EP3056828A1 - System floor with ventilation device - Google Patents

Abstract

System floor (1) for buildings, comprising a frame construction (2) and at least one floor panel (3). The bottom plate (3) is supported by the frame structure (2), and the frame structure (2) is at least partially hollow and thereby comprises a cavity (5). The system floor (1) also comprises a ventilation device (6) for supplying supply air into the building, the system floor (1) comprising an air-permeable ventilation connection (7) between the cavity (5) and the ventilation device (6). The ventilation connection (7) is designed to supply the ventilation device (6) with supply air from the cavity (5). The ventilation device (6) can optionally be hermetically sealed with a lid (10). The cover (10) can be designed, for example, to be movable with an adjusting device (11) relative to the base plate (3).

Description

The invention relates to the field of system floor for buildings comprising at least one floor panel and a frame structure supporting the floor panel.

Such a system floor, for example, is already off US 2007 245 642 known. It describes a system floor which comprises a multi-layer floor panel, a frame construction which at least partially surrounds the multi-layer floor panel, and at least one ground anchor for anchoring the frame construction in the floor.

System floors can be built quickly and inexpensively and are suitable, among other things for extensions and / or additional buildings. System floors can be used, for example, for winter gardens, greenhouses, greenhouses, garden sheds, tool sheds, storage buildings and huts.

Buildings with such system floors are therefore often at least partially freestanding, mainly freestanding (with only one wall adjacent to another building) or completely freestanding. Interiors of buildings with such known system floors have the disadvantage that they can be subject to high temperature fluctuations.

With temperature fluctuations, temporal variations in the temperature of the interiors may be meant. Temperature fluctuations may also include temperature differences between the interior of the building and a room adjoining the building or the outside environment, for example between the interior of a free-standing building and the outside air surrounding the building.

High temperature fluctuations are typically caused by weather conditions and may be exacerbated by exposure to parts of the building or the whole building exposed to the weather. Also design-related factors can increase the high temperature fluctuations, such as a high glass content in walls and / or ceilings and / or low heat insulation. Especially in the case of extensions or free-standing additional buildings high glass content and / or low heat insulation are widely used.

With high glass content is meant a high proportion of permeable to solar radiation material. Due to the high proportion of glass, solar radiation can heat the interior of the building directly or indirectly, and heat can escape the interior in the dark outside the building by heat radiation to the outside.

Depending on the design and / or use of a building with such a system floor and a supply of fresh air in the interior of the building is not always easy and / or associated with effort.

Frequently, airing by manually opening and manually closing a window is necessary in a time and space adapted to the circumstances and weather conditions. Such ventilation is complex. An intake air volume is difficult to dose. Depending on the weather, rain, snow, dust, leaves or other material in the Enter interior spaces. Insects, spiders, birds and other animals can also enter the interior.

In order to counteract the variations in temperature and / or to improve the supply of fresh air, various complex solutions are proposed in the prior art in addition to the manual opening and closing of a window. For example, underbody vents are built with ducts and ducts and corresponding air outlets, such as out DE 24 07 448 known. These are expensive construction measures, which are associated with high costs and a complicated construction and appropriate Pannenanfälligkeit with a high space requirement and possibly associated loss of interior space.

Also, various types of opening and closing mechanisms for windows or other vents are known. However, these in turn require windows or other ventilation openings, which does not always have to be the case with all buildings with system floor. Such opening and closing mechanisms are positioned on these components, which requires space there, can be aesthetically undesirable and can cause a corresponding wiring there in electrical operation. The known opening and closing mechanisms usually have a complicated construction and / or complex control, are therefore puncture and failure prone, have high wear and are expensive to manufacture, maintain and maintain.

It is therefore an object of the invention to provide a system floor of the type mentioned, which at least partially solves at least one of the above-mentioned disadvantages.

The inventive system floor for buildings comprises a frame construction and at least one base plate. Here is the bottom plate of the Frame construction supported. The frame construction is at least partially hollow and thereby comprises a cavity. The system floor also includes a ventilation device for supplying supply air into the building. The system floor also includes an air-permeable ventilation connection between the cavity of the frame structure and the ventilation device. The ventilation connection is designed to supply the ventilation device with supply air from the cavity.

