WO2014102221A1 - Actuator for maneuvering a movable closing, sun protection, concealing or screen element and operating method of such a maneuvering actuator - Google Patents

Abstract

The invention relates to an operating method for an actuator, in particular an autonomous actuator, for manoeuvring a movable closing, sun protection, concealing or screen element, the actuator and/or the movable element comprising a photovoltaic panel designed to recharge an electricity storage battery for powering a motor of the actuator, the operating method comprising, as the result of an order to move the movable element, a phase for determining at least one first position of the actuator and/or the movable element in which the exposure of the photovoltaic panel to the light rays makes it possible to charge the electricity storage battery.

Description

 Maneuvering actuator for a movable closing, sun protection, occultation or screen element and method of operating such a maneuvering actuator. The present invention relates to an actuator for maneuvering a movable closing element, sun protection, occultation or screen. The invention also relates to a method of operating an actuating actuator of a movable closing member, sun protection, occultation or screen, the actuator and / or the movable element comprising a photovoltaic panel for recharging an electric energy storage battery supply of an actuator motor.

In the field of home automation, it is known to use an electromechanical actuator to maneuver a mobile element closing, sun protection, occultation or screen. It is also known to provide that this actuator is autonomous. In particular, to achieve such autonomy, it is known to provide a photovoltaic panel capable of recharging an electric battery whose energy can power a drive motor included in the actuator. This panel can be installed away from the movable closing element, sunscreen, occultation or screen so that it is in a situation in which it is exposed to solar radiation. However, such a design may not be possible or desirable, particularly when the motor is moving relative to the building when powered to maneuver the movable member.

Also, it may be interesting to have the photovoltaic panel on the movable element or on the actuator to limit wiring constraints. However, there is a problem. In certain positions of the movable element or the actuator, the photovoltaic panel may not be exposed to solar radiation or be less exposed to solar radiation. In unfavorable and common cases, the movable element or the actuator is often or almost always in such a position. Accordingly, in such an arrangement, there may be a lack of reliability. Indeed, it is possible to end up in a situation in which the battery is no longer recharged and can no longer supply the motor of the actuator.

The object of the invention is to provide an actuator remedying the disadvantages mentioned and improving the known actuators of the prior art. In particular, the invention proposes an autonomous actuator of simple and reliable structure. The invention also relates to a method of operating such an actuator. The invention finally relates to a home automation system comprising such an actuator. According to the invention, the method governs the operation of an actuator, in particular a stand-alone actuator, for maneuvering a mobile closure, sun protection, occultation or screen element. The actuator and / or the movable element comprises a photovoltaic panel for recharging an electric energy storage battery supplying an actuator motor. The method comprises, as a consequence of an order of movement of the movable element, a determination phase of at least a first position of the actuator and / or the movable element in which the exposure of the photovoltaic panel to the Light radiation allows a charge of the electrical energy accumulator.

The determination phase of the at least one first position may comprise the following steps:

at. move the actuator and / or the movable element over a significant extent of its race, in particular over more than a third of the race, or even more than half of the race, or even over its entire race, b. to collect from the photovoltaic panel, during the preceding step, a signal, in particular an electrical signal, representative of the intensity of the light radiation to which the photovoltaic panel is exposed along the extent of the race,

 vs. processing the signal obtained in the previous step and determining a second position of the actuator and / or the movable element in which the exposure of the photovoltaic panel to the light radiation allows charging of the electric energy accumulator. The acquisition step may comprise a step of associating different positions of the actuator and / or the mobile element with different corresponding luminous intensity of light.

The processing step may comprise a step of determining a first light intensity whose value is equal to or substantially equal to a second threshold and the step of determining the second position of the actuator and / or the element. mobile may include a step of defining the position of the actuator and / or the movable element associated with the first light intensity as the second position of the actuator and / or the movable element.

The method may further comprise the following step:

 d. record the second position as the first position. The method may comprise an iteration phase of steps a, b, c and d.

The method may further include an averaging step, including a weighted average calculation step, first and second positions, and a step of recording the result of the computing step as the first position. The method may comprise an iteration phase of steps a, b and c, each iteration comprising an averaging step, in particular a weighted average calculation step, first and second positions and a step of recording the result of the calculation step as the first position.

The determination phase of the at least one first position can comprise, prior to step a, a step of moving the actuator and / or the movable element, a step of stopping the actuator and / or the movable element in a third position on the order of a user and a step of recording the third position as the first position.

Following a command to move the actuator and / or the movable element to a fourth desired position, the following steps can be implemented:

 - check the state of charge of the electric energy accumulator,

- depending on the state of charge,

 moving the actuator and / or the movable element to the fourth position, or

 moving the actuator and / or the movable element to the first position.

