EP4343075A1 - Base profile - Google Patents

Abstract

The invention relates to a base base profile (10), comprising a wall leg (12) for fastening the base base profile (10) to a wall (150), with a support leg (20) oriented transversely to the wall leg (12) extending to the wall leg (12). , wherein the support leg (20) has a support leg length (L) and a support leg height (H), the support leg (20) being dimensioned such that it has a ratio of support leg height (H) to support leg length (L) that is less than 0 ,1 is. The invention is characterized in that the support leg (20) has an upper wall (22) and a lower wall (24), the upper wall (22) and the lower wall (24) having a plurality of connecting webs (26). are connected to each other, the wall thickness (S _O ) of the upper wall (22) as well as the wall thickness (S _U ) of the lower wall (24), over more than ¾ of the support leg length (L), less than a quarter of the support leg height (H ) of the support leg (20).

Description

The invention relates to a base base profile according to the preamble of claim 1.

From the DE 20 2013100 503 U1 a generic base profile - end profile - is known, which functions in particular as a base base profile at the lower edge of an insulation board layer on a building wall. The base profile has an L-shaped profile with a wall leg and a support leg, which extends essentially transversely to the wall leg and contributes to the support of insulation panels for wall insulation.

The invention is based on the knowledge that the base base profile contributes to the dissipation of heat from the building.

Consequently, it is the object of the invention to improve thermal insulation.

The task is solved by the characterizing features of claim 1 in conjunction with its generic features.

The subclaims form advantageous developments of the invention.

In a known manner, a base base profile comprises a wall leg for fastening the base base profile to a wall, with a support leg oriented transversely to the wall leg extending from the wall leg. The support leg extends over a support leg length. This is determined from the back of the wall leg to the free end of the support leg.

The support leg has a support leg height, with the ratio of support leg height to support leg length being less than 0.1.

According to the invention, the support leg has an upper wall and a lower wall, the upper wall and the lower wall being connected to one another via a plurality of connecting webs. Furthermore, the wall thickness of the upper wall as well as the wall thickness of the lower wall, over a range of more than 3/4 of the support leg length, are less than a quarter of the support leg height.

Due to the small wall thickness of the upper and lower walls, heat dissipation is inhibited and the insulating effect of the base base profile is improved compared to a support leg made of solid material, since in particular the stagnant air layers that arise between the connecting webs and the upper and lower walls inhibit the heat dissipation. Thanks to the connecting webs, despite the small wall thicknesses of the upper and lower walls, sufficient rigidity of the support leg can be achieved, which still allows reliable support of the wall insulation.

The fact that at least a large part of the support leg, i.e. more than ¾ of the support leg length, if not almost the entire support leg length, is designed with a small wall thickness of the upper and lower walls has the advantage that the insulation created by the design of the support leg does not easily pass through a plaster layer or an adhesive layer that is applied between the wall insulation or insulation board and the wall can be bridged.

In particular in the event that the base base profile is used between wall insulation and perimeter insulation, the effect of the thermal bridge that arises between the wall and the outside area and that lies between the two insulation sections can be reduced by the base base profile according to the invention. In this way, the overall insulation effect can be improved.

According to a particularly preferred embodiment, the wall thickness of the upper wall and the wall thickness of the lower wall are less than the thickness of the wall leg. The wall thicknesses are preferably each smaller than half the thickness of the wall leg.

The upper and lower walls are preferably connected to one another at least by a side wall, which lies in particular at the free end of the support leg. The free end of the support leg can in particular have a beveled contour in cross section, which has an effect when using a base insertion profile.

A beveled, narrowing contour results in a height offset between the front edge of the support leg and the top of the upper wall. This resulting cavity makes it easier to insert a base insertion profile if wall insulation is in contact with the support leg.

Furthermore, at least one base profile connector can be arranged in the cavity between the upper and lower walls of the support leg, which serves to connect individual base base profile elements to one another on the butt side. The base profile connector can, for example, be arranged on the front side of the base base profile along the support leg length, in particular at the end remote from the wall leg. In this way, the gap can be used at the same time for thermal insulation and for the aligned alignment of profiles plugged together, without the outline contour of the profile being negatively affected by the cavity necessary to accommodate the base connector.