The inventive system floor is in particular a system floor for a conservatory.

By frame construction is meant a construction which forms a frame. Individual frame elements can be assembled to form a complete frame construction. The frame construction is at least partially hollow, whereby a cavity is formed. The cavity may for example be formed in one or more individual frame elements. The cavity may also be formed in the entire frame construction. The cavity may comprise a plurality of small interconnected cavities.

A cavity is understood to be a space whose points of space are essentially surrounded by the frame construction. A point in space is essentially surrounded by the frame construction when the frame construction covers at least 50% of the full solid angle of that point in space. In particular, substantially surrounded by the frame construction means covering at least 70% of the full solid angle. Surrounded by the frame construction can also cover at least 85% of the full solid angle. The cavity can therefore only be partially surrounded by the frame construction.

The cavity has at least one for gases and in particular for air passable opening to the outside. By gas is meant in the context of this application, a gas, a gas mixture and / or air. Conversely, everywhere in this application called air always generally gas and / or a gas mixture meant. The cavity can therefore be in gas exchange with a space outside the frame construction. An example of such a space lying outside the frame construction is a space enclosed by the ventilation device. In this case, at least a part of this opening of the cavity forms the ventilation connection with the ventilation device. Another example of such a space lying outside the frame construction is a space lying below the frame construction or the outside environment of the system floor or of the building.

The frame construction may be at least partially permeable to air in terms of its cavity. This means that the cavity of the frame construction can be in air exchange with the environment of the frame construction. In particular, the cavity of the frame structure may be directly or indirectly in air exchange with the environment of the system floor or the building. For example, the air exchange with the cavity through gaps, slots and holes, which arise during assembly and manufacture of the frame structure and are not sealed.

The ventilation device comprises a ventilation cavity, which is designed to be able to supply supply air into the building with the system floor. The supply air is supplied from the ventilation device through a plane in the building, this level includes the bottom top. The ventilation cavity is viewed in the direction of gravity (ie in a projection on the floor plan of the building) together with the bottom plate within a limited by the frame construction bottom area of the building.

In particular, the ventilation cavity is arranged in the direction of gravity next to the frame construction.

The ventilation device may comprise walls. However, the ventilation device may also comprise, for example, a ventilation cavity which is bounded by walls, wherein the walls are not covered by the ventilation device. For example, a suitable for supplying supply air hole in the bottom plate may be referred to as a ventilation device, since this bore forms a ventilation cavity, the walls of which are in turn formed and covered by the bottom plate.

The gas exchange or the air exchange can take place unidirectionally in one direction or unidirectionally in the other direction or bidirectionally in both directions. A temporal change between unidirectional in one and / or the other direction and / or bidirectional is possible.

The system floor comprises at least one floor slab. The system floor may also include two or more floor panels supported by the frame structure.

The bottom plate is supported by the frame construction and is thus supported exclusively by the frame construction. The entire weight of the floor panel and weight acting on the floor panel is supported by the frame structure. In other words, the bottom plate is supported on the frame structure.

The frame construction may be formed as the bottom plate at least partially encircling frame construction. The frame construction can also completely revolve the bottom plate.

The ventilation device is used to supply supply air into the building. By supplying supply air into the building, temperature fluctuations can be compensated. The supply of supply air can be used for a supply of fresh air.

The supply of supply air is passive, ie free of active movement of supply air through the ventilation device. The supply air is moved by pressure differences, density differences and / or temperature differences between the cavity of the frame construction, the ventilation device, the interior of the building with the system floor and the environment of the building. In other words, the supply of supply air by convection occurs.

Alternatively, an active movement of the supply air can take place. Active movement may be by a drive, such as by an air pump or a fan. The drive can be encompassed by the system floor and in particular by the ventilation device and / or the frame construction. The drive can also be arranged outside the system floor.

The ventilation connection is designed to supply the ventilation device with supply air from the cavity. The supply air should therefore reach the ventilation device from the cavity. From the ventilation device, the supply air can then enter the building. Thus, supply air from the cavity through the ventilation device can enter the building, more precisely in the interior of the building.