The step of performing a displacement of the actuator and / or the movable element to the fourth position can be implemented if the state of charge of the electric energy accumulator is greater than one. first threshold. The step of performing a movement of the actuator and / or the movable element to the first position can be implemented if the state of charge of the electric energy accumulator is lower than that first threshold. According to the invention, an actuating actuator of a movable closing element, sun protection, occultation or screen, comprises hardware and / or software means for implementing the previously defined operating method.

According to the invention, a home automation installation comprises an actuator defined above and a movable closing element, solar protection, occultation or screen. Other features and advantages of the present invention will emerge from the description given below, with reference to the figures which illustrate an embodiment having no limiting character.

Figure 1 is a diagram of an embodiment of a home automation system according to the invention.

Figure 2 is a graph showing the change in light intensity seen by a photovoltaic panel secured to a movable element along the stroke of the movable member.

Figure 3 is a diagram of an embodiment of a home automation actuator according to the invention.

Figure 4 is a flow chart of an embodiment of a method of operating an actuator according to the invention.

FIG. 5 is a flow diagram of an embodiment of a first procedure of a method of operating an actuator according to the invention. Figure 6 is a flow chart of an embodiment of a second procedure of a method of operating an actuator according to the invention. One embodiment of a home automation installation 1 is shown in FIG. This installation comprises an actuator 3 and a movable element 6 closing, sun protection, occultation or screen. For example, the movable member is a curtain suspended from a rail 2 located above an opening having a first glazing 7 and a second glazing 8. The installation also includes a remote control and a sun sensor, suitable to transmit motion commands to the actuator, in particular by non-wire transmission.

The actuator 3 for maneuvering the mobile element 6 for closing, sun protection, occultation or screen is for example a carriage 3 adapted to move relative to the rail 2 or in the rail 2 under the effect The movable element is also mechanically connected to the movable element so that it is displaced when the actuator moves relative to the rail. In the embodiment of Figure 1, the curtain is for example fixed to the rail or immobilized relative to the rail at one of its ends (the left end in Figure 1) and attached to the actuator 3 to the other of its ends (the right end in Figure 1). Thus, by moving the movable member as a result of the displacement of the actuator, it is possible to obscure the first glazing 7, or the first glazing 7 and the second glazing 8 or neither of the two glazings. The rail 2 advantageously comprises a first guide element cooperating with a second guide element of the actuator. In one embodiment shown in FIG. 4, the actuator 3 comprises, besides the motor 5, an accumulator or a battery 9 for storing electrical energy, a photovoltaic panel 4 and a unit Process logic 92. The photovoltaic panel makes it possible to convert energy into electrical energy that is stored in the battery 9. The battery 9 makes it possible to supply the motor with electrical energy and thus to activate it. The logic processing unit makes it possible to control the periods of powering the motor by the battery, in particular as a function of the signals received by the latter. The logic processing unit also makes it possible to know the position of the actuator on its stroke 91 in the rail 2. The logic unit still makes it possible to know the value of the light intensity impacting the photovoltaic panel. The actuator is preferably autonomous.

The actuator 3 of maneuver comprises hardware means 4, 5, 9, 92 and / or software for governing its operation according to the method of the invention. In particular, the actuator comprises all the hardware elements 4, 5, 9, 92, 93, 94, 95 and / or software for implementing the steps of the method of operation object of the invention. Some elements may include software modules. The hardware and / or software elements comprise in particular memories 93, calculation elements 94 and interpretation elements 95, in particular elements making it possible to determine luminous intensity values and elements enabling the position of the light to be determined. actuator.

One embodiment of a method of operating an actuating actuator of a movable closing element, sun protection, occultation or screen is described below with reference to FIG.

In a first step 10, a user issues a command to move the moving element, that is to say that the user issues a movement order of the movable element or a movement control command of the element mobile, for example using or activating a remote control. Once the actuator 3 is in a position it considers adequate to allow a charge of the battery through the light radiation arriving on the photovoltaic panel, the user controls the immobilization of the actuator. Thus, in this embodiment, the determination phase is the consequence of an action of the actuator. This action reflects the user's desire to move the mobile element. A command command for activating the actuator, and therefore for moving the movable element, is thus issued and executed. In a second step 20, the user controls the recording of the current position of the actuator as a first position.

The procedure of steps 10 and 20 is optional. It can be replaced by the second optional procedure described below. In this case, an initial value of first position is for example pre-stored in the factory memory. This initial value of first position can correspond to any position. For example, it may be a run-stop or mid-race, or it is given as a percentage of the total run.

