WO2003093916A2 - Power regulation and management system - Google Patents

Abstract

The invention relates to a regulation and management system for variable-watt power consumption devices. More specifically, the invention relates to a programmable, analytical regulation and management system for variable-watt power consumption devices, comprising a built-in microcontroller with adaptive proportional-integral-derivative (PID) operation which is linked to at least one temperature datum, e.g. as with an electric radiator. Moreover, said devices can remotely receive simple information via a transmitting home automation centre. The system consists of: an electronic board (R1) comprising a programmable, analytical microcontroller (1) which performs the adaptive PID functions regardless of the functions requested, e.g. freeze prevention, power saving; and a receiving interface (4), e.g. a radio, which is non-transmitting and which, if necessary, can receive simple function information from a home automation centre: e.g. time intervals, start, stop.

Description

 The present invention relates to a regulation and management system for energy-consuming devices that can accept a variable, programmable and analytical watt power integrating a microcontroller operating in Proportional Integral Derivative Adaptive, linked to at least one temperature datum, as for a electric radiator, for example, and which can receive simple information remotely via a home automation station.

To our knowledge, and, to date, no digital processing in radio frequencies or carrier current, as well as regulation in Proportional Integral Derivative Adaptive "P.I.D.A", managed by microcontroller, are known to us.

In fact, very simple systems are available for these uses and, for certain, by carrier current, or infrared, or high frequency radio, but using only receivers by triac or dry "all or nothing" relays.

The system according to the invention makes it possible to make up for this failure. It includes:

According to a first characteristic, taking, as a non-limiting example, the management of electric heating with heat-transfer fluid, whether it is water or a heat-transfer fluid or a solid heating body, a programmable and analytical receiver incorporating a microcontroller is assigned to each device, the main control functions of which are presented on a control keyboard attached directly to the printed circuit or remote on an external keyboard, glued to a casing for example, makes it possible to transmit information to the microcontroller of the receiver and to view it instantly thanks to a "seven-segment" display and visual confirmation lights or, for example, on a digital dial.

In a first function, it can accept all simple and already known orders, received on a radio receiving interface or carrier current, for example, transmitted by a home automation station only transmitting, in "automatic mode" operation,

A second function, transmitted to the microcontroller by a "NON AUTO" push button, makes the device autonomous. In this function each regulation is independent and does not receive any order from the home automation center since it performs its own functions, apart from the time bands, but requiring manual intervention by the user, on all the devices installed initialized in this configuration

A third function makes it possible to display on the display "seven segments", or a digital screen for example, a set temperature established by pressing a push-button "+" or a push-button "-" from degree to degree. This information is transmitted to the microcontroller which manages it according to the readings a calibrated outdoor temperature sensor that senses the ambient temperature of the volume to be heated; where inside a hot water production tank for example, non-limiting example of use.

A fourth function, transmitted by the microcontroller which after analysis, acts on a "bargraph" of six different colored lamps for example, lighting progressively according to the energy consumed, or on a digital screen for example. Whatever the requested function, "comfort" or "frost-free" or "economical, the microcontroller analyzes the equation: temperature recorded by the user, temperature of the external volume transmitted by at least one probe, temperature of the heating body by at minus a probe and its temporal calorific evolution or of fluids, to instantly calculate the adequate power transmitted to the triac by "PIDA" Proportional Integral Derivative Adaptive. The "bargraph", allows to easily visualize the output of the device.

A fifth function, transmitted to the microcontroller by a push button makes it possible to give an order of three choices, for example, called "economic" which, with each press down the temperature initialized in first function "automatic mode" or in second function, manual mode "NON AUTO" of -1 ° C, -2 ° C or -4 ° C, for example, illuminating for each of these temperatures an assigned visual control light. This function can be immediately canceled by the "COMFORT" function, which gives priority to the first or second function, according to the mode determined by the user.