For example, air may enter the cavity of the system floor from the surroundings of the frame construction and, in particular, from the environment of the system floor or the building, through cracks, gaps, slots, holes and / or other openings in the frame construction. Then the air can be used as supply air from the Cavity of the system floor through the ventilation device in the building and more precisely in the interior of the building.

The advantage of the system floor described is that the supply of supply air can counteract the temperature fluctuations and / or supply the building with fresh air, and that the ventilation device can be easily constructed. The ventilation device uses a part of the frame structure, namely the cavity, and can thereby be made compact. The production, maintenance and repair of the system floor is inexpensive and fast. Also, such a device for the supply of supply air requires no specially designated windows or hatches and can be arranged to save space and aesthetics.

Depending on the weather conditions, construction and material of the system floor and the building, the air in the cavity, which can then enter the building as supply air through the ventilation device, compared to the air in the building be cooler and / or dry. Or the air in the cavity may be warmer and / or wetter.

Weather-related factors include intensity of direct or indirect solar radiation, ambient temperature, wind force, humidity, rain and evaporative coldness. Design-related factors are, for example, the position of the system floor and the frame construction with respect to the ground (directly positioned and / or spaced), material and color and extent of thermal insulation of the frame construction and the building, measure and shape of exposure of the system floor and the floor Building of the weather opposite and glass part of the building (walls and or ceiling).

For example, in the case of a winter garden, a frame construction of the system floor made of metal and therefore highly thermally conductive is arranged near the floor, In summer, in warm weather (ie with warm outside air and cooler ground), the air in the cavity, which then can enter the building as supply air through the ventilation device, compared to the air in the conservatory be cooler and / or drier. The air in the cavity may also be warmer and / or wetter, such as in cold weather and / or in winter. By supplying this, for example, in the summer drier and cooler air into the conservatory, the conservatory can be ventilated, so be supplied with fresh air. The conservatory can also be dehumidified. The conservatory can also be cooled. Conversely, under appropriate circumstances it is also possible to moisten, warm and / or ventilate the conservatory.

The system floor and in particular the frame construction and / or the ventilation device can be designed in such a way that although gas can enter the building, penetration of other elements is prevented. Since the frame construction and thus also the cavity serves as the floor of the building and is thus arranged below the interior, a penetration of snow, rain, hail and / or other foreign objects such as dust and / or leaves is difficult, if not completely prevented, by design , Constructive measures such as grids, screens, nets, filters, curvatures in the cavity and / or arrangement and orientation of the cavity and its openings against the outside can additionally reinforce this effect. Also, intrusion of insects, spiders, birds and other animals in the interior can be difficult and / or prevented.

As an optional feature, the vent is flush with a bottom top of the bottom panel.

The bottom top of the bottom plate refers to that side of the bottom plate, which is facing the interior of the building and thus limits the interior.

Aligned flush with the bottom plate, the venting device is when the venting device abuts a plane that includes the bottom top, and does not project upwardly beyond. In other words, the ventilation device is sunk or recessed in the bottom plate. This has the advantage that the ventilation device does not require an interior of the building. The ventilation device forms in this way with the bottom top a plane. Also, a risk of tripping and injury is low. A cleaning of the ventilation device surrounding the bottom top can be done easily and efficiently.

By above or above is meant a position in the direction of gravity upstream, with below or below a position in the direction of gravity downstream. A lateral offset (transverse to the direction of gravity) does not matter.

Alternatively, however, the ventilation device may also protrude upward above the floor top into the interior of the building and thus into the building. However, the ventilation device can also be arranged below the level comprising the bottom top.

As a further optional feature, the ventilation device is applied to the frame construction.

In this way, the ventilation device can be arranged on the edge of the bottom plate. This saves space and allows the formation of a large contiguous floor top with as few interruptions. In addition, a distance between the cavity and ventilation device may be low, which allows a rapid supply of supply air from the cavity into the ventilation device with little resistance.

The ventilation device can also be arranged away from the frame construction. In this case, the ventilation connection may be formed, for example, as a channel or hose and bridge a distance between the ventilation device and the frame structure.

Optionally, the system floor has a cover for the ventilation device. The lid allows a dosage of supply air.

The lid may for example be arranged in a first position flush with the bottom top and form a flat surface together with the bottom top in this first position. The advantages described above of a flat surface and flush arrangement to the bottom top also apply to the lid in this arrangement.

