FR2901046A1 - External store controlling device for e.g. professional building, has wind force recognizing unit whose interrogation unit interrogates remote server via Wireless Fidelity or Bluetooth interface to obtain wind force - Google Patents

Abstract

The device has a Wireless Fidelity or Bluetooth interface connected to a communication network i.e. Internet. A wind force recognizing unit has an interrogation unit for interrogating a remote server via the interface to obtain wind force. The interrogation unit has a sending unit for sending a request requiring the wind force to the remote server, and a receiving unit with a wind force indicator for receiving a response. An independent claim is also included for a method for protecting a solar occultation external device against wind.

Description

Technical area

  The invention relates to home automation control devices and more particularly the control devices of external blinds and the means with which they are equipped to ensure the protection of the awning in the event of a gust of wind.

Prior art

  Exterior blinds are generally used to conceal the openings of a building or to shade an outdoor area such as a terrace. These blinds can consist of webs, panels or slats that can be deployed in such a way that they offer an obstacle to the sun's rays. They are usually equipped with a mechanism to retract and deploy them. They can, for example in the case of a canvas, wrap around an axis in a chest. An example of such a blind is shown in FIG. 1. We see a blind 1.1 consists of a canvas 1 3 which wraps around an axis 1.5 in the chest 1.10. The fabric is stretched between the axis 1.5 and a tension bar 1.4 while two folding arms 1.2 maintain the tension bar 1.4.

  Such blinds generally offer a significant wind grip. As a result, they may be damaged when the wind is strong. It is therefore important to equip them with a protection system that allows them to be folded over a certain wind force. If the awning is manually operated, the user of the awning must think to fold it when the wind forces. It is common nowadays to motorize the blinds.

  In this case a 1.6 engine makes it possible to mechanize the folding process of the blind 1.1. The engine 1.6 drives the axis 1.5 in rotation allowing folding and deployment of the blind. This motor can be controlled by control means 1.7. These control means can be manual, they are in this case consist essentially of a switch. But it is also possible to control these control means by a control device 1.8. This control device can, for example, send deployment or folding commands via a radio protocol or via electrical wiring.

  To ensure the protection of the blind, it is then possible to add to the control system an anemometer attached to the outside of the home and to collect an indication of wind strength. This indication is used by the control system to send a blind folding command when the wind force exceeds a previously set threshold. This ensures that the awning will never be exposed to significant wind forces that could damage it.

  This way of doing so requires the installation of an anemometer outside the building and means of communication between it and the control system.

Presentation of the invention

  The invention aims to provide blinds with a protective device against gales without the need to install an anemometer. To do this, the control system is provided with means for interrogating remote servers with wind force information. It is possible to use for this purpose, for example, the Internet network now available in an increasing number of buildings. The servers may consist of weather servers already available on the Internet or servers dedicated to this feature.

  In this way it is possible to dispense with the installation of an anemometer, and thus simplify the system installed in the building. The reliability of the device is also improved by the removal of a mechanical device likely malfunctions.

  The invention relates to a control system for an external solar occultation device that is susceptible to damage due to a wind of excessive force, said system being provided with a protection function of the device against the wind comprising means of knowing the force of the wind and means for controlling the folding of the device when this wind force exceeds a parameterized threshold and means of connection to a communication network. The means for knowing the strength of the hold include means for interrogating a remote server, via the connection means, in order to obtain this wind force.

  According to a particular embodiment of the invention, the connection means comprise a bluetooth link with a device itself connected to the communication network. According to one particular embodiment of the invention, the connection means comprise a wi-fi link with a device itself connected to the communication network.

  According to a particular embodiment of the invention, the system further comprises means of knowing its geographical location.

  According to a particular embodiment of the invention, the means of knowing the geographical location consist of a parameter entered during a system configuration phase. According to one particular embodiment of the invention, the means of knowing the geographical location consist of a radio positioning receiver able to calculate this location automatically.

  According to a particular embodiment of the invention, the interrogation means comprise means for sending a request requesting the force of the wind to the remote server and means for receiving a response comprising an indication of wind force.

  According to a particular embodiment of the invention, the geographical location is included in the request to the remote server.

  According to a particular embodiment of the invention, a system identifier is included in the request to the remote server.

  The invention also relates to an external solar occultation device with a control system as described.

