FR3086084A1 - METHOD FOR CONFIGURING A HEATING SYSTEM - Google Patents

Abstract

A method for configuring a heating installation in a building comprises a sequential presentation to a user of interrogations, an analysis of responses provided by the user to the interrogations via a user interface, the responses comprising at least one identification of a first thermal energy production equipment, a step of determining configuration parameters taking into account the analyzed responses, this determination step comprising a step of identifying a second thermal regulation device compatible with the characteristics of the first thermal energy production equipment identified and a step of updating the configuration parameters with at least one reference of the second thermal regulation device identified and a quantity by reference of the second thermal regulation device, the second regulation device n thermal referenced in the configuration parameters being able to be integrated into the installation replacing a first thermal regulation device. Figure for the abstract: Fig. 2

Description

Description

Title of the invention: METHOD FOR CONFIGURING A HEATING SYSTEM [0001] The invention relates to a method for configuring a heating system in a building, as well as a user interface intended for configuring a heating installation in a building.

Heating installations are known in a building comprising one or more equipment for producing thermal energy and at least one first thermal regulation device in the building. The first thermal regulation device comprises one or more elements for controlling the thermal energy production equipment or devices. The first thermal regulation device makes it possible to regulate the supply of energy to the installation, by controlling the equipment for producing thermal energy.

The first thermal regulation device comprises a temperature sensor, as well as a memory for a temperature setpoint. If a difference is detected between a measured temperature and the temperature setpoint, control aimed at increasing or decreasing the supply of thermal energy to the installation is carried out on the thermal energy production equipment.

The first thermal regulation device can for example be a thermostatic valve. The thermostatic valve is mounted directly on a water supply supplying one of the thermal energy production equipment, such as a radiator. The operation of such a thermostatic valve is described in particular in patent application WO 2009/024746 A2. Alternatively, the first thermal regulation device can be a thermostat, which communicates with thermal energy production equipment, such as a boiler or a heat pump. As a variant, the first thermal regulation device can be a thermostat integrated into an electric heater. The first thermal regulation devices were generally supplied with thermal energy production equipment and have basic control functionalities only linked to the thermal energy production equipment or equipment with which they are associated.

It is however advantageous to be able to optimize the temperature regulation in an installation, as much locally, that is to say at the level of one of the thermal energy production equipments, for example depending building users' lifestyle habits only globally, for example to generate energy savings. It is also advantageous to be able to remotely control such an installation. This optimization involves replacing all or part of the first thermal regulation devices. The difficulty lies for the user in determining which first control devices are to be replaced and which replacement devices are necessary to significantly improve their installation.

The present invention aims to solve the aforementioned drawbacks and to propose a method for configuring a heating installation in a building, as well as a user interface intended for the configuration of a heating installation in a building. , to facilitate the configuration of such an installation by determining and proposing how to improve the existing installation.

In this regard, the present invention aims, according to a first aspect, a method of configuring a heating installation in a building, the installation comprising:

- one or more thermal energy production equipment and

- At least a first thermal regulation device in the building, the first thermal regulation device in the building comprising at least one control element of the thermal energy production equipment (s).

According to the invention, the method comprises at least the following steps:

a) sequential presentation to a user of interrogations via a user interface, at least one interrogation comprising a request for identification of a first thermal energy production equipment,

b) analysis of responses provided by the user to the interrogations via the user interface, at least one response comprising an identification of the first equipment for producing thermal energy,

d) determining configuration parameters taking account of the analyzed responses, the determining step comprising a step of identifying a second thermal regulation device compatible with the first thermal energy production equipment identified and a step of updating configuration parameters with at least one reference of the second thermal regulation device identified and a quantity by reference of second thermal regulation device, the second thermal regulation device referenced in the configuration parameters being able to be integrated into the installation in replacement of the first thermal regulation device.

Thus, it is possible to determine the suitable replacement device or devices necessary to significantly improve the installation.

According to one embodiment, the method further comprises a step of identifying a communication device able to be integrated into the installation and intended to communicate with the second thermal regulation device referenced in the parameters configuration and / or intended to communicate with the first identified thermal energy production equipment, and in that the identification of the communication device comprises a determination of a communication device reference from among a plurality of device references compatible communications, the determined communication device reference being stored in the configuration parameters.