The lid can be gas-tight and thus airtight. The fact that the lid is gas-tight offers the advantage that the ventilation device can also be closed gas-tight by the lid. In the context of this application, a ventilation device closed in a gas-tight manner by the cover means that the cover closes off the ventilation device in a gastight manner with respect to the interior of the building. For example, the ventilation device may be closed by the gas-tight lid when the lid is arranged flush with the bottom top.

The metering of the supply air quantity can take place in that on the one hand the cover closes the ventilation device and no supply of supply air allowed (as by being attached to the ventilation device) or on the other hand, the ventilation device is open and supply of supply air takes place (such as the cover of the ventilation device is arranged away). This switching on and off the supply of supply air is also referred to as dosing.

The dosage can also be done in smaller steps, for example, by partially covering or closing the ventilation device. The cover may also be formed at least partially permeable to gas. For example, the lid can thus be provided with ventilation slots and / or comprise a ventilation grille. The cover may also be designed to be variable gas-permeable, for example with mutually displaceable elements, which varies a size of the opening in the lid.

The system floor may include an adjustment mechanism for the lid, which is designed for a targeted metering of the supply air through the ventilation device in the building.

The adjusting mechanism can, for example, adjust the lid by the dosage described above in smaller steps. The adjusting mechanism can thus selectively increase or decrease an opening between the cover and the ventilation device in order to dose the supply air volume. The adjustment mechanism can, for example, also deliberately enlarge or reduce an opening in the cover in order to meter the supply air quantity.

A targeted dosage allows a simple and targeted supply of a certain supply air. This has the advantage that, for example, manual ventilation does not have to be monitored in order to close this window again after the desired amount of fresh air has been supplied through approximately one window. A targeted metering of a desired and / or required supply air quantity can provide a supply of supply air over a long period of time, which makes monitoring unnecessary as with manual airing.

The adjustment mechanism can be designed manually adjustable. In other words, the adjusting mechanism can be designed to be free from a drive. The adjustment mechanism can optionally but also include a drive and for example, comprise an adjusting motor. The adjustment mechanism is in particular controllably adjustable and, in other words, can operate semi-automatically and / or automatically. For example, the adjusting mechanism can be regulated by at least one thermostat. The thermostat, for example, mechanically and / or electronically control to a desired temperature.

The adjusting mechanism can be designed such that the cover can be moved for a change in the supply air quantity relative to the bottom top side of the bottom plate. In particular, the adjustment mechanism can move the cover for a change in the supply air quantity perpendicular to the bottom top of the bottom plate.

A relative movement of the cover to the bottom top makes it possible to form the cover gas-tight and thus to close the ventilation device in a position of the lid in a gastight manner. However, the lid by the relative movement to the bottom top but - in a different than the gas-tight closing position - yet targeted and metered supply air.

The adjustment mechanism optionally includes gas springs. Gas springs have the advantage of allowing controlled guided movements, which may also be damped. Gas springs are compact and take up little space.

The adjusting mechanism optionally includes a closing position of the lid, which is designed for airtight closing of the ventilation device. In particular, the lid is aligned in the closed position flush with the bottom top of the bottom plate.

A perpendicular to the bottom top movement of the lid allows a rapid and efficient variation of a distance between the lid and bottom top and thus the supply air.

The movement of the lid relative to the bottom top can be done translationally, rotationally and / or in a mixture of rotation and translation. The movement can be up, down and / or on one side. For example, the lid can be moved translationally perpendicular to the bottom top. The lid can also be pivoted about an axis.

In particular, the cover can be moved translationally in a direction parallel to the bottom top oriented orientation perpendicular to the bottom top.

In other words, the lid can be moved vertically relative to the bottom top between different positions in which the lid is arranged parallel to the bottom top of the bottom plate. A parallel position of the lid increases the safety of the ventilation device, in particular because the lid can regularly protrude beyond the bottom top and thus less cause tripping over than, for example, an angled lid, which projects obliquely and irregularly far beyond the bottom side.

The system floor can also be designed without an adjustment mechanism for the lid.

As an optional feature, the ventilation device is box-shaped.