The upper and lower wall thicknesses are preferably in a range from 0.25 mm to 0.75 mm, preferably about 0.5 mm. The connecting bars are similarly dimensioned.

The support leg height is preferably between 3 mm and 7 mm.

The distance between the connecting webs is preferably between 5 mm and 15 mm, in particular 9 mm. In order to prevent the support leg from twisting under tension and ultimately failure of the support leg, the maximum distance between the connecting webs is preferably 15 mm. A distance of 9 mm between the connecting bars has an optimal ratio of load-bearing capacity to reduced heat conduction.

This means that both the thermal insulation effect and the stability of the base base profile can be taken into account.

According to a preferred development, the support leg height, the thickness of the connecting webs and the wall thicknesses of the upper and lower walls are dimensioned such that the cross-sectional area of the support leg consists of more than 40% cavity.

According to a further advantageous embodiment, the wall leg has a fastening area for fastening to a wall. The fastening area is formed in particular by perforations for screwing the base base profile to the wall, which lie in the direction of support of the wall insulation.

The angle between the wall leg and the support leg in the direction of support of the wall insulation is preferably less than 90°.

In a preferred development of the invention, a wedge-shaped transition extends on the wall insulation side from the wall leg, which has the fastening area, to the support leg. This increases the stability of the connection of the support leg and the possible moment load.

The ratio of the leg length of the wedge-shaped transition on the wall leg to the leg length of the wedge-shaped transition on the support leg is approximately 1/3. The angle between the wedge surface and the surface of the support leg is therefore approximately 20°. Through the wedge-shaped transition, the tensile forces from the upper wall, which arise from the support of the insulation, can be introduced into the wall leg. This creates a compensation for the reduced introduction of force in the pressure direction.

The base base profile is formed from an extruded base body made of aluminum or, more preferably, from an extruded base body made of plastic, in particular PVC. Through these manufacturing processes, a base base profile can be produced in a simple manner essentially in one work step, so that only the fastening area of the wall leg, which has the perforations, needs to be reworked. PVC, for example, has the advantage over aluminum in that the thermal insulation is further improved.

The invention further relates to building insulation, comprising perimeter insulation, thermal insulation and a base base profile described above, which is attached to a wall with a wall leg and supports the wall insulation in the direction of gravity via a support leg.

The perimeter insulation is preferably attached in such a way that the support leg of the base base profile lies between the wall insulation and the perimeter insulation.

Such an arrangement with a base base profile according to the invention ensures improved building insulation.

Furthermore, it is conceivable that the wall insulation is made from wall insulation panels. Additionally or alternatively, the perimeter insulation is made from perimeter wall insulation panels.

Further advantages, features and possible applications of the present invention result from the following description in conjunction with the exemplary embodiments shown in the drawings.

Fig. 1

eine perspektivische Ansicht eines Basissockelprofils;

Fig. 2a

eine Seitenansicht eines erfindungsgemäßen Basissockelprofils

Fig. 2b

eine vergrößerte Schnittansicht nach Fig. 2a; und

Fig. 3

eine Schnittansicht eines Basissockelprofils im eingebauten Zustand.

In the drawing means:

Fig. 1

a perspective view of a base base profile;

Fig. 2a

a side view of a base base profile according to the invention

Fig. 2b

an enlarged sectional view Fig. 2a ; and

Fig. 3

a sectional view of a base base profile in the installed state.

Fig. 1 shows a perspective view of a base base profile 10 according to the invention. The base base profile 10 has a wall leg 12 for fastening the base base profile 10 to a wall, not shown here. Starting from the wall leg 12, there is an L-shaped support leg 20 which is aligned transversely to the wall leg 12. The angle that the wall leg 12 forms with the support leg 20 is less than 90°. In this example the angle corresponds to 89°.

The support leg 20 has a support leg length L. This is determined from the back of the wall leg 12 to the free end of the support leg 20.

The support leg 20 is designed in this way in the manner of a thin support plate. The support leg 20 has a support leg height H which is essentially constant over the entire support leg length L, the ratio Q of the support leg height H to the support leg length L being less than 0.1 (Q=H/L <0.1).