Thus, the installation can also be optimized by the use of a communication device compatible with the second thermal regulation device or with the first identified thermal energy production equipment, which makes it possible to put these in connection with elements outside the existing installation. The possibilities of regulating an installation provided with this communication device are thus optimized.

According to one embodiment, the step of requesting identification of the first thermal energy production equipment comprises a request to identify a main source of thermal energy.

The interrogations can likewise include a request for identification of a second thermal energy production equipment comprising the identification of a secondary thermal energy source, the secondary thermal energy source being different from the main energy source.

Thus, it is possible to take into account different sources of energy, and to optimize the regulation of the installation by taking into account the possible interactions between the main and secondary thermal energy sources and / or the complementarities. primary and secondary thermal energy sources.

Preferably, the method comprises a step of identifying at least one third equipment for producing thermal energy which is not compatible with the second thermal regulation device referenced in the configuration parameters.

Thus, it is also possible to take into account thermal energy production equipment which cannot be interfaced with the second thermal regulation device, and to envisage an optimization of the regulation of the installation by taking account of the possible interactions between the main thermal energy source and a third thermal energy source from non-compatible thermal energy production equipment and / or the complementarities of the main thermal energy source and the third source of thermal energy.

According to one embodiment, the method comprises a step of updating the configuration parameters with characteristics of the building.

Advantageously, the method comprises a step of displaying the analyzed responses at the user interface level and / or a step of displaying the results of the determination step.

According to one embodiment, the method comprises a step of calculating an energy value saved by replacing the first thermal regulation device with the second thermal regulation device referenced in the configuration parameters.

Advantageously, the method comprises a step of supplying a purchase order for the second thermal regulation device referenced in the configuration parameters.

The present invention aims, according to a second aspect, a user interface intended for a configuration of a heating installation in a building and comprising hardware and software elements for the implementation of the configuration method according to the invention.

This user interface has characteristics and advantages similar to those described above, in relation to the configuration method according to the invention.

Other features and advantages of the invention will become apparent in the description below, given with reference to the accompanying drawings, given by way of nonlimiting examples:

[Fig.l] is a schematic view illustrating a heating installation in a building comprising thermal energy production equipment and first thermal regulation devices according to the state of the art;

[Fig-2] is a schematic view illustrating a heating installation in a building comprising equipment for producing thermal energy and second thermal regulation devices, according to an embodiment of the invention; and [fig-3] is a diagram of an algorithm of a method according to the invention, of configuration of the installation illustrated in FIG. 2;

[fig-4] is a schematic view of the user interface according to an embodiment of the invention.

FIG. 1 illustrates an existing installation 1 comprising a set of thermal energy production equipment 101, 102, 103, 104. The thermal energy production equipment 101, 102, 103, 104 are located inside a building. Here and by way of nonlimiting example, the thermal energy production equipment 101, 102, 103, 104 correspond to a boiler 101, to two water radiators 102, 103 and to an electric radiator 104. In general, thermal energy production equipment is equipment that produces thermal energy from electricity 30, such as electric heaters or from a fuel 32, such as a pellet or pellet stove, a oil boiler, a gas boiler, an electric radiator, a heat pump or which diffuse thermal energy, such as for example water radiators.

The existing installation 1 also comprises at least a first thermal regulation device 111, 112, 113, 114. Here and in no way limiting, the existing installation 1 comprises three first thermal regulation devices 111, 112, 113 , 114, including a general thermostat 111, two thermostatic valves 112,

113 and an electric pilot wire thermostat. The connections of heat transfer fluids, for example water, are not shown in the drawing for reasons of simplification. A main energy source corresponds to the fuel 32 used to operate the boiler 101 for heating the heat transfer fluid, while electricity is seen as a secondary energy source which relates to the electric radiator 104.

We want to improve the existing installation 1 by integrating into it in place of at least one of the first thermal regulation devices 111, 112, 113,

114 at least one second thermal regulation device 121, 122, 123, so as to allow thermal regulation of an optimized installation 100, illustrated in FIG. 2. In this example, each first regulation device has been replaced by a second thermal regulation device, but it is also possible to replace only a part of it. The second thermal regulation devices are new generation devices compared to the first devices. In particular, they have communication elements between them and more important control functions than those of the first devices.

