EP4261358A1 - Front end device - Google Patents

Abstract

A front-mounted device (1) is intended to be arranged on an outer wall (12) of a building (11). The front-mounted device (1) has a casing (4) with a front wall (2) and a rear wall (3) that can be arranged on the outer wall (12) of the building (11). The front wall (4) is kept at a distance (A) from the rear wall (3) by a structure (5). The cover (4) is essentially designed to be impermeable to air. At least one cavity (13) is formed between the front wall (4) and the rear wall (3) of the casing (4), in which a negative pressure is generated or can be generated.

Description

The invention relates to a front wall device for arrangement on an outer wall of a building, the front wall device having a shell with a front wall and a rear wall that can be arranged on the outer wall of the building, and the front wall being kept at a distance from the rear wall by a structure.

In order to better regulate the building climate and reduce the costs for necessary heating or cooling systems, it is common practice to insulate modern buildings from the outside as effectively as possible, i.e. to thermally insulate them. As a rule, the building is covered during construction with at least one layer of a highly thermally insulating material or material composite, such as rigid foam panels made of foamed plastic, such as polystyrene or polyurethane.

By today's standards, older buildings were often inadequately insulated or even built without any external insulation. However, in order to save costs and meet climate protection requirements, it makes sense or even necessary to subsequently bring such buildings up to newer climate standards. There is therefore an increased need for technical solutions with which existing, poorly thermally insulated buildings can be retrofitted.

When retroactively insulating existing buildings, two aspects are in the foreground: On the one hand, the building should be usable and habitable as smoothly as possible while measures are being taken to insulate its outer shell; On the other hand, the costs for such insulation measures should be as low as possible so that these measures are available to a broad audience and pay for themselves in the foreseeable future.

In order to significantly increase thermal insulation, residential buildings already have the option of subsequently installing prefabricated modules on the outside walls. Such modules, which have strong thermal insulation properties, are prefabricated at the factory and exactly replicate the sections of the house front on which they are to be installed, including all building openings.

For halls, such as factory, sports and event halls, stables or other large buildings, such as libraries or museums, which tend to be poorly or not at all insulated and have large building areas but relatively few building openings, the current options for subsequent thermal insulation are not particularly effective or not satisfactory in terms of price. For such buildings, solutions are being sought with which large building fronts can be upgraded in a particularly cost-effective and effective way in terms of climate technology.

The invention is therefore based on the object of providing a front-mounting device of the type mentioned at the outset, which does not have the disadvantages of the prior art. In particular, a front-mounting device should be provided with which large building areas can subsequently be thermally insulated from the outside as cost-effectively and effectively as possible.

This problem is solved according to the invention with a front-mounting device which has the features of claim 1.

Preferred and advantageous embodiments of the invention are the subject of the subclaims.

According to the invention it is provided that the casing of the front device is essentially impermeable to air is formed, and that at least one cavity is formed between the front wall and the rear wall of the casing, in which a negative pressure is generated or can be generated.

By sucking out the cover, a negative pressure can be created or formed in it, which is maintained due to the airtightness of the cover. The cavity or cavities in the casing also remain in place when a negative pressure is created or formed in the casing, without collapsing, since the front wall is kept at a distance from the rear wall via the structure. Since the cavity or possibly the cavities are air-free and therefore only slightly or not at all heat-conducting, the front device forms a very effective heat-conducting barrier or heat-insulating layer on the outer wall of the building on which it is arranged.

The structure of the front-mounted device according to the invention makes it possible to provide large-area thermal insulation elements with a very low heat transfer coefficient using simple means, so that building areas can be subsequently insulated over a large area and cost-effectively.

For example, several of the front-mounted devices according to the invention can be subsequently mounted or hung on an outer wall of a building, such as a hall (in particular over the entire area), in order to insulate the outer wall from the outside over a large area. Such thermal insulation can be installed permanently or only temporarily, e.g. for an event in a hall.

It is particularly preferred if the structure is formed by a foam arranged between the front wall and the rear wall. The foam can be used as a prefabricated layer when assembling the stem device be arranged between the front wall and the rear wall. However, the foam is preferably filled into the casing in a non-hardened or non-expanded state and hardens directly in it. In embodiments in which the structure is formed by a foam, in particular a plurality of cavities are formed in the shell, all or partially of which can be connected to one another or separated from one another. From a manufacturing perspective, a structure made of foam can be arranged in the casing particularly easily and cost-effectively.