The support leg 20 is delimited by an upper wall 22, on which wall insulation rests when the base base profile is installed, and a lower wall 24. According to the invention, the upper wall 22 and the lower wall 24 are connected to one another via a plurality of connecting webs 26, so that a cavity 32 results between the connecting webs 26.

The wall thickness So of the upper wall 22 and the wall thickness Su of the lower wall 24 are less than a quarter of the support leg height H of the support leg 20. An area with a low wall thickness So of the upper wall 22 extends over more than 85% of the support leg length L. A Area with low wall thickness Su of the lower wall 24 extends over the entire support leg length L. In the present exemplary embodiment, the wall thickness So of the upper wall 22 and the wall thickness Su of the lower wall 24 are the same and are 0.5 mm.

Due to the small wall thickness So of the upper wall 22 and the small wall thickness Su of the lower wall 24, heat dissipation is hindered and thus the insulating effect of the base base profile 10 compared to a support leg made of solid material is improved, since the standing air layers that are between the connecting webs 26 and the upper wall 22 and the lower wall 26 in the cavity 32, inhibit the heat flow. Through the connecting webs 26, despite the small wall thicknesses So, Su of the upper and lower walls 22, 24, sufficient rigidity of the support leg 20 can be achieved, so that reliable support of the wall insulation is guaranteed.

In the present exemplary embodiment, the support leg height H, the width Bs of the connecting webs 26 and the wall thicknesses So, Su of the upper and lower walls 22, 24 are dimensioned such that the cross-sectional area of the support leg 20 consists of a little more than 50% of the cavity 32.

The wall thickness So of the upper wall 22 and the wall thickness Su of the lower wall 24 are each less than the thickness Sw of the wall leg 12, in the present case about a quarter.

The upper wall 22 and the lower wall 24 are preferably connected to one another at least by a lateral wall 28a at the free end of the support leg 20 and a lateral wall 28b which lies on the rear side of the wall leg 12, so that a circumferentially completely closed profile is obtained.

In the present case, the side wall 28a at the free end of the support leg 20 is designed with a beveled contour in cross section. This allows a base insertion profile 180, as in Fig. 3 is shown, between the in Fig. 3 Wall insulation 160 shown and the base base profile 10 are introduced.

Furthermore, at least one base profile connector 42 can be arranged between the upper wall 22 and the lower wall 24 of the support leg 20, which serves to connect individual base base profiles 10 to one another on the joint side. The base profile connector 42 can, for example, be arranged on the front side between the upper and lower walls 22, 24 along the support leg length L. The outer contour of the support leg can be formed without disturbing edges due to the already existing receiving space for a base profile connector 42. The position of the base profile connector 42 is also somewhat variable, with an arrangement at the free end of the support leg being preferred.

The distance As between the connecting webs 26 is between 5 mm and 15 mm. This allows both the thermal insulation effect and the stability of the base base profile 10 to be taken into account.

The ratio of support leg height to chamber width As of a cavity 32 is preferably less than 1.

The wall leg 12 has a fastening area for fastening to a wall. This is formed by recesses or perforations 40 for screwing the base base profile 10 to the wall, not shown here.

The L-shaped base base profile 10 has a wedge-shaped transition 30, which extends on the wall insulation side from the wall leg 12 having the fastening area to the Support leg 20 extends. This increases the stability of the connection of the support leg 20 and the possible moment load. The wedge-shaped transition 30 is in Fig. 2b described in more detail.

The base base profile 10 is made in particular from an extruded base body made of PVC. Fig. 2a shows a side view of a base base profile according to the invention Fig. 1 without base profile connector.

Fig. 2b shows a partially enlarged view of the base base profile according to the invention Fig. 2a .

In this cut-out, enlarged representation, the ratios of the wall thickness So of the upper wall 22 and the wall thickness Su of the lower wall 24 to the support leg height H. The ratio of the web distance A _s to the support leg height H is here such that a rectangular contour of the cavity 32 results , the longer side of which lies longitudinally. The ratio of support leg height H to web distance A _s is preferably <1, in particular about 0.5.