The first or second thermal regulation devices will be called respectively first or second regulation devices thereafter, while the thermal energy production equipment will be called thermal equipment thereafter. They advantageously include a temperature sensor (not shown). A communication link 10 can be established between two second regulating devices 121, 122, 123 and / or between at least one of the second regulating devices 121, 122, 123 and at least one of the thermal devices 101, 102 , 103, 104, shown in dotted lines in FIG. 2. This communication link 10 can be wired or wireless.

We will now describe, with reference to FIG. 3, an embodiment of a method for configuring the heating installation 100 of the building, illustrated in FIG. 2.

The configuration process can thus be made available to users of the existing installation 1, so that they can assess the impact and the advantages of an improvement to the existing installation 1 on their thermal balance and on their budget. An essential criterion during this evaluation is also to ensure the compatibility of the second thermal regulation device (s) 121, 122, 123 in the existing installation 1.

The thermal equipment 101, 102, 103, 104 of the existing installation 1 and / or the first thermal regulation devices 11, 112, 113, 114 may have been installed by different installers over time and correspond to different manufacturers, different brands or references. The replacement one by one of one of the first thermal regulation devices 111, 112, 113, 114 by a second thermal regulation device with an equivalent thermal regulation function is not enough to optimize the existing installation 1.

Thermal equipment 101, 102, 103, 104 have a unique reference specific to each manufacturer and operating characteristics associated with this reference. This reference corresponds in particular to a model of thermal equipment. Similarly, each first and second thermal regulation device 111, 112, 113, 114, 121, 122, 123 has a reference and specific operating characteristics associated with this reference. A user can, from a label on thermal equipment or regulation devices, find these unique references. Alternatively, the name of the manufacturer, the brand, the date of manufacture and / or one or more other data affixed to the thermal equipment or the regulation device can make it possible to find these unique references.

According to a first embodiment of the invention, the configuration method is implemented by a user from a user interface I, in particular a man-machine interface of a personal computer connected to an Internet network . In particular, the user interface I allows access to external databases, in which are stored references and / or characteristics of thermal equipment of different brands and / or references and / or characteristics of regulation devices.

A series of interrogations is presented sequentially to the user on the user interface I. These interrogations allow a computer provided with a memory and computer resources, such as a microprocessor, and means of communication with external databases, analyze the responses provided to each of these queries and then determine configuration parameters for installation 1, so as to achieve optimal energy performance. The steps of analyzing the responses and determining the configuration parameters take place during a step C1 of the method. Although shown following the series of interrogations in FIG. 3, this step C1 can be implemented in parallel with the interrogations. This step C1 is followed by a step DI of presentation to a user at the user interface I of the results of the determination step.

Cl, in particular for the presentation of the configuration parameters determined in the previous step.

The series of interrogations can be detailed as follows.

A first question Q1 relates to the type of building concerned, in particular if it is an individual dwelling, a collective dwelling, an office building, etc.

A second interrogation Q2 relates to the number of thermal zones present in the installation 1. In particular, this can be summarized as questioning the user on the number of floors on which the installation 1 is distributed in the building. . An additional question Q2.1 could relate to the number of rooms in which the thermal equipment 101, 102, 103, 104 are distributed.

A third question Q3 relates to the main source of thermal energy in the building. This main thermal energy source can be selected from a list of thermal energy sources, presented on the user interface I. For example, this list can include: an energy source linked to a pellet or pellet stove or to a heat pump or an oil or gas boiler, a source of electrical energy, a source of photovoltaic energy.

Depending on the main thermal energy source selected, optional queries Q3.1, Q3.2 can identify a first thermal device associated with this main thermal energy source. In particular, the interrogations aim to define the type or subtype of first thermal equipment used in the installation 1. In the case of the selection of an electrical energy source, the type of thermal equipment can be, for example, an electric heating floor, one or more electric radiators, in particular with dry contact, with pilot wire or connected, or an electric boiler. Following the selection of a first thermal device, for example an electric heater, a new question Q3.3 can be asked to the user, asking him to indicate the number of first thermal devices present in the installation 1 in connection with the main source of thermal energy.