The foam serving as a structure can be a foamed plastic, i.e. a plastic foam, which preferably consists essentially of polyethylene (PE) or polyurethane (PU). These foams are inexpensive and easy to process.

However, the foam can also consist of a foamed metal, i.e. a metal foam, for example foamed aluminum. Such foams form a particularly resistant structure that is difficult to deform, so that a particularly low negative pressure can be generated or formed in the casing.

Within the scope of the invention, the structure can also be formed via spacers, for example webs or walls, which are arranged between the front wall and the rear wall and connect the front wall and the rear wall. Such spacers are particularly dimensionally stable, so that a particularly low negative pressure can also be generated in cases whose front wall and rear wall are thus kept at a distance, without the cavity (or the cavities) collapsing (or collapsing).

The spacers, in particular webs or walls, are preferably made of plastic, in particular essentially of PE or PU, or of metal, in particular essentially of aluminum, since these materials are easy and inexpensive to process and form extremely dimensionally stable spacers.

Within the scope of the invention, the structure can be formed both from bars or walls and from foam arranged between them in order to combine the advantages of both variants.

Within the scope of the invention it can be provided that the casing consists of plates, i.e. that at least the front wall and the rear wall are each formed by a preferably very thin plate. Since plate elements themselves have a high degree of dimensional stability, a structure made of a particularly coarse-pored foam or a structure made of relatively widely spaced spacers, such as webs or walls, can be used in such cases without the case being in the process of generating or forming a negative pressure Cavities or areas of the cavity arranged directly on the casing are sucked and reduced in size.

It is also possible within the scope of the invention for the cover to consist of a film, a coated fabric or a coated fiber fleece. Such cases are particularly easy and inexpensive to produce. In addition, such cases, if they are intended to be filled with a structure made of foam, can be stored in a particularly space-saving manner and transported cost-effectively before filling in the not yet hardened foam.

The casing preferably consists essentially of plastic, in particular PET, or the casing is coated with plastic, in particular PET. The cover can, for example, be a plastic-coated natural fabric or nonwoven fabric, such as paper. The plastics used to manufacture the cover, such as polyethylene (PE) or polyethylene terephthalate (PET), are usually particularly light and weather-resistant, easy to process and inexpensive.

In a particularly preferred embodiment, the front device has at least one vacuum pump arranged inside and/or outside of the casing and connected to the cavity or possibly the cavities for generating and maintaining a negative pressure in the cavity or possibly in the cavities. The vacuum pump can be set up to run continuously or according to a predetermined schedule, or instead or additionally to be put into operation by manual or automatic activation. The presence of a vacuum pump means that a negative pressure can be maintained over long periods of time even in a cavity or cavities inside a casing that is not 100% airtight. Instead of a vacuum pump, any other possible device that is suitable for generating a negative pressure can also be provided.

If there are several front-mounted devices according to the invention arranged on a building, each of the front-mounted devices can have its own vacuum pump. However, it is also possible that only some of the front-mounted devices have vacuum pumps, and these front-mounted devices are connected to the other front-mounted devices via lines, or that there is only one or a few common vacuum pumps that are connected to all of the front-mounted devices via lines. are.

In a preferred development, the front device has a control which is connected to the vacuum pump and via which the vacuum pump can be controlled. For example, the vacuum pump can be operated according to a predefined schedule using the controller. It is also conceivable that the vacuum pump can be activated remotely, automatically or manually, using the control.

Preferably, the control is additionally connected to at least one gas pressure sensor arranged in the casing, so that in such an embodiment the vacuum pump can be controlled or regulated depending on the values measured with the gas pressure sensor. With such a link between sensors and control, the pump can be operated fully automatically by only activating it when necessary, i.e. when the pressure in the cavity or cavities exceeds a certain limit value.

In a preferred embodiment of the front device according to the invention, at least one photovoltaic device is arranged on the front wall of the casing. The photovoltaic device supplies the vacuum pump and, in embodiments with a controller, optionally also the controller (and possibly the gas pressure sensor) with energy. The front-mounted device can thus be operated autonomously or the negative pressure inside the front-mounted device can be independently maintained at a certain level.

The energy supply can take place directly. However, the front device preferably has an energy storage device which is connected to the photovoltaic device and which is charged with electrical energy via the photovoltaic device when the weather conditions are suitable. If necessary, such an energy storage device releases energy to the vacuum pump and, if necessary, to the controller (or the gas pressure sensor), so that the Autonomous energy supply to the front-mounted device is ensured even in bad weather or at night.

