ITVI20070171A1 - METHOD OF OPENING OF OPENABLE ELEMENTS INSTALLED ON BUILDINGS AND AUTONOMOUS UNIT OF COMMAND OF OPENING AND CLOSING OF THESE OPENING ELEMENTS SUITABLE FOR REALIZING THIS OPENING METHOD - Google Patents

Description

Description of the patent for industrial invention entitled: "OPENING METHOD OF OPENABLE ELEMENTS INSTALLED ON BUILDINGS AND AUTONOMOUS OPENING AND CLOSING COMMAND UNIT OF THE ABOVE OPENABLE ELEMENTS SUITABLE TO REALIZE THIS OPENING METHOD".

DESCRIPTION

The invention relates to a method for opening opening elements which are installed on buildings.

In the following discussion, the term opening element will indicate any opening structure installed on buildings, such as a skylight.

Particularly the invention refers to a method for opening skylights and the like which are installed in buildings for the intake of light and air and which are operated by electric motors powered by direct current supplied by electric storage batteries with photovoltaic charging. .

The invention also concerns an autonomous unit for controlling the opening and closing of the aforementioned skylights, of the type comprising a battery of photovoltaic recharged electric accumulators, suitable for opening the aforementioned skylights according to the aforementioned method.

It is known that special opening elements are installed on the roofs of buildings, commonly referred to as skylights, which provide light and the exchange of air in the environment.

According to the known art, each skylight includes a dome delimited by a frame applied to a base positioned peripherally to an opening made in the building structure.

If the dome can be opened, the frame can also be hinged to the base and actuator means, connected to the frame, open and close the skylight by rotating the dome around the hinging means. In some embodiments, the actuator means comprise a direct current electric motor which is powered and controlled by an autonomous unit provided with photovoltaic recharging accumulator batteries.

The opening and closing of the skylight are manually controlled by the user via a button or remote control, while the closing can also take place automatically by atmospheric sensors that detect the presence of rain or wind.

The aforementioned skylights have the advantage of autonomy of operation, since they can work even in the event of absence or interruption of the mains electricity. However, they also have the recognized drawback that in the event of the accumulators running out, their opening and closing are impossible.

This eventuality can occur, for example, due to repeated and close opening and closing maneuvers over time by manual intervention by the user or by atmospheric wind or rain sensors.

Above all, however, the high electricity consumption of the rain sensors is one of the most frequent causes of battery depletion.

It is in fact known that in the presence of rain the sensor which detects it commands the closure of the evacuator if it is open or prevents its opening if it is closed.

Since the rain sensor is also activated by the presence of humidity, it is associated with an electrical resistance that keeps it warm in order to prevent frost or dew from forming on it.

In fact, the presence of frost or dew would be interpreted by the sensor as the presence of rain and therefore the autonomous unit that powers and controls the skylight, would not execute an opening command given by the user. To avoid this possibility, in the known art, when the skylight is closed, the electrical resistance is continuously powered and this obviously reduces the duration of the accumulator charge.

Furthermore, if repeated and close openings and closings are also carried out over time, perhaps concomitant with external conditions unfavorable to the photovoltaic generation for the compensation of the discharge of the accumulators, the latter can easily run out of their charge.

It is understood that in this case it is impossible to operate the motors and therefore to open the evacuator if it is closed or to close it if it is open.

If the latter event occurs in the event of rain, it is particularly dangerous for the environments and for the things in them.

Another recognized drawback is constituted by the fact that the autonomous opening and closing units of the known type do not provide the user with any indication of the state of charge of the accumulators with the danger that, after the last opening or closing, the skylight will without the user's knowledge, it remains open or closed.

The present invention intends to eliminate the aforementioned drawbacks.

In particular, it is a first object of the invention to provide a method of opening skylights operated by electric motors controlled by atmospheric wind and rain sensors and powered by electric storage batteries with photovoltaic recharge which, compared to the known art, allows to reduce the electrical absorption.

Another purpose of the invention is to create an autonomous unit for controlling the opening and closing of skylights of the type mentioned above that is capable of implementing this method of opening.

Last but not least, the aim of the invention is to guarantee skylights greater operational reliability in opening and closing, compared to that found in equivalent skylights belonging to the known art.

The said purposes are achieved by means of a method of opening the skylights which is carried out according to what is reported in the main claim to which reference is made for the sake of brevity.

Other detailed features of the invention are reported in the related dependent claims.

Advantageously, the opening method and the autonomous unit that creates it, both of which are the subject of the invention, extend the duration of the battery charge.

Still advantageously, the opening method and the control unit that creates it, make the operation of the skylights to which they are applied safer.