A sixth function, transmitted to the microcontroller by a push button, makes it possible to give the order to put the device in a so-called "frost-free" situation programmable by the user from + 5 ° to + 10 ° C, for example, by pressing a push button and confirmed by an indicator light showing the given order, this temperature selected by the user in a range of + 5 ° C to + 10 ° C is displayed on the "seven segments". This temperature value selection "Frost-free" is done by successive pressing of the push buttons "-" to go down or "+" to go up this temperature. This function can be immediately canceled by function eight, below, called "COMFORT MODE" which gives priority to the first or second function.

A seventh function, transmitted to the microcontroller by a light sensor makes it possible to give the order to decrease the light intensity or to switch off all the illuminated visual control information, "seven segment" display and visual control light, when the the device is at night, so as not to harm people, if one or more devices are installed in a room for example, This function is independent and autonomous.

An eighth function, transmitted to the microcontroller by a button push button called "Comfort" allows to give the order to the microcontroller to restore all priority to the first function called "Automatic mode", or second "non-auto mode" and cancels all the other functions initialized manually.

A ninth function: thanks to at least one temperature sensor located in the ambient air of a heating body or integrated into it, transmits the information to the microcontroller which after analysis can give the order to cut the power supply device if it detects an abnormal overheating previously initialized, and gives the order to return to service as soon as the temperature has dropped below the safety tolerance standards initialized.

A tenth function, thanks to at least one other temperature sensor located in the ambient air close to the device in question, makes it possible to detect an abnormal and rapid drop or increase in temperature, transmits the information to the microcontroller which after analysis can trigger an audible signal to warn the user that a window has been left open in extreme cold with a radiator, for example, that a window has been opened in extreme heat with an air conditioner, for example, or, for example, that a fire broke out in the environment close to the device in question.

An eleventh function, taking a constant pressure of at least a few seconds, for example; pressing the "-" button puts the device on standby.

A twelfth function, taking a constant pressure of at least a few seconds, for example; on the push button "+" allows the commissioning of the device.

A thirteenth function, by holding a constant pressure on the "non auto" button, for example, after changing the temperature displayed on the "seven segment" using the "+ or -" buttons allows to adjust and to calibrate the setpoint temperature displayed on the seven segments as a function of the actual temperature measured by the ambient temperature sensor so that the receiver takes this information into account when calculating the "PIDA" equation.

And according to a second characteristic: a "central home automation" box, only transmitting and whose functions are known and not essential to the operation of the regulation and management system relating to the patent, with its external control keyboard, integrating a digital electronic card allows control by standard radio frequencies or by carrier current for example and ensures programming in one place of several receivers located in several zones; whose essential functions can be: * Ensure the recognition of each device equipped with a programmable and analytical receiver regulation and management system incorporating a microcontroller, and codify it definitively, or not, according to its assignment in a defined area or according to a particular assignment. By receiver is meant the entire regulation system integrating a radio receiver module or a carrier current interface module managed by a digital microcontroller. Each device, equipped with its programmable and analytical receiver incorporating a microcontroller, in an automatic function is programmed to perform the functions of the orders given: the multis programmed time slots, without limitation of number, from minutes to minutes, for example; the "COMFORT"instructions;"ECO" (energy saving) or "FROST FREE", recommended by the client according to the desired energy consumption or the desired temperature.

* Load shedding of devices according to instructions and priority orders, in order to avoid peak power consumption due to the start-up of all devices at the same time, with, and, for example, delayed start orders ; The orders transmitted by the central unit have priority in the event of a change of orders given to one or more receivers when these operate in automatic mode under temporary manual orders. The program (s) memorized in the control panel take over priority when switching to the next time slot modifying the temperature or a particular setpoint in one or more zones. This load shedding function is very much reduced and very often canceled out by the fact that the P.I.D.A. (independent of the home automation system) allows equipped devices to operate only very rarely at full power.

* Ensure "frost protection" by a push button on the keyboard giving the order to each receiver to respect a minimum temperature of 5 ° C manually adjustable in addition to 10 ° C for example, in their respective areas.