A fourth question Q4 relates to the number of first thermal regulation devices 111 of a first type, for example thermostats, having means of communication with thermal equipment 101, 102, 103, 104, in particular the number of thermostats 111 already present in the existing installation 1. In the case where this number is greater than or equal to 1, an additional query Q4.1 relates to the type of communication link used, for example by proposing a selection between wired or wireless links, in particular radio or infrared.

A fifth question Q5 aims to determine whether a communication device 131, such as a home automation system, is present in the installation 1. A home automation system is a communication device making it possible to make a link between several installations 1 and / or between the installation 1 and a control device 20 external to the installation 1, for example a smart phone (or smartphone in English), as illustrated in FIG. 2, on which a control software application is installed of installation 1.

A sixth question Q6 relates to the number of first thermal regulation devices 112, 113 of a second type, for example associated and mounted on thermal equipment 102, 103, such as thermostatic valves. These first thermal regulation devices 112, 113 of a second type notably include material elements for controlling and regulating the supply of thermal energy at an input of at least one of the thermal equipments, 102, 103 .

A seventh question Q7 relates to the existence of a secondary thermal energy source available in the installation 1. This secondary thermal energy source can supplement the main thermal energy source and itself correspond to one or several first thermal regulation devices distinct from those associated with the main thermal energy source and / or with one or more second thermal devices.

The interrogations applicable to the main thermal energy source can also be taken up in the context of the secondary thermal energy source. In particular, optional interrogations Q7.1, Q7.2 can make it possible to determine the type and, possibly, the subtype of thermal equipment associated with the secondary thermal energy source used in the installation 1, in other words d '' identify the second thermal equipment relating to the secondary thermal energy source. A supplementary question Q7.3 can also be asked to the user, asking him to indicate the number of second thermal equipment present in the installation 1 in connection with the secondary thermal energy source.

An eighth question Q8 relates to the brand of thermal equipment 101, 102, 103, 104, which correspond to the main or secondary source of thermal energy. An additional question Q8.1 relates to the reference of the thermal equipment model 101, 102, 103, 104, possibly as a function of another additional question Q8.2 relating to the type of means of communication associated with the thermal equipment. 101, 102, 103, 104.

A response step RI to R8 and R3.1 to R8.2 follows each interrogation Q1 to Q8 and Q3.1 to Q8.2, during which the user responds to the questions asked. Each response to a query can take the form of a selection from a proposed list or a numerical choice entered using a keyboard C of the user interface I.

The responses may include a validation step, in which the user validates his choice of answer or returns to a previous step. The responses provided by the user make it possible to identify the thermal equipment (s) 101, 102, 103, 104 present in the existing installation 1 and their characteristics, in particular their main operating characteristics. The responses provided by the user also make it possible to identify the first regulation device (s) 111, 112, 113, 114 present in the existing installation 1 and their characteristics, in particular their main operating characteristics.

The taking into account of the responses provided to the interrogations by the user or intermediate results, makes it possible to direct the appearance of the following different interrogations.

The order of appearance of the interrogations can be variable, in particular as a function of the intermediate results.

The method also includes a step of determining configuration parameters which notably includes updating the configuration parameters. This update can take place with each new response provided by the user or following the analysis of all the responses provided by the user. In the first case, the response to the last interrogation then makes it possible to trigger the last update of the configuration parameters. The step of determining configuration parameters also includes a presentation of the configuration parameters on the user interface.

FIG. 4 shows an example of presentation of the interrogations and analysis of responses of the corresponding steps of the method. The responses RI, R2 and R3 to the queries QI, Q2 and Q3 having been provided, these are displayed in a summary list making the inventory of the installation and / or in the form of icons.

The following query, here Q3.1, is also displayed at the top of the interface. A list of thermal equipment, in the form of icons E1 to E8 is also displayed to allow selection by the user, either by the keyboard C or by another input tool O associated with the user interface I.

The step of determining configuration parameters notably comprises a step of identifying at least one second radio or wired thermal regulation device compatible with thermal equipment 101, 102, 103, 104 present in the installation 1 , from a list of second regulation devices compatible with thermal equipment 101, 102, 103, 104 present in the installation 1. Thus, as a function of the installation 1 as described by the user through his responses to questions Q1 to Q8 and Q3.1 to Q8.2 asked, the list of second thermal regulation devices 121, 122, 123 may vary.