A box-shaped ventilation device can be easily and inexpensively manufactured. A box-shaped ventilation device can be arranged in a corner of a bottom plate.

The ventilation device may also have a different shape than a box shape. For example, the ventilation device may be tubular.

In particular, the ventilation device is embedded in the bottom plate. A ventilation device embedded in the bottom plate may have the same advantages (described above) as a ventilation device aligned flush with the bottom plate.

In particular, the ventilation device is embedded in the closed and / or open state in the bottom plate. The ventilation device may protrude (especially for a certain amount of supply air) on the bottom top. But the ventilation device may also protrude (especially for a certain supply air volume) on the underside of the bottom plate.

As a further optional feature, the system floor comprises an inlet device. The inlet device comprises an inlet connection with the cavity of the frame construction, wherein the inlet connection is permeable to air and the inlet device is used to supply air to the cavity of the frame construction and the ventilation device.

The inlet device can selectively introduce air into the cavity from a specific point of the system floor. In this way, air with desired properties can be introduced into the frame construction and into the cavity. For example, an inlet device for introducing air from the environment of the building, in particular air from the ground, be formed.

The system floor can also be formed free of an inlet device.

The inlet connection may be disposed on another side of the frame structure than the ventilation connection.

In this way, the air in the cavity between the inlet connection and the ventilation connection must pass a predetermined path of a certain length. If the inlet connection and the ventilation connection are far apart, the air from the inlet device to the ventilation device passes a long way in the cavity or in the frame construction. This can be used, for example, to achieve a cooling and / or drying effect on the air when, for example, the frame construction is cooler than the air in the cavity. The air can also be heated by the frame construction on its way from the inlet connection to the ventilation connection. For example, the air can also be filtered in this way.

However, the inlet connection can also be arranged on the same side of the frame construction as the ventilation connection.

As an optional feature, a foreign body protection device such as a mosquito net is disposed on and / or in the lumen, the ventilation device, the inlet device, the ventilation connection and / or the inlet connection. The constructive measures against the penetration of foreign bodies described above are referred to as foreign body protection device. The foreign body protection devices may thus be formed as grids, screens, nets, filters, curvatures in the cavity and / or arrangement and alignment of the cavity and its openings against the outside. The curvatures, arrangement, orientation and openings of the cavity may be analogously formed in the ventilation device, the inlet device, the ventilation connection and / or the inlet connection.

For example, a mounting kit comprising the ventilation device can be made available. This mounting kit can on the one hand in a new building with a system floor and on the other hand in a already existing buildings with system floor can be used. The mounting kit can be used approximately in an opening recessed in the bottom area.

Optionally, bottom plate of the system floor is designed as a layer plate with several parallel layers.

The bottom plate may therefore comprise a plurality of parallel layers. Such a bottom plate may be referred to as a sandwich plate. The parallel layers may have different material properties from each other. For example, a layer may have good thermal insulation. A layer can have a high scratch and abrasion resistance. A layer may have an aesthetically pleasing surface. A layer can be stable and transmit high forces.

The bottom plate may consist of individual layers or layers. These layers or layers can be brought together, for example, from several individual parts only in the frame construction to the layer or layer. The layers or layers can also be joined together to form a bottom plate before the bottom plate is installed in the frame construction.

The multi-layer floor slab may have a variety of different combinations of material properties and manifestations of other factors such as weight, cost, longevity, environmental compatibility, toxicity and allergy neutrality. A base plate with several layers can meet the specific requirements of the system floor in a simple manner by appropriate targeted design.

In an optional embodiment of the system floor, an isolation distance is formed between the frame construction and the floor top. In particular, the isolation distance comprises an insulation material.

By insulation is meant thermal isolation.

In other words, an insulation strip may be arranged between the bottom top side and the frame construction. The insulation strip may comprise air and / or insulation material. The insulation strip may comprise the ventilation device. The venting device may form part of the insulating strip, for example, when the venting device is disposed between the bottom top and the frame structure.

The insulation distance may be formed over an entire thickness of the bottom plate between the frame structure and the bottom plate. In other words, the bottom plate can only rest in the direction of gravity on the frame construction, and the bottom plate at least partially circumferential parts of the frame structure can be spaced with the isolation distance from the bottom plate.

The system floor can also be designed free of an insulation distance.