  The invention also relates to a wind shielding method of a solar occultation device capable of undergoing damage due to a wind of excessive force, said method being implemented by a control system of said device comprising means to control the folding of the device comprising a step of determining the force of the wind, a step of controlling the folding of the device when this wind force exceeds a parameterized threshold, said system comprising means of connection to a communication network, the step of determining the force of the wind comprises a step of interrogating a remote server, via the connection means, in order to obtain this wind force.

  According to a particular embodiment of the invention, the interrogation step of the remote server comprises a step of sending a request to the server and a step of receiving a response comprising the wind force from the server.

  According to a particular embodiment of the invention, the method further comprises a step of determining the geographical location of the device. According to a particular embodiment of the invention, the step of determining the geographical location of the device comprises reading a parameter entered during a system configuration phase. According to one particular embodiment of the invention, the step of determining the geographical location of the device is done by calculating this location by means of a radio positioning receiver. According to a particular embodiment of the invention, the geographical location is included in the request to the remote server. According to a particular embodiment of the invention, a system identifier is included in the request to the remote server. BRIEF DESCRIPTION OF THE DRAWINGS The above-mentioned and other features of the invention will become more apparent upon reading the following description of an exemplary embodiment, said description being made in connection with the accompanying drawings, among which: FIG. 1 represents a known example of a blind with its control system and protection against the wind.

  Fig. 2 represents a flowchart of an embodiment of the interrogation by the control system of a remote server. Fig. 3 represents an example of architecture of a windproof blind system according to the invention. Fig. 4 represents the software architecture of an embodiment of the control system according to the invention. Fig. 5 represents the hardware architecture of an embodiment of the control system according to the invention. Fig. 6 represents the interactions between the occultation device, the control system and the server in an exemplary embodiment of the invention.

Detailed exposition of the invention

  It is becoming increasingly common for buildings, whether individual homes or professional buildings, to be connected to a communication network such as the Internet. The idea underlying the invention is to take advantage of the presence of this communication network to implement the protection function of a solar occultation device such as an external blind. The term blind is used in a general sense where it refers to any solar occultation device. It is indeed possible, since the blind control device has connection means to the communication network to consider replacing the anemometer by interrogating a remote server available via this communication network. In this case, the control device no longer has, as in the prior art described in FIG. 1, the wind force indication provided by the anemometer. It must implement an interrogation mechanism based on a request / response system addressed to a server. This general mechanism is illustrated in FIG. 2. The control device sends a request during a step E21, in return it receives a response from the server during a step E22, this response contains an indication of the strength of the wind. It is then able to compare this indication with a threshold during step E23. If the wind force is greater than this threshold E24, it then controls the folding of the blind in a step E25 so as to ensure its protection. This mechanism will be repeated over time.

  To implement this solution, the blind control device must be connected to the communication network. This connection can take various forms. Fig. 3 represents an example of architecture of a windproof blind system according to the invention. It can be seen a control device according to the invention 3.8. This control device 3.8 allows to control blinds 3.1 to the number of three in the figure, each of these blinds can be actuated by a control device 3.7. The control device communicates with the control devices to control the deployment and folding of the blinds. This dialog uses a link 3.11 which can be a Wired link or a radio link. It is possible to use a home automation protocol such as the European Standard Installation (EIB) standardized by the International Standardization Organization (ISO). The exemplary embodiment uses the X2D protocol developed by the applicant. The home is also equipped with a local network 3.12 still called home network. This network is connected to the Internet via a 3.13 gateway which can be an ADSL (Asymmetric Digital Subscriber Line) modem, but also a cable modem or any other means of connection to the Internet. This connection makes it possible to offer multiple services to the user such as Internet Protocol (IP) telephony by plugging in a 3.18 telephone, broadcasting multimedia content by connecting a television 3.17 where still access to the Internet for a microcomputer 3.16. The home network may consist of a wired network based for example on Ethernet technology, standardized under the reference 802.3 by the IEEE (Institute of Electrical and Electronics Engineers) or a wireless network such as a Wi-network. -Fi standardized under the 802.11 reference family by the IEEE.