In this illustration it can be seen that the transition 30 has a wedge ratio of the leg length at the wall connection to the leg length at the support leg 20 is approximately 1/3. The angle α between the wedge surface and the surface of the support leg 20 is preferably approximately 18°. This allows additional support for the upper wall 22 and thus the entire support leg 20.

Fig. 3 shows a schematic sectional view of a building insulation 100 according to the invention comprising a base base profile 10 according to the invention.

In the installation situation described, the base base profile 10 is inserted between an insulation board 160 of building insulation, which in the present case is attached to a wall 150 via an adhesive layer 190, and a perimeter insulation 170. The base base profile 10 according to the invention can be used to reduce a thermal bridge that arises between the two insulating sections 160, 170 between the wall and the outside area through the base base profile. In this way, the overall insulation effect can be improved compared to a base base profile made of solid material, which dissipates heat from the wall 150 or the adhesive layer 190 towards the outside area.

Since, according to the invention, the upper wall 22 and the lower wall 24 of the support leg 20 are connected to one another via a large number of connecting webs 26, this results in a large number of cavities 32 in which resting air layers are present, so that heat outflow is inhibited, which occurs due to a temperature gradient between the warmer wall 150 or the adhesive layer 190, and the outside area with a cooler outside temperature.

By designing approximately the entire support leg length L with a small wall thickness So, Su of the upper wall 22 and the lower wall 24, the insulation between the outer wall and the adhesive 190, which is attached between the insulation board 160 and the base base profile 10, can be achieved due to the lower thermal conductivity of the base base profile according to the invention 10 cannot be easily bridged.

Claims (10)

Base base profile (10), comprising a wall leg (12) for fastening the base base profile to a wall, a support leg (20) oriented transversely to the wall leg (12) extending to the wall leg (12), the support leg (20) having a support leg length ( L) and has a support leg height (H), the support leg (20) being dimensioned such that it has a ratio of support leg height (H) to support leg length (L) that is less than 0.1, characterized in that the support leg (20) has an upper wall (22) and a lower wall (24), the upper wall (22) and the lower wall (24) being connected to one another via a plurality of connecting webs (26), the wall thickness (So) of the upper wall (22) as well as the wall thickness (Su) of the lower wall (24), over more than ¾ of the support leg length (L), is less than a quarter of the support leg height (H) of the support leg (20). Base base profile according to claim 1, characterized in that the wall thickness (So) of the upper wall (22) and the wall thickness (Su) of the lower wall (24) are less than the wall thickness (Sw) of the wall leg (12). Base base profile according to one of the preceding claims, characterized in that the wall leg (12) has recesses (40) for screwing the base base profile (10) to the wall. Base base profile according to one of the preceding claims, characterized in that between the upper wall (22) and the wall leg (12) there is a transition region (30) which extends from the wall leg (12) along the Support leg (20) extends, its thickness decreasing towards the free end of the support leg (20). Base base profile according to claim 4, characterized in that the transition region (30) is wedge-shaped and its thickness decreases in the direction of the free end of the support leg (20), in particular linearly. Base base profile according to one of the preceding claims, characterized in that the width (Bs) of the connecting webs (26) is each smaller or equal to the thickness of the wall leg (12), in particular thinner than ¼ of the support leg height (H). Base base profile according to one of the preceding claims, characterized in that the base base profile (10) is a one-piece extrusion part, in particular made of PVC. Building insulation (100) comprising perimeter insulation (170), wall insulation (160) and a base base profile (10) according to one of the preceding claims, wherein the base base profile (10) is attached to the wall (150) with the wall leg (12) and the Support leg (20) supports the wall insulation (160) in the direction of gravity. Building insulation (100) according to claim 8, characterized in that the perimeter insulation (170) is attached such that the support leg (20) of the base base profile (10) lies between the wall insulation (160) and the perimeter insulation (170). Building insulation according to one of the preceding claims 8 or 9, characterized in that the wall insulation is formed from wall insulation panels (160) and/or the perimeter insulation (170) is formed from perimeter wall insulation panels.

Images