* Ensure an economic mode "ECO" by a push button on the keyboard giving the order to each receiver to respect a lower temperature of "minus 1 ° C"; "minus 2 ° C"; or "minus 4 ° C" for example, compared to the initial temperatures programmed in each zone and for each device while respecting the time bands and without preprogramming the latter.

* A push button called "COMFORT" allows you to instantly cancel the recorded modes: frost-free and economical, and to return to the initial instructions memorized originally by the user. In an optional framework, the start of these functions can be triggered by a telephone order to this central.

Fig / l, is a diagram of a regulation and management system programmable and analytical (RI for example), integrating a microcontroller (1) which allows a triac (2) to act in Proportional Integrated Derivative Apdaptative "PIDA", and can follow the orders which it receives from a central (3 ) by an interface (4) in digital radio or carrier current for example. Each receiver can operate alone, without receiving an order from the central unit (3), in an "NON AUTO" option with the basic orders detailed below.

For reasons of understanding, the transparent reserves on the front (7), to let the light from the indicator lights, the "seven segments" and light sensor, designated below, bear the same numbers for correspondence.

1. A "NON AUTO" function order confirmed by an indicator light (5), when a push button (6) integrated on the front panel (7) connected by a braid (8) is pressed makes the receiver. The setting of the setpoint temperature designated by the user as the "COMFORT" temperature is obtained by successive pressing of push buttons: "+" (9) to obtain a higher setpoint temperature and "-" (10) to obtain a lower set temperature. It will be retained by the microcontroller (1) that the value of the last set temperature displayed on a "seven-segment" display (11). In all configurations, the "seven-segment" display (11) will display the set temperatures only temporarily and only with manual intervention by the user on the receiver keyboard.

2. A "COMFORT" function order makes it possible to give priority to the microcontroller (1) the total management of the receiver (RI) following the setting in temperature "COMFORT" ordered by the user. This "COMFORT" function also makes it possible, by pressing this said push button (12), to cancel all the other "FROST FREE" or "ECO" orders.

3. A bar of six indicator lights (13,14,15,16,17 and 18) visible through the front (7), not limiting in number but of reasonable quantity, visualize the consumption of energy absorbed by the heating cartridge of the device equipped with the receiver (RI), for example. A range of different colors can better visualize this consumption knowing that each of the indicators corresponds to a percentage of the power of the device. When the first indicator light comes on, it can represent, for example, 16.5% of said total energy consumption; when the first two indicator lights come on, they can represent, for example, 33% of said energy consumption; etc. up to 100%. Different values can be given to each indicator when the equation is calculated by the microcontroller (1). These indicator lights (13,14,15,16,17 and 18) light up to display said consumption at all times at%. This permanent visualization confirms the effectiveness of "PIDA".

4. A light sensor (19) managed by the microcontroller makes it possible to lower the light intensity of all the indicators until the complete extinction, when the receiver is in the dark, at night for example. This function is valid for all indicator lights for visual order confirmation. The "seven-segment" display (11), managed by the microcontroller (1), turns off automatically after a few seconds after the last manipulation.

5. An economic order "" ECO "" ~ 1 ° C "(20);" -2 ° C "(21) or" -4 ° C "(22) can be given to the receiver, immediately by pressing an "ECO" push button (23), integrated on the front panel (7), once, twice, or three times, depending on the setpoint desired by the user. Each press on this push button (23) will select a data item energy saving desired, lighting one of the visual confirmation lights (20); (21) or (22) corresponding to the choice In this configuration the "COMFORT" temperature initialized and ordered to the microcontroller will be instantly reduced by the value d economy selected. This order will be instantly canceled only by a new manual intervention of pressure on the "COMFORT" push button (12) integrated on the front panel (7) which will give priority to the set temperature initialized at the origin and displayed. on the "seven-segment" display (11) .The screw confirmation light uelle confirming the corresponding "ECO" mode goes out.