  The invention is based on the connection of the control device 3.8 to the home network 3.12. This connection can be done in various ways. For example, it may take the form of a Bluetooth connection to a home network device that will serve as a relay for communications between the control device and the communication network. The Bluetooth standard is a point-to-point radio communication standard in the 2.4 GHz band. In the case where the gateway has Wi-Fi wireless routing capabilities, it is possible to establish this connection over Wi-Fi. In this case the control device will be a customer of the Wi-Fi network of the home and will have , to this liter, access to the communication network. A direct Ethernet connection is also possible in the case of a cable network using this technology. Regardless of the connection mode adopted, the control device functions as a client of the home network and can access the communication network through it. A variant of the embodiment allows a direct connection to the communication network in the case where the home is not equipped with a home network. In this case, it suffices to provide the control device with a modem so that it can connect directly to the communication network. In this way, it is also possible to directly connect the control device to the remote server that also has receiving modems.

  The remote server must provide the control device with information on wind strength. To do this, the remote server can be a dedicated server that maintains a map of wind forces. It is possible for the remote server to obtain this data from servers such as meteorological servers. These are available for self-service. In this case, the function of the server is to periodically recover this data and make it available to the control devices in an agreed form. This server can be maintained by the manufacturer or distributor of control devices or by an autonomous operator. In a particular embodiment of the invention, the control device is provided with means for interrogating and analyzing the responses of the public meteorological servers. In this case, it is necessary to provide updates of these means to adapt to changes in format of these sites.

  To obtain relevant information on the wind force to which a given building is subject, it is necessary to be able to locate this building geographically. This location can be set in the control device during the installation of the system. In this case the installing installer will enter, for example, the name of the nearest town of the building. In an alternative embodiment of the invention, the control device may be provided with radio positioning means such as the GPS system (Global Positioning System in English). In this case, by analyzing radio signals transmitted by several satellites, the control device can obtain its precise positioning. In another embodiment of the invention, this information is not available for the control device, but stored by the server. This solution can be adopted when the server operator is, for example, the provider of the system.

  In this case, it stores the geographic location of its customers on the server. It is then easy to associate during a query phase, the request of a client with its geographical location so as to provide a precise indication of wind force concerning its location.

  The control device can take many forms. It must have an interface allowing control of the blinds. We have seen that this interface can be wired or wireless. It must also have a connection interface, to a communication network so as to be able to communicate with the remote server. This interface can also be wired, for example Ethernet or wireless, such as a Wi-Fi or Bluetooth interface, or be made of a modem. This device must generally be controllable by the user. It usually has a screen and controls in the form of buttons. These can be real buttons or virtual buttons arranged in the form of controls on the screen. The hardware architecture of an exemplary embodiment is shown in FIG. 5. In this example, the device takes the form of a wireless remote control 5.5 composed of an infrared interface 5.3 allowing the control of living room devices such as a television or a DVD player, a Bluetooth 5.1 radio interface allowing the connection to a device such as a personal computer or other. This interface will serve as a connection interface to the communication network in our case. Control of home automation devices such as blinds is via an X2D 5.2 radio interface. A screen 5.4 allows interactions with the user. The whole is controlled by a processor 5.6 rotating a software package housed in a memory 5.7. All these modules communicate via an internal bus 5.8.

  Fig. 4 illustrates the software architecture of this embodiment. It contains the 1IW modules of Figure 5, the Bluetooth 4.1 interface, the 4.2 radio interface, the 4.3 infrared interface, the 4.4 screen. These interfaces are controlled by a driver layer (u drivers in English) 4.5. There is a management module for the human / machine interface 4.9, an infrared control module 4.8, an X2D management module 4.7 and a TCP / IP stack (Transfer Control Protocol / Internet Protocol). 4.6 which will manage communications with the communication network via the Bluetooth interface. Module 4.10 implements the protection function. It interacts with the 4.6 module for remote server interrogation and with the X2D 4.7 module to control the folding of the blind when the wind force makes it necessary. Module 4.11 is a global control application that manages the entire remote control.

