BE1030690B1 - VENTILABLE CONSTRUCTION THAT ENCLOSES AN OUTDOOR SPACE - Google Patents

Abstract

A structure (1) that encloses an outdoor space comprises load-bearing elements (2A, 2B), wall elements (3A, 3B, 3C, 3D), and a roof structure (4). The roof construction (4) consists at least partly of rotatable slats (5) that can be rotated between a closed position in which the rotatable slats (5) form a closing surface for the outdoor space, and an open position in which the outdoor space is ventilated along the rotatable slats. (5). A control unit (6) that controls the rotatable slats (5) is linked to a carbon dioxide meter (7), abbreviated CO2 meter, and configured to control at least part of the rotatable slats (5A) based on a carbon dioxide measurement, abbreviated CO2 measurement, received from the CO2 meter (7).

Description

VENTILABLE CONSTRUCTION ENCLOSING AN OUTDOOR SPACE PE20C25550

Technical Area

[01] The present invention relates to a closed construction that closes off an outdoor space. Examples thereof are a pergola, a veranda, a winter garden, a pool house, an outdoor office, etc. The invention relates in particular to such a closed construction with improved ventilation.

State of the art

[02] A closed structure that encloses an outdoor space typically includes a number of load-bearing elements: columns or vertical load-bearing elements, and beams or horizontal load-bearing elements. These load-bearing elements are, for example, made of steel or wood. For example, a stand-alone closed construction with a rectangular base comprises four columns (placed at the corners) and four beams (at the height between the columns or lying on the columns). For a closed structure under construction on an existing building with a rectangular base, two columns and three beams (a front beam and two side beams) may suffice, because the facade or other parts of the existing building can fulfill a load-bearing function for such a closed structure under construction. The closed structure further comprises a roof structure that is supported by the load-bearing elements, either the load-bearing elements that are part of the structure, or load-bearing elements of the building against which the closed structure is built. The closed construction is finally closed by walls between the load-bearing elements. These walls generally have no load-bearing function. For example, they are made of glass, wood, plastic, aluminum, cloth, etc., and include opaque wall elements, windows, doors, sliding doors, etc.

[03] Such closed constructions that close off an outdoor space have been gaining popularity in recent years because they have numerous applications, such as expanding an existing home with a winter garden, a terrace extension in the catering sector, a pool house next to an open-air swimming pool, an outdoor office , a pergola, a veranda, etc. Typically, such closed structures make it possible to create spaces in which the users are sheltered from unpleasant weather conditions such as rain, snow, wind, direct sunlight, etc., while still enjoying the experience of a bright outdoor space to enjoy.

[04] The European patent application EP 2 853 647 A1 entitled "Swivel roof tile for structures of the type of roofs, pergolas, platform shelters and the like and corresponding roof, pergola, platform shelter and the like" describes a pergola (2 in Fig. 1) with load-bearing columns (3 in Fig. 1) and a roof consisting of rotatable blades (1 in Fig. 1) that are coplanar when closed. The slats can be heated by heating elements (9 in Fig. 1) so that the structure remains resistant to heavy snowfall. There is no mention of ventilation in EP 2 853 647 A1.

[05] The European patent application EP 3 450 640 A1 entitled "Wintergarten with Lüftungselement" describes a closed winter garden consisting of load-bearing elements (vertical columns 5 and horizontal beams 4 in Fig. 1), a roof structure (3 in Fig. 1) and walls (6, 6', 6" in Fig. 1). The winter garden also contains a ventilation element (8 in Fig. 1). The ventilation element comprises one or more rotatable "louvers" that are either part of a wall (a vertical slat such as 8 in Fig. 1), or form part of the roof construction (see

[0020] and [0024]). EP 3 450 640 A1 addresses the problem of security and describes sizing the slat in such a way that burglary is prevented while ventilation is provided.

[06] The German patent application DE 10 2007 050 522 A1 with the title "Bauelement für einen Wintergarten" also describes a closed winter garden consisting of load-bearing columns and beams (2, 3, 4 in Fig. 1), a roof construction

(5, 6, 7 in Fig. 1 with ventilation element. Ventilation openings (10, 147706615500 in Fig. 1) are provided in the profiles (3, 4) of the winter garden. The ventilation is controlled on the basis of a timer and a profile that specifies the desired temperature as a function of time during the day (see [0018]).The ventilation in DE 102007 050 522 A1 therefore only aims to improve the thermal comfort for the users during the day.

