FR3009608A1 - DEVICE FOR CONTROLLING A HEATING OR AIR CONDITIONING INSTALLATION OF A LOCAL - Google Patents

Abstract

The invention relates to a device for regulating the temperature of an installation, in particular an air conditioning, reversible air-conditioning or heating, consisting of at least one convector, preferably a fan coil, and a thermostat connected to the fan-convector, further comprising an autonomous temperature probe connected to a local PLC said controller is itself connected to the fan coil and may be connected to a control system. The object of the present invention is particularly useful in a multi-room building such as a hotel. The system of the present invention proposes depending on the group of premises or schedules to change the control of the temperature of the premises controlled.

Description

The present invention relates to temperature control systems, and more particularly to air conditioning, reversible air-conditioning or heating systems and their means. control. In particular, the present invention is useful for controlling the temperature in one or more rooms of a building comprising a multitude of rooms such as a building or a hotel. BACKGROUND ART Existing air conditioning or heating systems generally consist of a fan / convector unit or convector unit alone, which is supplied by the network. They are controlled by a thermostat that can be operated by the user who determines the setpoint (cold, hot, temperature, ventilation speed etc ...). In multi-room buildings, such as a hotel where residents change frequently, these facilities need to be controlled. The temperature of the fan convectors is thus predefined and the user changes the temperature if he wishes when he takes possession of the premises or during his stay. European application EP-A-2 088 383 describes an example of a conventional installation in a hotel comprising several rooms to be air-conditioned. The installation includes one or more primary PLCs located in the rooms to be conditioned and a central controller (or master) remote. The central controller allows remote control of each of the local PLCs and thus centrally control individual fan coil units or fan coil units. Typically, this type of controlled installation (or Controlled Technical Management) is provided by the same installer (so-called proprietary solutions). Thus, the different units of the installation communicate with each other in the same proprietary language or via communication cards with a common KNX type protocol, usually using electronic communication cards. The measured temperature and other information of the thermostat are then made exclusive when they are taken up by the different units of the installation. In addition, these control systems also manage the operation of the convector itself. The installation then becomes difficult to modify and / or evolve without using communicating materials most often of the same brand. In fact, it is common for these electronic devices to fail both at the level of the central unit and local controllers. This affects the control device and it becomes impossible to maintain control of the temperature in the rooms, which are no longer connected or in the rooms in which local controllers are defective, or even to use the convector / air conditioner itself. even. On the other hand, given the complexity of electronic communication systems and the availability of proprietary solutions, it is often necessary to wait for long weeks before receiving a replacement item, to be able to carry out repairs or to have developments or programs. In this type of system, the costs and deadlines are imposed by the manufacturer and / or the installer, only likely to intervene on their proprietary solution. The same type of constraint appears with standard control devices. In addition, it appears that these centralized control systems are not satisfactory since they commonly vary the temperatures in anticipation according to the foreseeable occupancy of the premises but do not actually allow to adapt the control to the actual planning of the premises. occupation of the rooms. Thus, many additional additional temperature adjustments are necessary.

SUMMARY OF THE INVENTION The object of the present invention makes it possible to overcome the various disadvantages mentioned above. More particularly, the devices according to the invention make it possible to adequately control the temperature of a room. By proposing a potentially decentralized control system, it becomes possible to overcome the risks of a general breakdown or one of the elements of the existing control system. The residents then remain masters at home and keep their hands on the thermostat and therefore on the control system.

On the other hand, the devices according to the invention adapt in parallel to primary air conditioning / heating systems, without it being necessary to insert them into the control or regulation chain of the existing control system, nor to modify installation already in place or to generate additional work. A first aspect of the present invention relates to a temperature control device, especially an air conditioning, reversible air conditioning or heating system consisting of at least one convector, preferably a fan coil and a thermostat connected to the fan coil, comprising an autonomous temperature probe connected to a local PLC said controller itself being connected to the fan coil and may be connected to a control system. According to one embodiment of the present invention, the local controller connected to the fan coil of the redundant device is supplied with 230 volts.

According to one embodiment of the present invention, the probe has a resistance of 5 K ohms and is fixed in the thermostat of the installation, preferably using a jumper and a wireless connector. Another aspect of the present invention relates to an air conditioning, reversible air conditioning or heating system comprising an initial temperature control device and at least one device according to the invention. According to one embodiment of the present invention, one or more of the system regulating devices are connected to a parallel control system, distinct from the initial control system.

According to one embodiment of the present invention, the parallel control of one or more local controllers may be disabled using said parallel control system. According to one embodiment of the present invention, the local controllers are connected to the parallel control system over the Internet, using Ethernet connections, preferably via a central machine which is itself connected. to internet. According to one embodiment of the present invention, the devices according to the invention are controlled in parallel with the aid of a control software available on a terminal connected to the Internet.