  Fig. 6, in turn, illustrates the exchanges occurring between the different devices involved in the blind protection function according to the embodiment of the invention. These devices are the blind to be protected, the control device, master of the protection function and the remote server providing the wind force data. The protection function is initiated by the control device in a step E61. During this step, the device determines the geographical position of the building. We have seen that this determination can be summarized in the reading of the information in memory in the case where this data is recorded during the configuration by the installer or consist in a reading of this data by interrogating a radio positioning module . The device then sends a Msgl request to the server to ask for the strength of the wind. This Msgl request can, for example, be made using the HTTP protocol (Hyper Text Transfer Protocol in English). This request Msg1 contains the geographic location information determined in step E61. Upon receipt of this Msgl request, the server determines the strength of the wind by consulting its map of the wind forces and the geographical location contained in the request. This is step E62. Once this wind force indication is determined, the server sends the Msg2 response containing this indication as an HTTP response to the control device. The latter then compares this received indication with a threshold value previously configured during a step E63. Depending on the result of this comparison, when the indicated wind force exceeds the threshold, the control device sends the store Msg3 message commanding him to fold to prevent damage to the blind. This message is sent using the X2D protocolè. Upon receipt of this command, the blind folds during step E64.

  We have seen that the step E61 for determining the geographical location of the building can also be conducted by the server. In this case, it has the geographical location information of each installation and the Msgl query then contains an identifier of the installation that is used by the server to find this location. To ensure good protection over time, this operation must be repeated. The frequency of this repetition depends on the exact nature of the reported wind force indication. If this indication is representative of the current force, the frequency should be high. On the other hand, if this indication is, for example, the maximum wind force expected for a given duration, for example the following 4 hours, it is sufficient to perform this protection function at a frequency lower than this duration to ensure a good protection of the equipment.

  It will be apparent to those skilled in the art that the invention is not limited to the embodiment described. In particular, it can be applied to any material sensitive to the wind and likely to be automatically positioned in a safe position.

Claims (4)

  1 / Control system (1.8, 3.8) of an external solar occultation device (1.1, 3.1) susceptible to damage due to an excessive force wind, said system being provided with a protection function (4.10) of the device against the wind comprising means for knowing the wind force and means for controlling the folding of the device when this wind force exceeds a parameterized threshold, characterized in that the system further comprises connection means (4.1 , 5.1) to a communication network and that the means for knowing the wind force comprise means for interrogating a remote server (3.15), via the connection means, in order to obtain this wind force. 2 / A control system according to claim 1 wherein the connection means comprise a bluetooth connection with a device itself connected to the communication network. 3 / A control system according to claim 1 wherein the connection means comprises a wi-fi connection with a device itself connected to the communication network. 4 / control system according to one of the preceding claims further comprising means to know its geographical location. 5 / Control system according to claim 4 wherein the means of knowing the geographical location consist of a parameter entered during a system configuration phase. 6. The control system according to claim 5, wherein the means of knowing the geographical location consist of a radio positioning receiver capable of calculating this location automatically. 7 / control system according to one of claims 1 to 6 wherein the interrogation means comprise means for sending a request (Msgl), requesting the wind force to the remote server and means for receiving a response (Msg2) comprising an indication of wind strength. 8 / control system according to claim 7 and according to one of claims 2 to 4 wherein the geographical location is included in the request to the remote server (3.15). 9 / A control system according to claim 7 wherein an identifier of the system is included in the request to the remote server (3.15). 10 / external solar occultation device with a control system according to one of claims 1 to 9. 11 / Method of protection against the wind of a solar occultation device 15 may suffer damage due to a excessive force wind, said method being implemented by a control system (1.8, 3.8) of said device comprising means for controlling the folding of the device comprising: - a step (E21, E22) for determining the wind force; a step (E25) for controlling the folding of the device when this wind force exceeds a parameterized threshold; characterized in that - said system comprising connection means (4.1, 5.1) to a communication network. the step of determining the wind force comprises an interrogation step (E21, E22) of a remote server (3.15), via the connection means (4.1, 5.1), in order to obtain this force of wind. 12 / A method according to claim 11 wherein the interrogation step of the remote server (3.15) comprises: - a step (E21) for sending a request (Msgl) to the server; A step (E22) for receiving a response (Msg2) comprising the wind force from the server. 13 / A method according to one of claims 11 to 12 further comprising a step (E61) for determining the geographical location of the device. 1014 / A method according to claim 13 wherein the step (E61) for determining the geographical location of the device comprises reading a parameter entered during a system configuration phase. 15 / A method according to claim 13 wherein the step (E61) for determining the geographical location of the device is done by calculating this location by means of a radio positioning receiver. The method of claim 12 and any one of claims 13 to 15 wherein the geographic location is included in the request to the remote server (3.15). 17. The method of claim 12, wherein a system identifier is included in the request to the remote server (3.15).