[07] There is a general need for a closed construction that closes off an outdoor space with improved, automatic ventilation so that better air quality can be guaranteed, especially when the closed construction is used by a diverse group of people, for example as a winter bar, closed terrace, cafeteria, etc. in the catering sector.

Summary of the Invention

[08] According to a first aspect, the invention relates to a construction that closes off an outdoor space, comprising: - load-bearing elements, - wall elements between said load-bearing elements, and - a roof construction supported by said load-bearing elements, wherein said roof construction consists at least partly of rotatable slats that can be rotated between a closed position in which said rotatable slats form a closing surface for said outdoor space, and an open position in which said outdoor space is ventilated along said rotatable slats, wherein said construction comprises a control unit that controls said rotatable slats, and wherein said control unit is coupled to a carbon dioxide meter, abbreviated CO2 meter, and is configured to control at least a portion of said rotatable slats based on a carbon dioxide measurement, abbreviated CO2 measurement, received from said CO2 meter .

[09] The construction according to the present invention therefore comprises a 72279500 slatted roof or at least a section of the roof consisting of rotatable slats. While rotatable slats in roof constructions have until now been controlled depending on the location, orientation and position of the sun to regulate shade and sunlight according to the wishes of the users, or at best they have been controlled to improve the thermal comfort of To optimize the users, in the construction according to the present invention the position of at least a number of rotatable slats will be controlled based on the measured CO2 concentration. In this way, the closed outdoor space surrounded by the construction according to the present invention can be intelligently ventilated, and the air quality in the surrounded outdoor space can be guaranteed at all times. Particularly in applications such as the catering sector or events sector where the closed outdoor space is used by a large number of users at the same time and/or in situations where the air quality must comply with certain regulations, it is important that a high CO2 concentration is quickly detected and is quickly reversed by controlling the ventilation.

[10] In embodiments of the construction according to the present invention, defined in claim 2, said CO2 meter is integrated into one of said load-bearing elements.

[11] In alternative embodiments of the construction according to the present invention, defined in claim 3, said CO2 meter is integrated into said roof construction.

[12] The CO2 meter can therefore be part of the construction or separate from it. A separate CO2 meter can transmit the measured CO2 concentrations to the control unit via a wireless connection. A CO2 meter that is part of the construction can, for example, be integrated into one of the load-bearing elements, for example in a vertical column or in a horizontal beam. The CO2 meter can also be integrated into the roof construction of which the slats are part. Such integrated

CO2 meter can transmit the measured CO2 concentrations 4/5559 to the control unit via a wire connection, or can also be connected wirelessly to the control unit. When integrated into the construction, the CO2 meter can also be supplied with electrical power via the electrical power supply that is available for the motor of the rotatable slats.

[13] In embodiments of the construction according to the present invention, defined in claim 4, said control unit is configured to compare said CO2 measurement with one or more threshold values, and to control said rotatable slats from said closed position to an open position as soon as the CO2 measurement exceeds one or more of the threshold values mentioned.

[14] Indeed, the algorithm used by the control unit to direct the rotatable slats from the closed position to an open position can be based on threshold values. An algorithm that uses one threshold value can control the slats between the closed position and an open position. An algorithm that has multiple threshold values can control the slats between the closed position and several open positions. The slats remain in the closed position as long as none of the threshold values are exceeded.

As soon as threshold values are exceeded, the highest threshold value that is exceeded will determine to which open position the slats are controlled.

[5] In embodiments of the construction according to the present invention, defined in claim 5, said control unit is configured to determine the number of rotatable slats that are controlled from said closed position to an open position based on the exceeded threshold values.

[16] So, the number of slats that are rotated from the closed to open position when the CO2 concentration is too high can be determined by the control unit as a function of the measured CO2 concentration. A higher CO2 measurement will result in a greater number of slats being rotated from the closed 0924/5550 to an open state so that ventilation of the enclosed outdoor area is accelerated. This can be achieved by comparing the CO2 measurement with different threshold values and checking which is the highest threshold value that is exceeded. Each threshold value corresponds to a different number of slats that will be rotated, with a higher threshold value always corresponding to a higher number of slats than a lower threshold value.

