (14) equipped with a PI port. The system for monitoring consumption according to claim 6, characterized in that the wireless communication of the server runs simultaneously via wifi (3) with the local network to connect to local tablets and PCs (4), and via radio waves 868 MHz (5) to connect to socket plugs (6), socket thermostats (7a), battery measuring modules (7b, 7c) or other components of the system (1) for monitoring consumption. The consumption monitoring system according to claim 1, characterized in that each measuring module (6,7a, 7b, 7c, 10, 11, 12, 14, 15, 17, 18, connected to the local Web server (2), 19, 20) for measuring consumption is provided with a unique serial number (26), which is also printed on each measuring module, and with which the local Web server (2) can independently recognize and set all necessary settings and parameters in order to identify itself configure and enable auto configuration. The system for monitoring consumption according to claim 1, characterized in that the local Web server (2) always recognizes the signal strength (28) between the server and the WiFi network (3) on the one hand and between each measuring module (29) and the server (5) on the other hand, and can display these signal strengths graphically on web pages in order to detect communication problems in a timely manner. The system for monitoring consumption according to claim 9, characterized in that the local Web server (2) can operate in accordance with the master-slave principle as well as the everybody-master principle using the unique serial numbers (26) of the measuring modules. 12. - Consumption monitoring system according to claim 11, characterized in that, according to the everyone-master principle, the local Web server as a master via an RF broadcast one by one for each measuring module (6,7a, 7b, 7c, 15,17-) 20), each measuring module recognizing as its slave its serial number (26) and sending its measured consumption data back to the local Web server (2), which then stores the consumption data. The system for monitoring the consumption according to claim 11, characterized in that according to the all-master principle, each measuring module (17,18,19,20) can itself check whether the communication bus (16) is free and subsequently its current modified can transmit measured values as master to the local Web server (2) in response to a status change in the measured values, whereby the local Web server (2) can recognize the transmitting measuring module by its serial number (26), and then as slave the modified data in real time can be visible on the web pages (24.30). The system for monitoring consumption according to claim 10, characterized in that the local Web server (2) shows in real time both the signal strength (28) between the local Web server and the Wi-Fi router, and the signal strength (29) between the local Web server (2) and each individual wireless measurement module (6, 7a, 7b, 7c, 15, 1720), and these signal strengths can be used to optimize the positioning of the local Web server (2) and measurement modules (6,7a, 7b, 7c, 15.17-20). The system for monitoring the consumption according to claim 14, characterized in that with each data recording by the local Web server (2) the firmware version (27) of each individual RF module is also sent, after which the firmware versions (once every 24 hours) ( 27) of the measurement modules and of the local Web server itself are compared with the online versions, so that if necessary these firmware versions are automatically or manually updated via a wireless route. Consumption monitoring system according to claim 1, characterized in that the local Web server (2) is used both for configuring the system such as setting up a Wi-Fi network (3), adding measurement modules (6, 7a) , 7b, 7c, 10, 11, 12, 14, 15, 17-20), input of energy prices, time switches, as for the local storage of all measurement data, as for the operation of consumers and the visualization of measurement data (24.30 ) being energy consumption, measurements, energy costs, graphs with a history of energy consumption (42.44), real-time measured EPC number, and of energy costs or other measurement data, all without requiring internet, external software, apps or cloud applications, so that the application appears platform-independently on the web pages, and is generated in real time in the local Web server itself.