6. An order known as ^Λ FROST FREE ', represented by a snow star, for example, which is a known simple understanding, preceded by "+ 5 ° C" (24) can be given to the microcontroller (1) by pressing on a corresponding push button (25) integrated on the front panel (7) and displayed by an indicator light (26). This order will be canceled instantly only by a new manual intervention of pressure on a "COMFORT" push button (12) integrated on the front panel (7) which orders the microcontroller (1) to return to the set temperature initially initialized as a priority.The visual confirmation light (26) confirming the "FREEZE" mode goes out.

7. A temperature sensor (27) tared to a determined value, installed on the electronic card (RI) taking into account the immediate temperature or in contact with the heating body, outside or inside, makes it possible to request the microcontroller (1) cut off the electrical supply to the appliance if the latter detects an abnormal temperature which may exceed its value determined in safety instruction.

8. A temperature probe (28) placed outside the electronic card (RI) allows the microcontroller (1) to analyze the temperature of the ambient air in parallel with the temperature measured by a temperature sensor. temperature (27) in a second function thereof, so that it can perform the PIDA function of a triac (2) in order to allow the energy consumption of the device to be controlled as closely as possible.

8. The above-mentioned functions can be managed without the assistance of the control unit (3). However, if, even without the control unit (3), an "AUTO" (automatic) command was given manually by means of a push button (29), to the microcontroller (1) confirmed by an indicator light (30) , the programmed data initialized in "NON AUTO" mode will be executed. The microcontroller (1) of the receiver (RI) not receiving an order from the control panel (3), because it does not exist or has broken down, will go on its own after a few seconds in "NON AUTO" order (not automatic therefore manual) and will continue to operate normally. In this configuration, a visual confirmation light (5) will flash to wait for manual confirmation of the requested order. The user will press a "NON AUTO" push button (6), integrated on the front panel (7), to confirm this order to the microcontroller, and the indicator light (5) for visual confirmation will then remain permanently on to confirm that I the order has been successfully saved.

To execute orders in "AUTO" function (automatic) each receiver must be recognized by the central unit and these orders are given by pressing a "AUTO" push button (29), integrated on the front panel (7), and confirmed by the indicator light (30). In this configuration, each receiver will permanently receive orders in radio frequencies, for example, so that each microcontroller of each receiver obeys permanently and instantly to the central unit to execute the orders initiated in programming by the user.

And according to Fig: 2 is a block diagram of a system according to the invention having a home automation center (3) which transmits by radio frequencies, for example, which sends simple and known commands in transmission only, to a "ZONE 1 "and to a" ZONE 2 ", for example and not limiting in number but in reasonable quantity, and each being equipped with one or more receivers (RI to R8) and (Rai to Ra8), for example and not limiting in number but in reasonable quantities, fitted with inertial radiators, for example, (31, 32, 33, 34, 35, 36, 37, 38) and (39, 40, 41, 42, 43, 44, 45, 46).

The programmable home automation center (3) mentioned above in Fig: 2 has:

- A display screen (47) makes it possible to visualize, by image, clearly, the information programmed by the user: set temperatures (48); zone designation or numbering, for example: room No. l (49); Room N ° 2 (50); Room N ° 3 (51); kitchen N ° 4 (52); time slots (53), for example, defined below. Access to this display is by pressing a "MENU" push button (54) and scrolling through the zones to be initialized or to which a correction must be made is made by push buttons (55) for mounting and (56 ) to go down.

- An electronic control card (not shown) by radio frequencies or by carrier current, for example, provides, thanks to an antenna (57), programming of the management, in one place, of several receivers (RI to Ra8) equipped each of an interface (4) for the RI regulation system, for example, located in zones 1 and 2, the essential functions of which are:

* Send codes to one or more devices equipped with the regulation system which will recognize them only if they are given the order manually and individually on each regulation system, definitively or not, according to its assignment in one or zones defined or according to one or more specific assignments. This order acceptance can be done by pressing at least one push button, "comfort" (12) for example, for several seconds on the front panel (7) of the regulation system. Several devices can accept the same code if they have to work in the same area, for example.