[17] In embodiments of the construction according to the present invention, defined in claim 6, said control unit is configured to determine the rotation angle of said rotatable slats in the open position based on the exceeded threshold values.

[8] So, the ventilation opening created by turning slats when the CO2 concentration is too high can be determined by the control unit based on the measured CO2 concentration. A higher CO2 measurement will result in a greater rotation and therefore a larger ventilation opening so that ventilation of the enclosed outdoor space is accelerated. This can again be achieved by comparing the CO2 measurement with different threshold values and checking which is the highest threshold value that is exceeded. Each threshold value corresponds to a different angle of rotation for the slats and therefore to a different ventilation opening, whereby a higher threshold value always corresponds to a larger ventilation opening than a lower threshold value.

[19] In embodiments of the structure according to the present invention, defined in claim 7, said control unit is configured to determine the time interval during which said rotatable slats are controlled from said closed position to an open position based on the exceeded threshold values.

[20] So, the time interval during which the enclosed outdoor space 29990 will be ventilated by turning louvers if the CO2 concentration is too high can be determined by the control unit as a function of the measured CO2 concentration. A higher CO2 measurement will result in a longer ventilation time so that the enclosed outdoor space is better ventilated. This can again be achieved by comparing the CO2 measurement with different threshold values and checking which is the highest threshold value that is exceeded. Each threshold value corresponds to a different ventilation time, whereby a higher threshold value always corresponds to a longer ventilation time than a lower threshold value.

[21] The skilled person will understand that an even more intelligent control unit can set a combination of parameters based on the measured CO2 concentration and a comparison with CO2 threshold values, for example the ventilation duration (time interval), the ventilation opening (angle of rotation of the slats), and the number of slats that will be rotated to further optimize the ventilation of the enclosed outdoor space. The algorithm also does not necessarily have to use threshold values. In alternative embodiments, for example, the course of the CO2 concentration can be monitored and the variation of the CO2 concentration within a certain time interval can be used to control the rotatable slats. The intelligent control can also use profiles, or learning algorithms and machine learning technology can be used to allow the control unit to dynamically learn how the rotatable slats should be controlled depending on the changes in the CO2 concentration.

[22] In embodiments of the construction according to the present invention, defined in claim 8, said control unit is further coupled to one or more sensors, and configured to control at least a portion of said rotatable slats based on one or more sensor measurements received of said one or more sensors.

[23] In embodiments of the construction according to the present tri 7944/9550 defined in claim 9, said one or more sensors comprise a rain sensor.

[24] In addition to the CO2 measurement from the CO2 sensor, the control unit can also use other sensor measurements to determine how many slats are rotated, at what angle the slats are rotated, and/or how long the slats are be rotated into the open position.

For example, when a rain sensor indicates that it is raining outside and the

If the CO2 measurement in the enclosed space exceeds certain thresholds, the control unit can only open the slats slightly, at a limited angle, in such a way that ventilation is provided without letting in the rain. The control unit can be configured in such a way that in such a situation a larger number of slats are rotated through a smaller rotation angle and/or the slats are rotated in the open position for a longer period of time.

[25] Different embodiments of the construction according to the present invention can be tailored to different applications.

In an embodiment according to claim 8, the construction is a pergola for use in the catering sector. Such an embodiment is usually attached to an existing building and typically comprises glass wall elements. In an embodiment according to claim 9, the construction is an outdoor office. Such an embodiment typically comprises wooden wall elements. In an embodiment according to claim 10, the construction is a winter garden. In an embodiment according to claim 11, the construction is a pool house.

Brief Description of the Drawings

[26] Drawings 1-4 illustrate a first embodiment of the construction according to the present invention, more specifically a pergola for use in the catering sector;

[27] Drawings 5-6 illustrate a second embodiment of the construction according to the present invention, more specifically an outdoor office;

[28] Drawings 7-8 illustrate a third embodiment of the construction according to the present invention, more specifically a winter garden;

[29] Drawings 9-10 illustrate a fourth embodiment of the construction according to the present invention, more specifically a pool house; and

[30] Drawing 11 shows a computer system suitable as a control unit in embodiments of the construction according to this invention.