Thus, the operating method comprises a phase of determining a first position of the actuator and / or the movable element in which the exposure of the photovoltaic panel to the light radiation allows a charge of the electric energy accumulator. .

Therefore, the actuator is configured and can be used. Indeed, once this first stored position, the actuator can operate reliably. To achieve this goal, the operation of the actuator is such that the positioning thereof in configurations in which low solar radiation reaches the photovoltaic panel is avoided. To do this, as hereinafter described with reference to FIG. 6, in a first optional procedure of the operating method, following a movement command recognized in step 1 and requiring the actuator to move and / or of the movable element to a desired position, for example an end position, the following steps are implemented:

 - It is checked or determined the state of charge of the battery or battery in a step 120,

 - It is tested whether or not the state of charge value is greater than a first threshold given in a step 130,

 If this is the case, the movement of the actuator and / or the movable element is carried out to the desired position in a step 140,

 - If this is not the case, the movement of the actuator and / or the movable element is performed to the first position in a step 150.

Preferably, therefore, the first position is between the position occupied by the actuator and / or the movable element in step 1 and the desired position. More preferably, if the first position is not between the position occupied by the actuator and / or the movable element in step 1 and the desired position, the displacement of the actuator and / or the moving element is executed to the desired position regardless of the charge of the accumulator. Thus, it is particularly avoided that, following a movement control of the movable element in a direction required by the user, the displacement takes place in opposite directions, which would be disconcerting for the user. A second optional procedure of the operating method is described below with reference to FIG. 5. It makes it possible to determine the first position. In a step 210, the movable element and / or the actuator is moved along the race 91. Preferably, the movable element and / or the actuator is moved over a significant extent of its race, in particular over more than a third of the race, or even more than half of the race, or on the whole of the race. his race.

In a second step 220, during the displacement, a signal is collected, in particular an electrical signal, representative of the intensity of the light radiation to which the photovoltaic panel is exposed along the displacement. Thus, it is possible to perform a collection of data in which at different positions according to Corsican are associated values of intensity of light radiation received by the photovoltaic panel. Such a collection of data is advantageously stored in a memory. In addition, such a collection of data allows for example to build a graph as shown in Figure 2. In this graph illustrating the data collected during the movement of the actuator of Figure 1 along the race, we note that the the light intensity received by the photovoltaic panel at the end of the race and between the two windows is substantially lower than on the rest of the race.

In a third step 230, the signal obtained or the data are processed and it is thus determined, in a fourth step 240, a second position of the actuator and / or the movable element in which the exposure of the photovoltaic panel to the Light radiation allows a charge of the electrical energy accumulator. This processing step may for example comprise a step of determining a first light intensity Lui whose value is equal to or substantially equal to a second threshold Threshold 2. The step of determining the second position of the actuator and / or of the movable element comprises a step of defining the position Po1 of the actuator and / or of the movable element associated with the first light intensity Lui as the second position of the actuator and / or the movable element.

Finally, in a fifth step 250, the second position is used to modify the first position.

In a first variant of the use step, the second position can be registered directly as the first position. Alternatively, it is possible to average first and second positions, and then record the result of this average as the first position.

In a second variant of the use step, it is possible to iterate steps 210 to 240, and then the result (second position) of each iteration can be used to achieve one or more averages. Indeed, the result of each iteration can be used to average with the first position then in memory, the result of the average being then recorded as the new first position. Averages can be weighted averages.

Thus, in the second optional procedure, the determination phase is the consequence of an action of the actuator. This action reflects the user's desire to move the mobile element. A command command for activating the actuator, and therefore for moving the movable element, is thus issued and executed. It is during the execution of this command that the analysis of the luminous intensity along the race is carried out. The method of operation may include:

 - none of the optional procedures; or

- the first optional procedure; or - the second optional procedure; or

 - the first and second optional procedures.

Of course, since it is determined a first position, it can be determined several, including two, first positions. Moreover, since the first position is updated, it is possible to update several, including two, first positions. In particular, the first two positions may be substantially each close to a limit switch.

In the case of two first positions, the signal obtained or the data is processed and it is thus determined, in a fourth step 240, two second positions of the actuator and / or the movable element in which the exposure of the panel Photovoltaic light radiation allows a charge of the electric energy accumulator. This processing step may for example comprise a step of determining a first light intensity Lui, the value of which is equal to or substantially equal to a second threshold Threshold 2, or even a step of determining a second luminous intensity Lu2, whose value is equal to or substantially equal to a third threshold Threshold 3. The step of determining the second positions of the actuator and / or the movable element comprises a step of defining the position Po1 of the actuator and / or of the movable element associated with the first light intensity Lui as the second position of the actuator and / or the movable element, or even a step of defining the position Po2 of the actuator and / or the mobile element associated with the second luminous intensity Lu2 as the second position of the actuator and / or the movable element.