The home automation center (3) therefore displays on a liquid crystal display, for example (58), the zone in which the receiver will be considered after confirmation obtained by pressing a programming "P" push button (59). This operation is repeated for each regulation system to be recognized, and the home automation center (3), in its initiation configurations, can transmit its orders individually or in groups, to each regulation system in the areas assigned to them: the time bands established by the user as well as the set temperature to be observed in this period by each radiator equipped with its regulation system. This information is displayed by images, texts and logos on a display screen (58) and the scrolling can be adjusted by successive presses on a push button "+" (60) to increase the displayed figure, or by a push button " - "(61). These data are confirmed by pressing a program push button" P "(59).

- These main programmed data become so-called "COMFORT" data and become a priority for the home automation system (3). That is to say, if other data are entered without being confirmed in the initial program, the home automation central unit (3) will automatically and automatically return to the so-called "COMFORT" data when passing a next phase scheduled time.

- Orders, said "ECONOMIC"" ^tt -ι <>c";"-2 ° C";"-4 ° C"", displayed on a liquid crystal display for example, (58) can be given to all of the receivers, immediately by pressing a "ECO" push button (62), for example, according to the setpoint desired by the user. Each press of a push button (62) will select a desired economic data item which will be confirmed by a visual reading on a liquid crystal display screen (58) for example, corresponding to this choice. In this configuration, all the individual setpoint temperatures "COMFORT" of each regulation system will be instantly reduced by the selected value "" -ι ° c ";" -2 ° C ";" -4 ° C "". This economical "ECO" instruction will be permanently maintained, regardless of the time slots scrolling. This order will only be canceled by a manual intervention of pressure on a "COMFORT" push button (63) which will instruct the microcontroller, not shown, of the home automation central unit (3) to take over all of the programmed initialized management priorities and to no longer take this "ECO" concept into account. In this configuration, a corresponding visual icon goes out on the display.

- An order known as "FROST FREE", represented by a snow star, for example, which is a known simple understanding, and of "+ 5 ° C" (64) can be given to the microcontroller by pressing on a corresponding push button ( 65) and displayed by an icon in the liquid crystal display. All receivers will adjust the radiators they equip to a temperature selected by the user in a range, for example, from "+ 5 ° C to + 10 ° C". This temperature value selection is made by successive presses on a push button "-" (61) to go to "+ 5 ° C" and on a push button "+" (60) to go to "+ 10 ° VS". The control unit will take into account the remaining value displayed last. This order will only be canceled by a manual intervention of pressure on a "COMFORT" push button (35) which will instruct the central unit microcontroller (1) to take over all of the initialized management priorities programmed and to no longer take this notion into account. of the "FREEZE" function. In this configuration, the corresponding icon displayed in the display goes out.

The user has the possibility, in a less instinctive programming system and for criteria related to his installation or his needs, to program, only for devices equipped with a regulation system, priority zones (1) for his comfort, for example, or to offload non-priority areas (2), for example, in order to want to make voluntary additional energy savings or technical criteria related to the available power of the installed meter. The user can, knowing the available power of his installed meter and the power of his devices, equipped with an analytical regulation unit paired in each zone, access the writing of his particular program. This program being validated 1O

in the microcontroller of the home automation system (3), it will now manage all the primary programs for time bands and temperature in each zone, with the priority setting, to delay the start of the devices in one or more zones, for example , and whose start times are identical with changes in temperature increase. This information will be managed automatically by the microcontroller from the writing of the primary programs, as well as all the load shedding information, in the best interest programmed by the user.

All orders from the home automation system (3) are transmitted to each regulation system in the zones allocated to them by radio frequencies, or by carrier current, for example.

It will be understood that the present invention is in no way limited to uses exclusively linked to electric, fluid or solid heating, air conditioning for example or any other existing apparatus requiring the management of a source of electrical energy, such as: a balloon electric hot water, or a heated floor, for example.