Description of Embodiments

[31] Drawing 1 shows a pergola 1 suitable for use in the catering sector where the pergola 1 is attached to an existing building 9, for example a restaurant, hotel, brasserie or café building. The pergola 1 is a construction according to the present invention that encloses an outdoor space in such a way that that outdoor space can be exploited in addition to the interior space of the building 9. Catering areas must meet certain ventilation standards in order to be used. In the event of a pandemic, for example, catering establishments that do not meet the ventilation standards will not be allowed to operate if certain contamination thresholds are exceeded. Regardless of imposed standards, it is important for the health and well-being of users of a catering area, for example customers and staff, that the enclosed space is regularly ventilated.

The pergola 1 comprises load-bearing elements, more specifically columns 2A and beams 2B, which support the structure. The pergola 1 further comprises wall elements 3A, 3B, between the columns 2A and beams 2B. The wall elements 3A and 3B consist of glass, surrounded by a window that can be made of wood, aluminum, plastic or another material. The wall elements can be fixed, such as wall element 3A. some 79990 wall elements can also be movable, for example sliding such as wall element 3B, pivoting, tiltable, or tiltable. The pergola 1 further comprises a roof construction 4 that is supported on the load-bearing elements 2A, 2B. It is possible that the roof construction comprises 4 additional load-bearing elements, for example beams, that provide support to the construction.

[32] The roof construction 4 comprises a number of slats 5 in the upper surface, strip-shaped parts that can be rotated about a longitudinal axis. Depending on the design of the rotating system, the slats can be rotated synchronously or individually (and therefore not necessarily synchronously). In the implementation of

Drawing 1 assumes that the slats 5 can be individually rotated.

When the slats 5 are in closed position and all movable wall elements 3B are in closed position, the load-bearing elements 2A, 2B, the wall elements 3A, 3B and the roof construction 4 will completely enclose an outdoor space so that that space is free from rain, wind and other unpleasant weather conditions can be operated as part of the catering business.

[33] The pergola 1 further comprises a control unit 6 that controls the rotatable slats 5 and thus tilts the slats between a closed position (in which the slats lie in the top surface of the roof construction 4) and an open position (in which one or more slats are rotated at an angle relative to the top surface of the roof construction 4). To this end, the control unit 6 receives CO2 values from a CO2 meter 7 that is built into one of the columns 2A of the pergola 1 and measures the CO2 content in the outdoor space enclosed by the pergola 1. The control unit 6 also receives signals from a rain sensor 8 that is positioned at the height of the roof construction 4 of the pergola 1. In the embodiment of Drawing 1, both the CO2 meter 7 and the rain sensor 8 are connected via wiring that has been integrated into a column 2A and the roof structure 4 connected to the control unit 6. The professional will understand that the communication between CO2 meter 7 and control unit 6 and/or the communication between the rain sensor 7 and the control unit 6 can also be done wirelessly. performed.

[34] In dry weather - in the absence of a signal from the rain sensor 8292/5550 - the control unit 6 will rotate all slats 5 through a certain angle, for example 45°, as soon as the CO2 measurement is obtained from CO2 meter 7 exceeds a certain threshold value. The slats 5 are then in a first open position illustrated by Drawing 2. The outdoor space enclosed by pergola 1 is ventilated for a preset time or until the measured CO2 value again falls below a certain threshold value.

[35] When the above-mentioned CO2 threshold value is exceeded while it is raining, the slats 5 will be rotated at a smaller angle, for example 15°, to a second open position illustrated in

Drawing 3. In the second open position, the space enclosed by pergola 1 is still ventilated, but rain is prevented from seeping in. The time during which the enclosed outdoor space is ventilated will now typically be longer because the ventilation flow rate with slats rotated at an angle of 15° is lower than the ventilation area with slats rotated at an angle of 45°.

[36] It is also possible that the control unit takes different threshold values into account. When a first CO2 threshold value is exceeded in dry weather, the control unit 6 will only rotate a limited number of slats through an angle of 45°. The slats then enter an open position shown in Drawing 4, in which, for example, 3 slats SA of the 9 slats are tilted while 6 slats 5B of the 9 slats remain in the plane of the roof. If the CO2 concentration continues to rise despite ventilation and also exceeds a second (or further) CO2 threshold value, the control unit will rotate 6 additional slats until finally all slats 5 have been rotated through an angle of 45° and thus the situation is illustrated. in Drawing 2 is achieved.