As another optional feature, the frame construction is designed as a structural support for the building. In particular, the frame construction is designed as a load-bearing construction for building walls.

The frame construction may be formed circumferentially around the bottom plate. The frame construction may also be formed only partially circumferential the bottom plate. The latter is useful, for example, if the building is not freestanding.

In particular, the frame construction is designed as a load-bearing construction for building walls which have a high proportion of glass. The Building walls can be supported directly on the frame construction. For example, the frame construction can be designed as a load-bearing construction for glass walls and / or glazed walls.

A stable load-bearing frame construction can be easily and inexpensively manufactured, repaired and maintained. In particular, for building walls with high glass content, which require high strength and stability, so that the glass remains free of high pressure and no damage or even destroyed, appropriate stable supporting frame structures are easy and inexpensive to manufacture, repairable and maintainable.

In particular, the frame structure may include frame profiles. For example, a frame profile may be formed as a hollow profile.

Frame profiles can be used as a cheap and readily available part of frame structures. Frame profiles are manufactured and offered in a variety of embodiments (material, dimensions, properties) and sometimes in large quantities. In particular, the frame profiles can be made of drawn metal.

The frame construction can also be designed free of frame profiles. For example, individual bars and plates can be assembled into a frame construction.

Optionally, the system floor comprises anchoring elements for anchoring the system floor in the floor.

As anchoring elements for anchoring the system floor in the ground, for example, ground anchors, screws, threaded rods and / or posts can be used become. The anchoring elements can be attached directly to the frame construction.

In particular, the system floor comprises floor anchors, the frame structure being anchored by the floor anchors in the floor.
The ground anchors have anchoring elements which hold the ground anchor in the ground, for example in the ground, essentially by means of positive engagement.

Since ground anchors can be rammed into a floor and / or screwed in, can be dispensed with a previous excavation completely or largely. Another advantage of using ground anchors is that these ground anchors do not require potting compound, such as concrete, cement, etc. Casting compounds require a certain dehydration time or curing time. This time can be saved. In addition, conventional potting compounds such as mortar usually based on water and possibly other binders, which are usable only in a certain temperature range. For example, concreting or use of mortar and / or resins at temperatures below zero degrees Celsius is not or only insufficiently possible. Thanks to its use with ground anchors, the system floor can be anchored in any weather, especially permafrost.

By soil is meant in particular a soft and / or loose ground, such as soil. But ground can also mean a hard ground, such as rocky ground or, for example, a (hard) foundation in soft and / or loose ground.

Figur 1

einen Querschnitt durch einen Teil eines Systembodens;

Figur 2

einen Längsschnitt durch einen Teil des Systembodens aus Figur 1.

In the following, the subject invention will be explained in more detail with reference to a preferred embodiment, which is illustrated in the accompanying drawings. Show it:

FIG. 1

a cross section through a part of a system floor;

FIG. 2

a longitudinal section through a part of the system floor FIG. 1 ,

Basically, the same parts are provided with the same reference numerals in the figures.

The FIGS. 1 and 2 show the same embodiment of a system floor according to the invention 1. Both FIG. 1 as well as FIG. 2 show the lid 10 in a first position (closing position S) in which the ventilation device 6 is closed and does not allow supply of supply air, and in a second position in which the ventilation device 6 is open and allows supply of supply air. By adjusting between these two positions, the supply air volume can be dosed. So there are two covers 10 for better understanding of the system floor 1, although the in the FIGS. 1 and 2 illustrated system base 1 comprises a ventilation device 6 with only one cover 10. For clarity, is also in FIG. 1 the adjusting mechanism 11 for the cover 10 is shown only for the closing position S, but not for the second position of the lid 10. In FIG. 2 is shown for both positions of the lid 10 of the corresponding adjustment mechanism 11.

In FIG. 1 a cross section through a part of the system bottom 1 is shown. The frame bottom 2 comprises a frame profile, a bottom bracket 16 and a base plate 17. The frame profile is formed as a hollow profile 15, is made of metal and has a rectangular cross section with external dimensions of 7.5 cm times 15 cm up. The cavity 5 is formed in the hollow profile 15.