Furthermore, the present invention relates to a regulation and management system for energy-consuming devices that can accept a variable, programmable and analytical watt power integrating a microcontroller operating in proportional integral adaptive derivative, linked to at least one temperature datum, such as for an electric radiator for example, and which can remotely receive, via a transmitting home automation system, simple information.

Claims

1- Regulation and management system, for energy consuming devices which can accept a variable watt power linked to at least one temperature datum, as for an electric radiator for example, and which can receive remotely, via a home automation center, simple information, characterized by the fact that it:

- Integrates all the functions allowing it to work alone, autonomously, to manage the energy consumption in "Proportional Integral Derivative Adaptive" (P.I.D.A.) of the device on which it is installed.

- Can integrate a receiving interface (30bis), radio for example, non-transmitting, in order to be able, if necessary, to receive simple information, from a home automation center: time slots; market ; stop etc.

- Can integrate an individual recognition function by accepting a code, only for reception, allowing it to take orders issued from a home automation system using standard digital radio or carrier current.

- Incorporates simple functions such as: Walking; Stop.

- Incorporates a function for canceling the specific functions requested, such as Frost Protection or Economy for example, by pressing the COMFORT key (59) in order to return to the requested set temperature.

- Integrates the setpoint rise and fall functions by two keys + (42) and - (41)

- Incorporates running functions in "NON AUTO" (non automatic) (40) if the management control system must manage the device it equips alone, or "AUTO" (automatic) (65) if the management regulation and in reception link with a home automation central (1).

- Incorporates calibration and calibration functions for the set temperature, as close as possible to the actual ambient temperature of the volume to be heated, displayed on a seven segment (44), for example. This calibration and calibration function may possibly be modified at each site of use.

2- Regulation and management system, for devices consuming energy that can accept a variable watt power according to claim 1 characterized in that each receiver is equipped with a microcontroller (43) which analyzes the data transmitted by at least one probe outside temperature (64) and the temperature of the energy-consuming device as a function of the set temperature initialized on the seven segment (44) by the user, and immediately calculates the adequate power to be transmitted by the triac (38 ), to operate in "PIDA", and which takes into account at least three parameters according to the equation:

* outside volume temperature * temperature of the heating body and its temporal calorific evolution

* setpoint temperature initialized which allows it by joint analysis to predict its evolution.

3- Regulation and management system for devices consuming energy that can accept a variable watt power according to the preceding claims, characterized in that the microcontroller (43) makes it possible to manage, in PIDA, the "FREEZE" function with, by example 6 voluntary initialization selections between + 5 ° C and + 10 ° C which is displayed on a "seven segment" (44).

4- Regulation and management system, for devices consuming energy that can accept a variable watt power according to the preceding claims, characterized in that the microcontroller (43) makes it possible to manage in P.I.D.A. the "ECO" (economic) -1 ° C (56) function; -2 ° C (57) or -4 ° C (58) compared to the so-called "COMFORT" temperature depending on the temperature recorded by the user on a receiver (RI), for example, knowing that no receiver is is supposed to have the same recorded comfort temperature.

5- Regulation and management system, for devices consuming energy that can accept a variable watt power according to the preceding claims, characterized in that the indicator lights (45,46,47,48,49,50), for example of the bar graph allow to visualize, on each receiver, the energy consumption consumed in% according to the calculation of the microcontroller (43) according to the orders given by the latter to the triac (37).

6- Regulation and management system, for devices consuming energy that can accept a variable watt power according to the preceding claims, characterized in that each regulation and management system in P.I.D.A. can receive information from a standard or specific home automation management center (1) which can communicate these orders, only when transmitting, to manage the operating time slots.

7- Regulation and management system, for devices consuming energy that can accept a variable watt power according to the preceding claims characterized in that this system reduces or eliminates the load shedding function in the event of overload on the network due to the fact that apart at start-up, each equipped appliance will rarely consume its maximum energy power to maintain the requested setpoint temperature by only compensating for heat losses.