[37] Depending on the measured CO2 values and the signal obtained from the rain sensor 8, the control unit 6 will rotate one or more slats in such a way that the enclosed space is ventilated and the CO2 content drops again to an acceptable level , without impact on the comfort 7944/9550 for the users of the pergola: the space remains free from rain, wind or other unpleasant weather conditions. Depending on the algorithm, the control unit 6 will determine how many slats are rotated, at what angle the slats are rotated, and how long the slats are rotated, based on the signals from the CO2 meter 7 and the rain sensor 8.

Other parameters or signals from other sensors, not shown in Drawing 1-4, can also be used. For example, the position of the sun, the time of day, the location on earth, the orientation of the pergola, the temperature in the space enclosed by the pergola, the humidity in the space enclosed by the pergola, the air pressure, etc., to fine-tune the control of the rotatable slats by the control unit and increase the ease of use of the pergola 1. For example, the rotation angle of the slats 5, the choice of the slats that are rotated, the choice of the number of slats that are rotated can be determined depending on the position of the sun, so that even in an open position in which the room is ventilated, means that there is direct sunlight entering the pergola.

[38] Drawings 5 shows a free-standing outdoor office 1. The outdoor office 1 is also a construction according to the present invention. The outdoor office comprises load-bearing elements, for example the columns 2A, wall elements 3B and 3C between the columns 2A, and a roof construction 4 that supports the load-bearing elements 2A. The wall elements comprise a movable wall element 3B, mainly made of glass, and fixed wall elements 3C made of wood.

The roof structure 4 comprises 4 rotatable blades 5. In Drawing 5, the blades 5 are in the closed position: the blades 5 lie in the top surface of the roof. When closed, construction 1 encloses an outdoor space that can be used, for example as a home office.

[39] A control unit 6 and a CO2 meter 7 are built into the roof structure 4. The CO2 meter 7 measures the CO2 concentration inside the structure 1 and transmits the CO2 values to the control unit 6 via a wire connection that is also integrated into the roof structure 4. Furthermore, the structure 1 was equipped with a rain sensor 8 that is also connected to the control unit 6 via a 0922/5550 wire connection and thus signals to the control unit 6 whether or not precipitation is falling. The signaling can take place on a regular basis, for example every minute or at the request of the control unit 6, or at irregular times, for example each time a threshold (CO2 threshold, precipitation threshold) is exceeded or each time the change compared to a previous measurement exceeds a threshold.

[40] The control unit 6 interprets the signals from the CO2 meter 7 and the rain sensor 8, and controls the rotatable slats 5 on that basis. For example, if the CO2 meter 7 signals that the measured CO2 concentration inside the structure 1 exceeds an alarm threshold at a time when the rain sensor 8 signals no precipitation, then control unit 6 will tilt the slats 5 (via a motor or other drive). at a predetermined angle. The slats will thus be in the open position illustrated in Drawing 6 so that the office space enclosed by construction 1 is ventilated and the CO2 concentration in the office space will decrease again. As soon as the CO2 concentration falls below a certain acceptable threshold, the slats 5 will be returned to the closed position shown in Drawing 1. If the rain sensor 8 indicates that precipitation is falling, the slats 5 will be opened at a smaller angle to prevent precipitation from seeping in. The ventilation time, being the time required for the

CO2 concentration to fall below the acceptable threshold will then typically be greater.

[41] Drawing 7 shows a veranda 1 under construction on an existing house 9. The veranda 1 is an embodiment of the construction according to the present invention. The veranda 1 comprises load-bearing elements, for example columns 2A and beams 2B, wall elements 3A, 3B, 3C between the load-bearing elements 2A, 2B, and a roof construction 4. Some load-bearing elements are part of the roof construction 4. This is, for example, the case for beam 2B. The wall elements can be fixed or movable. For example, wall element 3A is a fixed window panel, wall element 3B is a sliding window panel, and wall element 3D is a roll-up cloth. The entire top surface of 7922/5550 roof construction 4 consists of slats 5 that can be rotated. The rotation of the slats is controlled by a control unit 6 which includes a wireless interface, for example a Bluetooth interface or a WiFi interface, which is used to wirelessly connect the control unit 6 to a CO2 meter 7 located in the space enclosed by the veranda 1, and with a rain sensor 8 located at the height of the roof structure 4.