If several front-mounted devices are arranged or mounted on a building, all front-mounted devices can have photovoltaic devices. However, it is also possible that only some of the front-mounted devices have photovoltaic devices, which, however, supply all of the front-mounted devices with energy. It is also conceivable that there are several or just one central energy storage device for the front-mounted devices.

Alternatively or additionally, the vacuum pump and possibly the control can also be connectable to an external energy supply, for example the building's energy supply, and can be supplied with energy from this energy supply. On the one hand, this means that there is no need for a photovoltaic device; On the other hand, in front-mounted devices that have photovoltaic devices, the energy supply is ensured even in the event of prolonged bad weather or a failure of the photovoltaic devices or, if applicable, the energy storage device.

In a preferred embodiment, the porch device has a suspension or several suspensions, via which the porch device can be hung on the outer wall of the building directly or with the aid of a structure or structures provided for this purpose. The suspension(s) is/are preferably arranged in the area of an upper end of the front-mounted device when the front-mounted device is in use and/or on the rear wall. With the help of the suspension(s) and, if necessary, the construction(s), the rear wall of the front structure can be arranged directly on the building or at a certain distance from the building. For example, the front device can have a holder at its upper end with which it can be hung on a bracket on the outer wall of the building. In such embodiments, only the brackets have to be subsequently mounted on the outer wall of the building to be insulated, which can be done particularly quickly and cost-effectively.

In a preferred embodiment, the front wall and/or the rear wall has/have a thickness of <= 15 mm, in particular <= 10 mm, preferably <= 5 mm. Such front-mounted devices are low in weight and sufficiently stable.

In the front-mounted device according to the invention, the distance between the front wall and the rear wall is preferably at least 10 mm, more preferably at least 30 mm, in particular at least 50 mm. This enables the formation of a cavity or cavities with the largest possible volume, so that particularly good thermal insulation is achieved.

However, the distance between the front wall and the rear wall is preferably a maximum of 300 mm, preferably a maximum of 200 mm, in particular a maximum of 100 mm. This enables easier assembly and/or transport of the stem devices.

Further details, features and advantages of the invention result from the following description with reference to the attached drawing, in which a preferred embodiment is shown.

The figure shows a section through a simplified front assembly device 1 according to the invention in a side view. The cut runs along one cutting plane running vertically and normal to the plate-shaped front device 1.

The front device 1 has a front wall 2 and a rear wall 3, which together form a casing 4 of the front device 1 or are components of the casing 4.

The front wall 2 and the rear wall 3 each have a thickness S (or thickness), which can be the same or different in size.

A structure 5 is arranged between the front wall 2 and the rear wall 3, through which the front wall 2 is spaced from the rear wall 4 by a distance A.

The structure 5 can, for example, be a foam 6 or also consist of a large number of spacers 7, such as webs or walls.

The figure shows, by way of example, an upper half of the stem device 1 with a hardened foam 6 accommodated in the casing 4 as a structure 5 and a lower half with spacers 7 accommodated in the casing 4 as a structure 5. The structure 5 is preferably formed either by a foam 6 or by spacers 7. However, the shell 4 can also contain a combination of foam 6 and spacers 7 as structure 5.

The front-mounted device 1 has a suspension 8, which in the illustrated embodiment is arranged at an upper end of the front-mounted device 1. With this suspension 8, the front device 1 is suspended or mounted on a structure 9 mounted on a building 11, so that the rear wall 3 is arranged on the outer wall 12 of the building 11. Due to the structure 5, a cavity 13 or several cavities 13 are formed in the casing 4, ie in the interior of the front assembly device 1.

Since the casing 4 of the front device 1 is largely airtight, a negative pressure can be generated in the cavity 13 or in the cavities 13 or a negative pressure generated remains at least temporarily.

In order to generate the negative pressure or to be able to maintain the negative pressure at a certain pressure level, the front assembly device 1 according to the invention has a vacuum pump 14. The vacuum pump 14 is arranged entirely in the casing 4, partially in the casing 4 or on the outside of the casing 4. It is also possible for the vacuum pump 14 to be spaced from the casing 4 and only connected to the casing 4 via a line.

A photovoltaic device 15 is arranged on the front wall 2 of the front-mounted device 1 according to the invention, in particular glued or screwed on. The photovoltaic device 15 can extend over the entire area of the front device 1 or only over a part of the area of the front device 1.