The hollow profile 15 is rigidly connected to the bottom bracket 16 formed as an angle and with the base plate 17. The bottom bracket 16 and the base plate 17 are also made of metal. The base plate 17 is below the hollow profile 15 arranged and projects laterally (ie transversely to the direction of gravity G) on both sides over the hollow section 15 also. The bottom bracket 16 is attached laterally to the hollow profile 15 and is aligned against the interior of the building so that the bottom plate 3 and / or the ventilation device 6 can at least partially rest on the bottom bracket 16. In FIG. 1 the ventilation device 6 is partially on the bottom bracket 16 and thus on the frame structure 2.

The ventilation device 6 forms in FIG. 1 an insulation distance between the frame structure 2 and the bottom plate 3 and thus also between the frame construction 2 and the bottom top 4 of the bottom plate 3 from. At other locations of the system floor 1, the bottom plate 3 and the bottom top 4 are also arranged with an isolation distance to the frame structure 2, wherein the insulation distance is filled with insulation material. The bottom plate 3 comprises in FIG. 1 six separate parallel layers, which are arranged stacked in the direction of gravity G. Two of the six separate layers have the same material properties and the same thickness, all other layers differ in material properties and thickness. The overhead side of the bottom plate 3 is referred to as bottom top 4.

The system base 1 also includes a plurality of anchoring elements, which are designed as ground anchors 20. Of the anchoring elements is in FIG. 1 only a ground anchor 20 is shown. The ground anchor 20 is here designed as a ground anchor, which is conical at its lower end and ends at the bottom in a tip. The ground anchor 20 has a spirally extending anchoring element, which can be screwed into the ground like a screw jack, thereby securing the ground anchor 20 in the ground. After the ground anchor 20 is fixed in the ground, the ground anchor 20 is fastened to the base plate 17 by means of screws from below. In this way, the frame construction 2 is assembled on site.

On the base plate 17, the building wall 21 supports from above, so that the building wall 21 laterally adjacent to the hollow section 15 comes to rest, on one of the bottom bracket 16 opposite side of the hollow section 15. The frame structure 2 is designed as a supporting structure, so is the supporting structure for the slab floor 3 and other elements of the building (such as building walls and building roof). On the upper side of the hollow section 15 are in FIG. 1 Brackets and guide rails for sliding doors shown. In the present exemplary embodiment, the frame construction 2 is partially encircling the base plate 3: as a conservatory with a rectangular plan, three sides of the rectangular base plate 3 are peripherally surrounded by the frame structure 2 and the remaining side of the base plate 3 adjoins the wall of the house ,

The ventilation device 6 is arranged between the frame construction 2 and the bottom plate 3. The ventilation device 6 is partially on the ground bracket 16 and adjacent to the side of the hollow section 15. The ventilation device 6 is box-shaped and comprises the ventilation cavity 8. The cover 10 has the same surface finish as the bottom top 4 of the bottom plate 3 and is arranged in the closed position S flush with the bottom top 4. In this way, the ventilation device 6 in the closed position S with the lid 10 can be hermetically sealed from above, and the bottom top 4 is together with the lid 10 in the same plane and has the same visual appearance. The ventilation device 6 and the cover 10 are embedded in the closed position S so in the bottom plate 3 and sunk. The lid 10 is rectangular and has side lengths of about 30cm and 60cm.

Between the cavity 5 in the hollow section 15 and the ventilation cavity 8 of the voltage applied to the hollow section 15 ventilation device 6 is an air-permeable opening formed, which as a ventilation connection 7 allows a supply of the ventilation cavity 8 and thus also the ventilation device 6 with supply air from the cavity 5. In FIG. 1 If the cutting plane runs past the ventilation connection 7, and where the ventilation connection 7 lies at another point of the frame construction 2, is in FIG. 1 to see a part of the ground support 16. The ventilation device 6 has against the bottom and side (except for the ventilation connection 7) walls made of foamed PVC with good thermal insulating properties. At the upper ends of inner sides of these walls of the ventilation device 6, an adjusting device 11 for the cover 10 is attached.