[42] In the embodiment of construction 1 shown in Drawing 7, no wiring and CO2 meter need to be integrated into elements of construction 1. A CO2 meter that is not part of construction 1 and other sensors that are not part of the construction 1 can be connected wirelessly to the control unit 6 and send signals to the control unit 6, on the basis of which the latter can control the ventilation of the enclosed space via rotation of the slatted roof 5. In case the measured CO2 concentration in the space enclosed by the veranda 1 exceeds an alarm value at a time when the rain sensor 8 does not detect precipitation, the control unit 6 will rotate the slats 5 from a closed (horizontal) position to an open position in which the slats are at a certain angle so that the space enclosed by the veranda is ventilated via the roof. This is shown in Drawing 8. If the measured CO2 concentration falls below an acceptable threshold value, the slats 5 will be tilted back to the closed position illustrated in Drawing 7.

[43] Drawing 9 shows a pool house 1 near a swimming pool. The pool house 1 is a construction according to the present invention. The pool house comprises load-bearing elements, for example columns 2A, wall elements 3A, 3B, 3C, and a roof construction 4. The wall elements can be fixed or movable. For example, wall element 3A is a fixed window panel, wall element 3B is a sliding window panel, and wall element 3C is a fixed wooden panel. the top surface of roof structure 4 partly consists of rotatable slats 5. Rotating the slats between the closed position from Drawing 9 (in which the slats lie in one plane) and the open position from Drawing 10 (in which the slats are tilted at an angle) is done by control unit 6 that is integrated into the roof structure 4. The control unit 6 is equipped with a wireless 009 interface through which a CO2 meter 7 in the space enclosed by pool house 1 and a rain sensor 8 at the height of the roof structure 4 are wireless can be connected to the control unit 6. Ventilation of the space enclosed by pool house 1 is controlled by moving the slats 5 to the open position when a CO2 alarm value is exceeded, and moving the slats again to the closed position when the The CO2 concentration in the room has decreased sufficiently. The signals from the rain sensor 8 can postpone or delay ventilation by not tilting the slats 5 during rain or by only tilting them over a smaller angle.

[44] Drawing 11 shows a suitable computer system 100 suitable as a control unit 6 in embodiments of the construction according to this invention. Computer system 100 may generally be designed as a general purpose computer and further include a bus 110, a processor 102, a local memory 104, one or more optional input interfaces 114, one or more optional output interfaces 116, a communications interface 112, a storage element interface 106 and one or more storage elements 108. Bus 110 may include one or more electrical conductors that enable communication between the components of the computer system 100. Processor 102 may include any type of conventional processor or microprocessor that interprets and executes program instructions.

Local memory 104 may include a Random Access Memory (RAM) or other type of dynamic storage device, which stores information and instructions for execution by processor 102, and/or a Read-Only Memory (ROM) or other type of static storage device. device that stores static information and instructions for use by processor 102. Input interface 114 may include one or more conventional mechanisms that enable an operator or user to input information into the computing device 100, such as a keyboard 120, a mouse 130, a pen, voice recognition and/or biometric mechanisms, a touch screen, etc. Output interface 116 may include one or more conventional mechanisms that deliver information to the operator or user, such as a display 140, a printer 150, a speaker, etc. Communications interface 112 may include a transmitter/receiver 6968/5550 mechanism, such as for example, one or more Ethernet interfaces, which enable the computer system 100 to communicate with other devices and/or systems 181, 182, 183. The communication interface 112 of computer system 100 may be connected to another computer system by means of a Local Area Network (LAN) or a Wide Area Network (WAN), such as the Internet. Storage element interface 106 may include a storage interface, such as a Serial Advanced Technology

Attachment (SATA) interface or a Small Computer System Interface (SCSI), for connecting bus 110 to one or more storage elements 108, such as one or more local drives, for example SATA disk drives, and reading and writing data to and/or or control these storage elements 108.