In particular, advantageously, the possibility is limited that the skylight remains open or closed after the respective closing and opening maneuvers, due to the accumulator charge being exhausted.

Again advantageously, this method and this autonomous unit can be applied to skylights of a known type, even if already installed.

The aforementioned purposes and advantages will be better highlighted during the description of a preferred embodiment of the invention which is given below by way of non-limiting indication, with reference to the attached drawing tables in which:

- figs. 1 to 4 schematically show a pivoting element in different phases of the opening maneuver according to the method of the invention;

- fig. 1 a shows a detail of fig. 1;

- fig. 5 represents the autonomous control unit for opening the opening element, object of the invention.

The opening method of the invention is described below with reference to figures 1 to 4 which schematically represent different positions of an opening element, in the case in question a skylight indicated as a whole with 1.

The aforementioned opening method can refer to an opening element of any type and therefore not only to a skylight.

Furthermore, in the description that follows the term skylight must be understood as a synonym for an opening element.

The skylight, as can be seen in the aforementioned figures 1 to 4, comprises a cover 2 provided with a frame 2a hinged to a base 3 which delimits an opening A made in a building indicated as a whole by B. A motor is connected to the cover 2 electric opening and closing 4 which is controlled by command means, indicated as a whole with 10, which comprise:

- manual control means, indicated as a whole with 5, which comprise, for example, a switch or a remote control 5a;

- automatic control means, indicated as a whole with 6, which comprise a first sensor 6 'for detecting rain provided with electric heating means 7 and a second sensor 6 "for wind detection.

In particular, the first sensor 6 'is "active" in the presence of rain or simply humidity and similarly the second sensor 6 "is" active "in the presence of wind.

Similarly, the sensors are “inactive” in the absence of rain or humidity and, respectively, of wind.

An autonomous control unit, indicated as a whole with 8 and electrically connected to the electric motor 4 and to the automatic control means 6, supervises the opening and closing of the lid 2 of the opening element 1.

In particular, the word "active" means that the sensor detects the presence of rain, humidity or wind and does not give the autonomous control unit 8 consent to open the cover 2.

Conversely, the word "disabled" means that the sensors provide the autonomous control unit 8 with the consent to open the lid 2.

According to the invention, the method of the invention provides that the following operations are performed to open the lid 2 of the opening element 1:

- check the active or inactive status of both sensors 6 'and 6 ";

- if both sensors 6 ', 6 "are deactivated and therefore in the absence of both rain or humidity and wind, start the electric motor 4 to fully open the cover 2;

- if the first sensor 6 'is active and therefore in the presence of rain or humidity and if the second sensor 6 "is deactivated and therefore in the absence of wind, start the electric motor 4 to lift the cover 2 by a predetermined quantity X with respect to to base 3;

- stop the engine 4.

If the first sensor 6 <*> is active and therefore in the presence of rain or humidity and if the second sensor 6 "is deactivated and therefore in the absence of wind, after lifting the cover 2 of the predetermined quantity X with respect to the base and the '' stopping the electric motor 4, the method involves the following operations:

- power the electric heating means 7 of the first sensor 6 ';

- interrupting the power supply of the aforesaid electric heating means 7 after a predetermined time;

- start the electric motor 4 to fully open the cover 2 if the first sensor 6 'is deactivated and therefore in the absence of rain or humidity;

- stop the electric motor 4.

If after the interruption of the heating the first sensor 6 'is wet, the lid 2 remains raised with respect to the base 3 and remains in this position until a command given by the user closes it.

According to a variant of operation, if after the interruption of the heating the first sensor 6 'is wet, the lid 2 is automatically closed immediately or after a predetermined time.

The method of the invention provides for the use of the autonomous control unit, indicated as a whole with 8 which is represented in detail in fig. 5, which includes a programmable logic unit 9 and an autonomous power supply unit indicated as a whole with 11, to which the electric motor 4 and the control means of the electric motor, generally indicated with 10, are connected.

The autonomous control unit 8, preferably but not necessarily, includes a casing 8a which contains the programmable logic unit 9 and the autonomous power supply unit 11 and in which the following are identified:

- a first port 12 for connection to the electric motor 4; - a second port 13 for connection to the automatic control means 6 of the electric motor 4 itself.

Furthermore, the programmable logic unit 9 is connected to the connection ports 12 and 13 and to the manual control means 5 of the electric motor 4 and the autonomous power supply unit 11 is connected to the programmable logic unit 9, to the automatic control means 6 and to the electric motor 4.

In particular, in the first door 12 there is a first contact 12a connected to the programmable logic unit 9 through a first conductor 14 and a second contact 12b connected to the output 11a of the autonomous power supply unit 11 through a second conductor 15.