The configuration parameters include at least one reference of the second thermal regulation device among the second compatible thermal regulation devices 121, 122, 123 identified. This is the result of the selection of the second thermal regulation device most suitable for replacing a first regulation device, with the aim of optimizing installation 1.

The configuration parameters also include an amount by reference of the second thermal regulation device. This makes it possible to provide an overall estimate, even a costing, of all the second regulation devices necessary to optimize the installation 1.

The configuration parameters also include the reference of the communication device 131 intended to communicate with the second thermal regulation device (s) referenced in the configuration parameters and / or intended to communicate with the thermal equipment (s) 101, 102 , 103, 104 of the installation 1. In this last paragraph, the fact that the elements are intended to communicate with each other means on the one hand that they have appropriate means and communication links 10 and on the other hand also that they are compatible to communicate with each other. This communication device 131 is intended to make the link between the second thermal regulation devices 121, 122, 123 referenced and the control device 20 outside the installation 1, on which the software application for controlling the installation is installed. installation 1. This communication device 131 can be proposed at the end of the step of determining configuration parameters either because the installation 1 does not include a communication device 131, or because a communication device 131 existing in installation 1 is not compatible with the second thermal regulation devices 121, 122, 123 referenced.

As seen previously, the interrogations Q1 to Q8 and Q3.1 to Q8.2 make it possible to distinguish the main thermal energy source and the secondary thermal energy source, as well as the characteristics of the thermal equipment 101, 102, 103, 104 correspondents. The objective of the invention is to optimize the installation 1 as a whole, which is made possible by knowing the installation 1. The thermal equipment 101, 102, 103 and the first thermal regulation devices 111, 112, 113, associated with the main thermal energy source can be seen as belonging to a main sub-installation while the thermal equipment 104 and the first thermal regulation devices 114 associated with the secondary thermal energy source can be seen as belonging to a secondary sub-installation. The method makes it possible to distinguish the interference or synergies between the main and secondary sub-installations and to select one or second thermal regulation devices suitable for all of these sub-installations.

In the same way, other interrogations can be planned. They relate for example to the identification of thermal equipment not compatible with the second thermal regulation devices, so as to take into account in the step of determining configuration parameters of the possible lack of compatibility with certain thermal equipment and therefore of take into account the positive or negative influences of this thermal equipment on the optimization of the installation. The non-compatible thermal equipment can for example be an electric radiator comprising a local thermostat which cannot be replaced without also replacing the radiator. It can also be additional thermal production equipment, such as a wood stove, which does not have a regulation device. In addition, the process may include a recommendation to modify the installation to take account of this non-compatible thermal equipment.

Another question relates to the topology of the building, in particular the distribution of distinct thermal zones in the building, the taking into account of which is also important for optimizing the installation 1. In fact, each thermal zone has its own behavior, relatively independent of other thermal zones. The thermal zones can easily be differentiated by the floors of the building and / or the number of generally closed rooms in which the thermal equipment 101, 102, 103, 104 are distributed. Thus, independently of the manner in which the thermal management is carried out from of the first thermal regulation devices 111, 112, 113, 114, the method makes it possible to supply a quantity by reference of second thermal regulation devices 121, 122, 123, which will make it possible to regulate each identified thermal zone.

Another question can relate to the location of the building, for example identified by geographic coordinates or the selection of a geographic area in which the location is located. Another question may relate to the total area concerned by the installation.

Queries can also relate to other criteria, such as for example:

- a power supplied by the available energy source or sources,

- a coefficient of inertia,

- one year of manufacture of the thermal equipment of the existing installation 1,

- a date of construction of the building,

- a date and / or type of renovation work carried out on the building.

The results of the step of determining configuration parameters can include a list of references of second thermal regulation devices 121, 122, 123 and associated quantities. They may also include a cost estimate per reference unit and a total. The results can also separate from second thermal regulation devices 121, 122, 123 basic, making it possible to obtain functionalities equivalent or superior to the installation 1 according to a first criterion, from second thermal regulation devices 121, 122, 123 or communication devices 131 allowing the functionality of the installation 1 to be optimized according to a second criterion. These results can be edited in the form of an order form and serve as the basis for ordering second thermal regulation devices 121, 122, 123 and / or communication devices 131 intended to be installed in installation 1 at least. replacing the first thermal regulation devices 111, 112, 113, 114.