Another aspect of the present invention relates to a method for controlling the temperature of a room or a group of rooms using a system according to the invention.

According to one embodiment of the present invention, the groups of parts correspond to the rooms facing the outside of the same building and having the same orientation. According to one embodiment of the present invention, the parallel control device has priority over the initial control device in predetermined time periods. Another aspect of the present invention relates to the use of a regulating device according to the invention on an air conditioning installation connected to a water network with 2 tubes or 4 tubes.

According to one embodiment of the present invention, the use is made on a heating / air conditioning system of a building comprising several rooms such as a hotel or a set of offices. According to another aspect of the present invention, the use of a device of the invention aims to replace a GTC type initial control system, communicating with the aid of communication cards or electromechanical means. DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic representation of a centralized air conditioning system of G.T.0 type of the prior art. FIG. 2 is a schematic representation of a device according to the invention coupled to an existing conventional controlled air conditioning system. FIG. 3 is a screenshot of a device management software of the invention in a building.

FIG.4 is a diagram showing a system according to the invention illustrating the control of a group of parts of the same building. DESCRIPTION OF EMBODIMENTS OF THE INVENTION The present invention relates to an installation for regulating the temperature of a room. It applies to any type of heating or air conditioning system using air or water as heat transfer fluid to heat or cool a room. It relates to conventional radiators heating parts by convection or radiation without the provision of a fan and with a control acting only on a solenoid valve to let the heat transfer fluid through the battery. It also relates to facilities acting on a ventilation that propels air through the battery to heat or cool a room. Typically, examples of installations compatible with the present invention are electric heaters, dual flow VMCs, cooling ceilings, heating ceilings or air conditioning. Preferably, the present invention applies to reversible air conditioning or heating air conditioning installations.

The present invention is usable for a room or group of rooms intended for the same type of operation, such as offices, meeting rooms, or intended to accommodate the same category of residents (employees, families, customers on the claim) ). Preferably, the present invention is particularly useful in hotels, where the temperature control systems are essential for the comfort of residents and very often expensive. The reversible air conditioning systems considered in the present invention, without being limited, relate to systems connected to water networks with two or four pipes. Typically a two-pipe network can convey either cold water or hot water while a four-pipe network can pass through a dual battery is water in the hot battery or the water in the cold battery of the fan coil. In the context of the present invention, the term "fan coil" refers to the element of the air conditioning or heating system capable of propelling heated or cooled air into a room to be tempered. This is a terminal element in the installation of reversible air conditioning. In the context of the present invention, the term "thermostat" refers to an element of the installation, typically an electronic or electromechanical control box allowing the user to force the creation of heat or cold in the room. Advantageously, the thermostat comprises a digital screen indicating various information such as room temperature, date, time, ventilation speed, etc. Advantageously, the thermostat allows the user to enter directly. the desired temperature in the room, using a knob or digitally. In the context of the present invention, a local controller, ie which is located in the room to be tempered, is added to an existing control system. It is added in place of the initial control system of the installation. It means "initial", the control system initially adapted to the installation. Typically, the initial control system is of the Centralized Technical Management type and consists of elements communicating with each other through communication cards of proprietary systems, that is to say communicating in a language that is specific to the manufacturer of installation. Most GTCs that are installed simply impose a temperature in a room. Some more complex multiply sensors, for example at the windows to cut air conditioning when a room is open. This type of primary system therefore increases the risk of breakdown or malfunction. They are very difficult to manage on a daily basis. According to the present invention, the local PLC is connected to an autonomous probe, that is to say separate from the probe included in the thermostat of the temperature control system to provide reliable information to the local controller. Suitable probes are those generally known to those skilled in the art and conventionally used in the field. Typically, the probe can be attached to the location of the existing thermostat or in it to minimize installation work. The probe can advantageously be attached to the existing thermostat using a jumper and a two-wire connector. In order to limit further work, the wire used to connect the autonomous probe to the local controller can also be housed in the sheath or cable of the thermostat initially installed for the initial control installation. The local controller / probe assembly constitutes a redundant control device, that is to say which is installed in parallel with a first control device. The term implies that the two devices are installed in parallel and can work alternately with each other. FIGS. 1 and 2 schematize a device according to the prior art and a device according to the present invention in which it is observed that the local automaton and the probe are arranged and connected in parallel with the existing system. In case of failure, the present invention corresponds to a robust, simple and economically advantageous system that overcomes the failure and continue to cool or heat the room despite the failure of the primary control system. This becomes particularly advantageous in buildings such as hotels where it is expensive to not be able to use a poorly tempered room and causes complaints from customers. Typically, the devices according to the invention can reduce from 70 to 80% the maintenance costs of a conventional controlled installation. It is also more economical to install with a cost reduction of around 20 to 30% compared to a conventional controlled installation.