A fuse 16 is arranged in series with the second conductor 15. As far as the second door 13 is concerned, there is a first contact 13a and a second contact 13b connected via an external line 17 to the automatic control means 6, in particular to the first sensor 6 'for detecting rain or humidity and the second sensor 6 ”for detecting wind.

Both of the aforementioned contacts 13a, 13b are also connected via an internal line 18 to the programmable logic unit 9 through the interposition of a communication interface 19.

In the second door there is also a third contact 13c which through a third conductor 20 is connected to the autonomous power supply unit 11 and a fourth contact 13d connected to the power supply neutral.

The presence of a radio receiver 21 interposed between the manual control means 5 and the programmable logic unit 9, allows the opening and closing of the element that can be opened by means of the manual control means 5 which in this case consist of a remote control 5a available to the operator.

In a different embodiment, the radio receiver 21 may not be present and the manual control means 5 may consist of buttons directly connected to the programmable logic unit 9.

As regards the autonomous power supply unit 11, it comprises a battery of electric accumulators 22 electrically connected to an electronic management unit 23 which controls the charge of the aforementioned accumulators 22 by a photovoltaic panel 24 to which it is connected via a first connection line 25.

It is evident that the photovoltaic panel 24 can be placed in any position.

Preferably, but not necessarily, the accumulators 22 are arranged in a remote position with respect to the autonomous control unit 8, in which case a second connection line 26 electrically connects them to the electric management unit 23.

A third connection line 27 connects the electronic management unit 23 to the programmable logic unit 9 through the interposition of a regulation unit 30.

It is also noted that the electronic management unit 23, the regulation unit 30 and the programmable logic unit 9 are connected to the power supply neutral.

As regards in particular the programmable logic unit 9, it is of the type known per se, available on the market and is programmed in such a way as to signal any state of incipient depletion of the accumulator charge by means of suitable alarms 31 of the acoustic, luminous or of another kind.

Operationally, when the user wants to open the lid 2 of the opening element, he acts on the manual control means 5 and sends the opening signal to the programmable logic unit 9.

The latter, on the basis of a program previously stored therein, first of all checks the active or inactive state of the sensors 6 'and 6 ".

If the second sensor 6 "is active, this means that there is wind and in this case the programmable logic unit 9, regardless of the state of the first sensor 6 'and therefore regardless of the presence or absence of rain or humidity, it does not allow the motor 4 to be powered and therefore the cover 2 remains closed as can be seen in fig. 1.

If, on the other hand, both sensors are deactivated, this means that there is neither wind nor rain or humidity and in this case the logic unit 9 allows the motor 4 to be powered up until the cover 2 is completely opened. observe in fig. 4.

If, on the other hand, the first sensor 6 'is active and the second sensor 6 "is deactivated, this means that it is in the presence of rain or humidity and in this case the logic unit 9 allows the motor 4 to be powered for a period of time. sufficient to lift the lid 2 by the predetermined quantity X with respect to the base 3 to arrange it in the configuration shown in figs. 2 and 3.

The electric motor 4 is then stopped and the programmable logic unit 9 allows the powering of the electric heating means 7 of the first sensor 6 ', through electricity supplied by the autonomous power supply unit 11.

The electric heating means 7 of the first sensor 6 'are powered for a predetermined time when programming the programmable logic unit 9, sufficient to allow the evaporation of any frost or dew present on the first sensor 6'.

If after this time the first sensor 6 'is dry, the programmable logic unit 9 feeds the electric motor 4 again for a time sufficient to allow the total opening of the lid 2 which moves to the opening position of fig. 4.

If, on the other hand, the first sensor 6 'is wet, the programmable logic unit 9 does not give the consent to start the motor 4 and consequently the cover 2 remains locked in the raised position with respect to the base 3 which can be seen in figs. 2 and 3.

An operating variant can provide that after the foreseen heating time has elapsed, if the first sensor 6 'still detects the presence of humidity, the programmable logic unit 9 gives the motor 4 the start consent to close the cover 2 again as described above. observe in fig. 1. The purpose of reducing the consumption of the accumulator battery 22 is thus achieved since the electric heating means 7 of the first rain detection sensor 6 ', which are the elements with the greatest absorption, are powered only for a limited time, only after partial lifting of the lid 2.

Therefore, the accumulator battery 22 supplies current only for a limited time, contrary to what happens in systems of the known type in which the electric heating means of the rain sensor are always powered.

In this way the charge of the accumulators is preserved. Furthermore, the presence of the warning devices 31 reduces the possibility of out of service due to unexpected discharge of the accumulator battery 22.

Based on the foregoing, it is therefore understood that the method of opening the opening elements and the autonomous unit for opening and closing the aforementioned opening elements object of the invention actually achieve all the intended purposes.