These results can be displayed, saved and / or transmitted to the user, for example by linking them to an address or e-mail or a user account. The link to an email address, an email address or a user account makes it easy to retrieve information during an order, for example, and to deduce regulation parameters from the optimized installation 100.

In fact, parameters for regulating the installation 100 optimized, such as for example the amount of energy savings achievable by the recommended optimization of the installation, a coefficient of temperature rise, a coefficient of learning or a regulation hysteresis can be determined on the basis of the configuration parameters. These are then directly accessible and usable by the optimized installation 100 when the second thermal regulation devices and / or a communication device, referenced and listed in the results of the determination step, are installed in the installation 1 existing.

Claims (1)

Claims [Claim 1] Method for configuring a heating installation in a building, the installation comprising: - one or more thermal energy production equipment (101, 102, 103, 104) and - at least a first thermal regulation device (111, 112, 113, 114) in the building, the first thermal regulation device in the building comprising at least one control element of the thermal energy production equipment (s), characterized in that the method comprises at least the following steps, implemented by a computer comprising means for connection to external databases: a) sequential presentation to a user of interrogations (Ql, Q2, Q3, Q4, Q5, Q7, Q8, Q3.1, Q3.2, Q3.3, Q4.1, Q7.1, Q7.2, Q7 .3, Q8.1, Q8.2) via a user interface (I), at least one interrogation comprising a request to identify a first piece of equipment for producing thermal energy (101, 102, 103 , 104), b) analysis of responses provided by the user to the interrogations via the user interface, at least one response comprising an identification of the first equipment for producing thermal energy, d) determination of configuration parameters taking into account the analyzed responses, the determining step comprising a step of identifying a second thermal regulation device (121, 122, 123) compatible with the first thermal energy production equipment identified from a list of second regulation devices compatible with the equipment thermal (101, 102, 103, 104) present in the installation (1) and a step of updating the configuration parameters with at least one reference of the second identified thermal regulation device and an amount per reference of second device of thermal regulation, the quantity of second thermal regulation devices referenced in the configuration parameters being intended to be integrated into the installation at least in replacement of the first thermal regulation device. [Claim 2] Configuration method according to claim 1, characterized in that the method further comprises a step of identifying a device communication device capable of being integrated into the installation and intended to communicate with the second thermal regulation device referenced in the configuration parameters and / or intended to communicate with the first identified thermal energy production equipment, and in that the the identification of the communication device comprises a determination of a reference of the communication device from a plurality of references of compatible communication devices, the reference of the determined communication device being stored in the configuration parameters. [Claim 3] Configuration method according to claim 1 or according to claim 2, characterized in that the step of requesting identification of the first thermal energy production equipment comprises a request to identify a main source of thermal energy. [Claim 4] Configuration method according to the preceding claim, characterized in that the interrogations comprise a request for identification of a second thermal energy production equipment comprising the identification of a secondary energy source, the thermal energy source secondary being different from the primary energy source. [Claim 5] Configuration method according to any one of the preceding claims, characterized in that the method comprises a step of identifying at least one third equipment for producing thermal energy which is not compatible with the second thermal regulation device referenced in the parameters configuration. [Claim 6] Configuration method according to any one of the preceding claims, characterized in that the method comprises a step of updating the configuration parameters with characteristics of the building. [Claim 7] Configuration method according to any one of the preceding claims, characterized in that the method comprises a step of displaying the analyzed responses in the user interface and / or a step of displaying the results of the determination step . [Claim 8] Configuration method according to any one of the preceding claims, characterized in that the method comprises a step of calculating an energy value saved by replacing the first thermal regulation device with the second thermal regulation device referenced in the configuration settings. [Claim 9] Configuration method according to any one of the preceding claims. , characterized in that the method comprises a step of supplying an order form for the second thermal regulation device referenced in the configuration parameters. [Claim 10] User interface intended for a configuration of a heating installation in a building, characterized in that the user interface comprises hardware and software elements for the implementation of the configuration method in accordance with any one of previous claims.