The photovoltaic device 15 is connected to an energy storage 16, from which the vacuum pump 14 is fed.

In the embodiment shown, the energy storage 16 is also connected to an energy supply 17 of the building 11.

A gas pressure sensor (not shown in the figure) is installed in the vacuum pump 14 and is connected to a control unit (also not shown) which is integrated into the energy storage 16 or is spaced apart from it. Over The vacuum pump 14 is controlled depending on the values measured by the gas pressure sensor.

List of reference symbols:

1

Stem device

2

front wall

3

Back wall

4

Covering

5

structure

6

Foam

7

Spacer

8th

suspension

9

construction

10

---

11

Building

12

external wall

13

cavity

14

vacuum pump

15

Photovoltaic device

16

Energy storage

17

power supply

S

Strength

A

Distance

Claims (15)

Front-mounted device (1) for arrangement on an outer wall (12) of a building (11), the front-mounted device (1) having a casing (4) with a front wall (2) and a rear wall that can be arranged on the outer wall (12) of the building (11). (3) and wherein the front wall (4) is kept at a distance (A) from the rear wall (3) by a structure (5), characterized in that the cover (4) is designed to be essentially airtight, and that between the Front wall (4) and the rear wall (3) of the casing (4) at least one cavity (13) is formed, in which a negative pressure is generated or can be generated. Stem device according to claim 1, characterized in that the structure (5) is formed by a foam (6) arranged between the front wall (4) and the rear wall (3), in particular hardened in the cover (4). Stem device according to claim 1 or 2, characterized in that the foam (6) is a plastic foam, in particular essentially made of PE or PU, or a metal foam, in particular essentially made of aluminum. Stem device according to one of claims 1 to 3,
characterized in that the structure (5) is formed by spacers (7), such as webs or walls, arranged between the front wall (4) and the rear wall (3) and connecting the front wall (4) and the rear wall (3). . Stem device according to claim 4, characterized in that the spacers (7) are made of Plastic, in particular essentially made of PE or PU, or made of metal, in particular essentially made of aluminum. Stem device according to one of claims 1 to 5,
characterized in that the cover (4) consists of plates, a film, a coated fabric or a coated fiber fleece. Stem device according to one of claims 1 to 6,
characterized in that the cover (4) consists essentially of plastic, in particular PET, or is coated with plastic, in particular PET. Stem device according to one of claims 1 to 7,
characterized in that the front device (1) has at least one vacuum pump (14) arranged inside and/or outside on the casing (4) and connected to the cavity (13) or possibly the cavities (13) for generating and maintaining a Negative pressure in the cavity (13) or possibly in the cavities (13). Front device according to claim 8, characterized in that the front device (1) has a control which is connected to the vacuum pump (14) and preferably at least one gas pressure sensor arranged in the casing (4), and via which the vacuum pump (14), in particular can be controlled or regulated depending on values measured with the gas pressure sensor. Front device according to claim 8 or 9, characterized in that at least one photovoltaic device (15) is arranged on the front wall (2) of the casing (4), which controls the vacuum pump (14) and possibly the control supplied with energy directly or via an energy storage device (17) connected to the photovoltaic device (15). Stem device according to one of claims 8 to 10,
characterized in that the vacuum pump (14) and possibly the control can be connected to an external energy supply (17), in particular with the energy supply (17) of the building (11), and can be supplied with energy from this energy supply (17). Stem device according to one of claims 1 to 11,
characterized in that it has a suspension (8) or several suspensions (8), which is preferably arranged in the area of an upper end of the front device (1) when the front device (1) is in use and/or on the rear wall (3). are and via which the front device (1) can be hung directly or with the help of a structure (9) or structures (9) provided for this purpose on the outer wall (12) of the building (11), so that the rear wall (3) of the front device (1) can be arranged directly or at a distance from the building (11). Stem device according to one of claims 1 to 12,
characterized in that the front wall (4) and/or the rear wall (3) has/have a thickness (S) of <= 15 mm, in particular <= 10 mm, preferably <= 5 mm. Stem device according to one of claims 1 to 13,
characterized in that the distance (A) between the front wall (4) and the rear wall (3) is at least 10 mm, preferably at least 30 mm, in particular at least 50 mm. Stem device according to one of claims 1 to 14, characterized in that the distance (A) between the front wall (4) and the rear wall (3) is a maximum of 300 mm, preferably a maximum of 200 mm, in particular a maximum of 100 mm.

Images