It is evident that operational variants of the described method and executive variants of the autonomous unit that realizes it, not described in the text and not represented in the drawings, should they fall within the scope of the following claims, they must certainly be considered protected by this patent.

Claims (1)

CLAIMS 1) Method for opening the lid (2) of an opening element (1) installed on buildings of the type comprising: - a base (3) that delimits an opening (A) made in a building (B); - a lid (2) hinged to said base (3); - at least one electric motor (4) for opening and closing said lid (2); - manual control means (5; 5a) of said electric motor (4); - automatic control means (6) of said electric motor (4) comprising at least a first sensor (6 ') for detecting the presence of rain or humidity provided with electric heating means (7) and a second sensor (6 " ) for the detection of the presence of wind; - an autonomous control unit (8) for opening and closing said lid (2), characterized by the fact that it includes the following operations: - check the active or inactive status of both said sensors (6 ', 6 ”); - if both said sensors (6 ', 6 ”) are deactivated and therefore in the absence of both rain or humidity and wind, start said electric motor (4) to fully open said cover (2); - if said first sensor (6 ') is active and therefore in the presence of rain or humidity and if said second sensor (6 ") is deactivated and therefore in the absence of wind, start said electric motor (4) to lift said cover ( 2) of a predetermined quantity (X) with respect to said base (3); - stop said engine (4). or 2) Method according to claim 1) characterized in that if said first sensor (6 ') is active and therefore in the presence of rain or humidity and if said second sensor (6 ") is deactivated and therefore in the absence of wind, after said lifting of said cover (2) of said predetermined quantity (X) with respect to said base (3) and stopping of said electric motor (4), the following operations are performed: - powering said electric heating means (7) of said first sensor (6 '); - interrupting the power supply of said electric heating means (7) after a predetermined time; - start said electric motor (4) to fully open said cover (2) if said first sensor (6 ') is deactivated and therefore in the absence of rain or humidity. 3) Method according to claim 2) characterized by the fact that said cover (2) remains raised with respect to said base, if after said interruption of said power supply of said heating means (7) said first sensor (6 ') is wet. 4) Method according to claim 2) characterized by the fact that said lid (2) is closed if after said interruption of said power supply of said heating means (7) said first sensor (6 ') is wet. 5) Method according to claim 1) characterized in that said autonomous control unit (8) comprises: - at least a first port (12) for connection to said electric motor (4); - at least a second door (13) for connection to said automatic control means (6) of said electric motor (4); - at least one programmable logic unit (9) connected to said connection ports (12, 13) and to said manual control means (5, 5a) of said electric motor (4); - at least one autonomous power supply unit (11) connected to said programmable logic unit (9), to said automatic control means (6) and to said electric motor (4). 6) Method according to claim 5) characterized by the fact that in said first gate (12) there are: - a first contact (12a) connected through a first conductor (14) to said programmable logic unit (9); - a second contact (12b) connected via a second conductor (15) to said autonomous power supply unit (11). 7) Method according to claim 6, characterized in that it comprises a fuse (16) arranged in series with said second conductor (15). 8) Method according to claim 5) characterized by the fact that in said second door (13) there are: - a first contact (13a) and a second contact (13b) connected via an external line (17) to said automatic control means (6) and via an internal line (18) to said programmable logic unit (9); - a third contact (13c) connected through a third conductor (20) to said autonomous power supply unit (11); - a fourth contact (13d) connected to the power supply neutral. 9) Method according to claim 8) characterized in that it comprises a communication interface (19) interposed between said second part (13) and said programmable logic unit (9). 10) Method according to claim 5, characterized in that it comprises a radio receiver (21) interposed between said manual control means (5) and said programmable logic unit (9). 11) Method according to claim 10, characterized in that said manual control means are a remote control (5a). 12) Method according to claim 5, characterized in that said manual control means (5) are pushbuttons. 13) Method according to claim 5) characterized by the fact that said autonomous power supply unit (11) comprises: - one or more electric accumulators (22); - at least one photovoltaic panel (24); - at least an electronic management unit (23) for the charge of said accumulators (22) in which a first line (25) for connection to said photovoltaic panel (24), a second connection line (26) for said accumulators are identified to said photovoltaic panel (24) and a third connection line (27) to said programmable logic unit (9). 14) Method according to claim 13) characterized by the fact that said autonomous power supply unit (11) also comprises a regulation unit (30) electrically inserted in said third line (27) between said electronic management unit (23) and said programmable logic unit (9). 15) Method according to claim 14, characterized in that said electronic management unit (23), said regulation unit (30) and said programmable logic unit (9) are connected to the power supply neutral.