In operation, following an order of movement of the movable element to a fourth position, the method alternatively comprises step 150 of FIG. 6, a step during which the actuator executes the displacement to the fourth position. position, between the first two positions, the closer to the desired position, rather than to the first position closest to its current position.

The invention makes it possible to obtain an actuator whose operation does not destabilize the user. In particular, the actuator according to the invention avoids displacements of the mobile element not requested by the user or non-coherent with respect to the expectations of the user. In particular, the actuator according to the invention moves to a first position only if a movement command is provided. However, the actuator is autonomous and reliable.

A movement command is transmitted to the actuator by a remote control or a sensor of the installation

Claims

Claims:

1. Method of operating an actuator (3), in particular an autonomous actuator, for operating a mobile element (6) for closing, sun protection, concealment or screening, the actuator and/or the mobile element comprising a photovoltaic panel (4) intended to recharge an accumulator (9) of electrical energy supplying a motor of the actuator, the operating method comprising, as a result of a movement order of the mobile element emitted by a user, a phase of determining at least a first position of the actuator and/or the mobile element in which exposure of the photovoltaic panel to light radiation allows charging of the electrical energy accumulator .

2. Operating method according to the preceding claim, characterized in that the phase of determining the at least one first position comprises the following steps:

has. move the actuator and/or the movable element over a significant extent of its travel (91), in particular over more than a third of the travel, or even over more than half of the travel, or even over its entire race,

b. collect from the photovoltaic panel, during the previous step, a signal, in particular an electrical signal, representative of the intensity of the light radiation to which the photovoltaic panel is exposed along the extent of the stroke,

vs. process the signal obtained during the previous step and determine a second position of the actuator and/or the mobile element in which exposure of the photovoltaic panel to light radiation allows charging of the electrical energy accumulator.

3. Operating method according to the preceding claim, characterized in that the collection step comprises a step of associating different positions of the actuator and/or the mobile element with different corresponding light radiation intensities.

4. Operating method according to claim 3, characterized in that the processing step comprises a step of determining a first light intensity whose value is equal or substantially equal to a second threshold and in that the step of determining the second position of the actuator and/or the movable element comprises a step of defining the position of the actuator and/or the movable element associated with the first light intensity as the second position of the actuator and/or the mobile element.

5. Operating method according to one of claims 2 to 4, characterized in that it further comprises the following step:

d. save the second position as the first position. 6. Operating method according to the preceding claim, characterized in that it comprises a phase of iterations of steps a, b, c and d.

Operating method according to one of claims 2 to 6, characterized in that it further comprises an average calculation step, in particular a weighted average calculation step, of the first and second positions and a step of recording the result of the calculation step as the first position.

8. Operating method according to one of claims 2 to 4, characterized in that it comprises a phase of iterations of steps a, b and c, each iteration comprising an average calculation step, in particular a step of calculating the weighted average, the first and second positions and a step of recording the result of the calculation step as the first position.

9. Operating method according to one of the preceding claims, characterized in that the phase of determining the at least one first position comprises, prior to step a, a step of moving the actuator and/or the movable element, a step of stopping the actuator and/or the movable element in a third position on order from a user and a step of recording the third position as a first position.

10. Operating method according to one of the preceding claims, characterized in that, following an order to move the actuator and/or the movable element to a desired fourth position, the steps are implemented following:

- check the state of charge of the electrical energy accumulator,

- depending on the state of charge,

- move the actuator and/or the movable element up to the fourth position, or

- move the actuator and/or the mobile element to the first position.

1 1 . Operating method according to the preceding claim, characterized in that the step of carrying out a movement of the actuator and/or the movable element up to the fourth position is implemented if the state of charge of the electrical energy accumulator is greater than a first threshold and in that the step of carrying out a movement of the actuator and/or the mobile element to the first position is implemented if the The state of charge of the electrical energy accumulator is lower than this first threshold.

12. Actuator (3) for operating a mobile element (6) for closing, sun protection, concealment or screen, the actuator comprising material means (4, 5, 9, 92, 93, 94 , 95) and/or software for implementing the operating method according to one of the preceding claims.

13. Home automation installation (1) comprising an actuator (3) according to the preceding claim and a mobile element (6) for closing, sun protection, concealment or screen.