Although the storage elements 108 have been described above as a local disk, in general any other suitable computer-readable medium, such as a removable magnetic disk, optical storage media, such as a CD or DVD, ROM disk, solid state drives, flash memory cards, can be used. The system 100 described above can also operate as a Virtual Machine on top of the physical hardware.

[45] The steps shown in the above embodiment(s) may be implemented as program instructions stored in local memory 104 of the computer system 100 for execution by the processor 102 thereof. Alternatively, the instruction may be stored on the storage element 108 or accessible from another computer system through the communications interface 112.

[46] Although the present invention has been illustrated with reference to specific embodiments, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied with various modifications and adjustments without departing from the scope of the invention. The present embodiments are therefore to be regarded in all respects as illustrative and not restrictive, the scope of the invention being described by the appended claims and not by the foregoing description, and any modifications falling within the meaning and scope of the claims , are therefore included here.

In other words, it is intended to include all modifications, variations or equivalents that fall within the scope of the underlying basic principles and whose essential attributes are claimed in this patent application.

In addition, the reader of this patent application will understand that the words "comprising" or "comprising" do not exclude other elements or steps, that the word "a" does not exclude a plural, and that a single element, such as a computer system, a processor or other integrated unit can perform the functions of various devices stated in the claims.

Any references in the claims should not be construed as limiting the claims in question.

The terms "first", "second", "third", "a", "b", "c" and the like, when used in the description or in the claims, are used to distinguish between similar elements or steps and do not necessarily describe a sequential or chronological order.

Likewise, the terms "top", "bottom", "over", bottom" and the like are used for purposes of description and do not necessarily refer to relative positions.

It is to be understood that those terms are interchangeable under appropriate circumstances and that embodiments of the invention are capable of functioning according to the present invention in orders or orientations other than those described or illustrated above.

Claims (13)

CONCLUSIONS BE2022/5550 1. A construction (1) that encloses an outdoor space, comprising: - load-bearing elements (2A, 2B), - wall elements (3A, 3B, 3C, 3D) between said load-bearing elements (2A, 2B), and - a roof construction (4 ) supported by said load-bearing elements (2A, 2B), wherein said roof construction (4) consists at least partly of rotatable slats (5) that can be rotated between a closed position in which said rotatable slats (5) form a closing surface for said outdoor space, and an open position in which said outdoor space is ventilated along said rotatable slats (5), wherein said construction (1) comprises a control unit (6) that controls said rotatable slats (5), and in which said control unit (6) is coupled is connected to a carbon dioxide meter (7), abbreviated CO2 meter, and is configured to control at least a part (5A) of said rotatable slats (5) based on a carbon dioxide measurement, abbreviated CO2 measurement, received from said CO2 meter (7). A construction (1) according to claim 1, wherein said CO2 meter (7) is integrated into one of said supporting elements (2A, 2B). A construction (1) according to claim 1, wherein said CO2 meter (7) is integrated into said roof construction (4). A structure (1) according to any one of the preceding claims, wherein said control unit (6) is configured to compare said CO2 measurement with one or more threshold values, and control said rotatable slats (5) from said closed position to an open position as soon as the CO2 measurement exceeds one or more of the threshold values mentioned. A structure (1) according to claim 4, wherein said control unit (6) is configured to determine the number of rotatable slats (5A) controlled from said closed position to an open position based on the threshold values exceeded. A structure (1) according to claim 4 or 5, wherein said control unit (6) is configured to determine the rotation angle of said rotatable slats (5) in the open position based on the exceeded threshold values. A structure (1) according to claim 4, 5 or 6, wherein said control unit (6) is configured to determine the time interval during which said rotatable slats (5) are controlled from said closed position to an open position based on of the threshold values exceeded. A structure (1) according to any one of the preceding claims, wherein said control unit (6) is further coupled to one or more sensors (8), and is configured to control at least part of said rotatable slats (5) based on one or more sensor measurements received from said one or more sensors (8). A structure (1) according to claim 8, wherein said one or more sensors comprises a rain sensor (8). A construction (1) according to any one of the preceding claims, wherein said construction is a pergola for use in the catering sector. A structure (1) according to any preceding claim, wherein said structure is an outdoor office. mn | BE2022/5550 A structure (1) according to any one of the preceding claims, wherein said structure is a winter garden. A structure (1) according to any preceding claim, wherein said structure is a pool house.