The adjustment device 11 allows an adjustment of the lid 10 of the ventilation device 6 airtight closing position S to adjust to a second position. In the second position of the lid 10, which is also in FIG. 1 is shown, the ventilation device 6 supply fresh air. In both positions and also in between the cover 10 is guided by the adjusting device 11 parallel to the bottom top 4. The guided by the adjusting device 11 movement of the lid 10 is perpendicular to the bottom top 4. The adjusting device 11 engages the lid 10 on the ventilation device 6 side facing by angular adjustment brackets.

FIG. 2 shows a longitudinal section through a part of the system floor 1 FIG. 1 , More specifically shows FIG. 2 a longitudinal section through the ventilation device 6, the adjusting device 11 and the cover 10 of the system base 1 from FIG. 1 , The adjustment mechanism 11 can be seen better in this view. Between the ventilation device 6 and the cover 10 and the cover 10 fixed angle Verstellhalterungen gas springs are arranged. The gas springs are length-adjustable elements, which the cover 10 by the adjustment mechanism 11 in the closed position S or in the second position (in which the upwardly pointing into the interior of the building opening of the Ventilation device 6 is open) holds. The gas springs and thus the adjusting mechanism 11 may be adjusted such that the cover 10 also positions between the in FIGS. 1 and 2 Positions taken can be taken. By adjusting between these intermediate positions, the supply air quantity can be selectively metered in small steps.

Claims (15)

System floor (1) for buildings, in particular for a conservatory, comprising a frame construction (2) and at least one floor panel (3), the floor panel (3) being supported by the frame structure (2) and the frame construction (2) being at least partially hollow and thereby comprises a cavity (5),
characterized in that
the system floor (1) comprises a ventilation device (6) for supplying supply air into the building, the system floor (1) having an air-permeable ventilation connection (7) between the cavity (5) of the frame construction (2) and the ventilation device (6) comprises and the ventilation connection (7) for supplying the ventilation device (6) with supply air from the cavity (5) is formed. System floor (1) according to claim 1, characterized in that the ventilation device (6) is aligned flush with a bottom top (4) of the bottom plate (3). System floor (1) according to claim 1 or 2, characterized in that the ventilation device (6) rests against the frame construction (2). System floor (1) one of claims 1 to 3, characterized in that the system base (1) comprises a cover (10) for the ventilation device (6), which allows a dosage of the supply air. System floor (1) according to claim 4, characterized in that the system base (1) comprises an adjusting mechanism (11) for the cover (10), which is designed for a targeted metering of the supply air through the ventilation device (6) in the building. System base (1) according to claim 5, characterized in that the adjusting mechanism (11) is designed such that the cover (10) for a change in the supply air quantity relative to the bottom top (4) of the bottom plate (3) can be moved and in particular perpendicular to Bottom top (4) of the bottom plate (3) can be moved. System floor (1) according to one of claims 5 to 6, characterized in that the adjusting mechanism (11) comprises a closing position (S) of the lid (10), which is designed for airtight closing of the ventilation device (6), wherein in particular the lid ( 10) in the closed position (S) is aligned flush with the bottom top (4) of the bottom plate (3). System floor (1) according to one of claims 1 to 7, characterized in that the ventilation device (6) is box-shaped and in particular in the bottom plate (3) is embedded. System floor (1) according to one of claims 1 to 8, characterized in that the system floor (1) comprises an inlet device which comprises an inlet connection with the cavity (5) of the frame construction (2), the inlet connection being permeable to air and the Inlet device of supplying the cavity (5) of the frame structure (2) with air. System floor (1) according to claim 9, characterized in that the inlet connection is arranged on another side of the frame construction (2) than the ventilation connection (7). System floor (1) according to one of claims 1 to 10, characterized in that the bottom plate (3) is designed as a layer plate having a plurality of parallel layers. System floor (1) according to one of claims 1 to 11, characterized in that between the frame construction (2) and the bottom top (4) of the bottom plate (3) an insulation distance is formed, which in particular comprises an insulating material. System floor (1) according to one of claims 1 to 12, characterized in that the frame construction (2) is designed as a supporting structure for the building, in particular as a load-bearing construction for building walls. System floor (1) according to one of claims 1 to 13, characterized in that the frame construction (2) comprises frame profiles. System floor (1) according to one of claims 1 to 14, characterized in that the system floor (1) comprises anchoring elements for anchoring the system floor (1) in the floor.

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