The local PLC is likely to be connected to a control system parallel to the first system, which may possibly be deposited during the installation of the devices of the invention. Advantageously, several automata and therefore devices can be connected or grouped on relays which are themselves connected to the control system. Using this second control system, the PLC can be activated or deactivated remotely to take control or on the contrary allow the resident to control the temperature locally. It is also conceivable to allow the local controller to disable the redundant control system manually, for example using a mechanical mechanism. Advantageously, the redundant control system is managed from a server controller. The server PLC is then connected to the Internet and sends instructions via the network, away from the local PLCs. The server PLC is available from any "administrator" terminal connected to the internet, for example by means of a secure connection. In this way, the manager or the technicians of a building or a hotel can control the system via their mobile phone with complete freedom of movement. This management system makes it possible to override, if necessary, the primary regulation system of an installation while keeping control of the remote devices. As part of a hotel, an example of a terminal may be the reception computer, where the room information is usually centralized. Typically, a management software is installed on a remote server, that is to say located outside the walls of the building. The user accesses it via a terminal connected to the internet, for example using a secure interface to control the various connected devices. The management software can also be available via a web interface. Thus, the various updates and interventions on the control software can be done remotely and in one go without the need to move to each of the sites using the system, as is currently the case for existing solutions. An example of a software interface is given in FIG. 3. Home automation systems that can be used via the Internet, in particular via Wi-Fi or the telephone network, are known as such and are applied in the present invention to the air-conditioning system. especially a building or a hotel.

It then becomes possible to control each device individually, and thus to control each room of a building. It is also possible to control a whole group of rooms at a time, for example those which in the same building are exterior and have the same orientation. It is indeed useful to be able to act on all the parts that face the same conditions of sunshine, cold etc ... Advantageously, it is also possible to force the redundant control system in predefined time slots , especially to harmonize temperatures and optimize energy gain.

Typically, the following time slots can be envisaged with the object of the present invention. These correspond to the time slots in which guests are physically present in the rooms. Time Range Risk of Complaint Proposed Mode of Control Energy Savings 9:00 am - 6:00 pm Nearly No Control High 18:00 - 21:00 Important Local Low 21:00 - 06:00 Low Intermediate Medium 6:00 - 9:00 Important Local Low Figure 4 shows an example of systems according to the invention, wherein the local machine of each of the parts of the same group of parts located on the same facade, are interconnected to an ethernet / internet connection. The other parts of the building are not shown in the figure. The management software installed on a remote server is then accessible via a terminal of the building, such as the computer of the reception.

Claims (14)

REVENDICATIONS1. Device for regulating the temperature of an installation, especially an air-conditioning, reversible air-conditioning or heating, consisting of at least one convector, preferably a fan coil, and a thermostat connected to the fan coil, comprising in addition, a self-contained temperature probe connected to a local PLC, said PLC being itself connected to the fan-coil and capable of being connected to a control system. 2. Device according to claim 1, wherein the local PLC connected to the convector is powered by 230 volts. 3. Device according to one of claims 1 to 2, wherein the probe has a resistance of 5 K ohms and is fixed in the thermostat of the installation, preferably using a jumper and a connector wireless. 4. Air conditioning, reversible air conditioning or heating system comprising an initial temperature control device and at least one device defined according to one of claims 1 to 3. 5. System according to claim 4, wherein one or more of the regulating devices are connected to a parallel control system, distinct from the initial control system. The system of claim 5 wherein the parallel control of one or more of the local controllers can be disabled using the same parallel control system, leaving room temperature control to the single thermostat. 7. System according to one of claims 4 to 6, wherein the local controllers are connected to the parallel control system over the Internet, using Ethernet connections to a server machine which is itself connected to the internet. . 8. System according to one of claims 5 to 7, wherein the devices defined according to one of claims 1 to 4 are controlled with the help of software installed on the server machine and accessible by a user terminal connected to Internet. 9. A method for controlling the temperature of a room or a group of rooms using a system defined according to one of claims 4 to 8. 10. Temperature control method according to claim 9, wherein the groups of parts correspond to the rooms facing the outside of the same building and having the same orientation. 11. Temperature control method according to one of claims 9 to 10, wherein the device is controlled alternately using the parallel control system and the local thermostat according to predetermined time periods. 12. Use of a control device defined according to one of claims 1 to 3, on an air conditioning installation connected to a water system with 2 tubes or 4 tubes. 13. Use of a control device defined according to one of claims 1 to 3, on a heating / air conditioning system of a building comprising several rooms such as a hotel or a set of offices. 14. Use of a device defined according to one of claims 1 to 3, replacing an initial control system type GTC, communicating with communication cards or electromechanical means.