EP3034744B1 - Slidable wall system - Google Patents

Description

The invention relates to a horizontal sliding wall system, comprising a ceiling guide with at least one running rail and at least one door leaf element, which is connected to a roller carriage, which is arranged displaceably in the ceiling guide.

Sliding wall systems and their door panels are known, for example, in multi-leaf entrance doors, wall sliding elements used as a room divider or wall elements in front areas of buildings, especially in restaurants and shops, to keep the shop open or closed according to the weather. The door leaf elements are usually movably received in ceiling mounted ceiling guides. In this case, the individual wing elements can be parked in a lateral position, so that there is no hindrance to the entering public traffic. Such systems are for example off DE202008002204U1 or DE20003563U1 known.

Due to increasing requirements for energy efficiency in and on buildings, the requirements for thermal insulation of such sliding wall systems are also increasing.

Object of the present invention is to provide an improved thermal separation of a sliding wall system, which in particular can be easily and inexpensively manufactured and which in particular allows easy operation of a rotary sliding sash within a sliding wall system.

This object is achieved by a sliding wall system with the features of claim 1.

The horizontal sliding wall system according to the invention comprises a ceiling guide with at least one running rail and at least one door leaf element, which is connected to a roller carriage, which is slidably disposed in the ceiling guide, wherein at least one door leaf element in the ceiling guide is pivotally and slidably formed as a rotary sliding sash, wherein the Dreh-Schiebeflügel a swing door and a Verrieglungshandhabe, which is designed to be rotatable between a first Verrieglungsstellung and a second Verrieglungsstellung, and a first gear arrangement and a second gear arrangement, wherein the first gear arrangement, the rotational movement of the Verrieglungshandhabe in a vertical, translational movement of a first locking bar and a second locking bar converts, wherein the second gear arrangement with at least one of Locking bars is coupled so that the vertical translational movement of the locking bars is converted into a horizontal movement of a third Verrieglungsstange, the second Verrieglungsstange has at its ceiling, distal end a Verrieglungsbolzen which engages in the first Verrieglungsstellung the Verrieglungshandhabe in a fixed pivot bearing, and the first Verrieglungsstange has at its bottom end a Verrieglungsbolzen, which engages in the first Verrieglungsstellung the Verrieglungshandhabe in a bottom-side stationary pivot bearing so that a rotational movement of the rotary sliding wing around the Verrieglungsstangen effected and a displacement of the door leaf element is prevented, wherein in the second Verrieglungsstellung the Verrieglungshandhabe prevents rotation of the rotary sliding wing around the locking bars and a sliding of the door leaf element is made possible, wherein the third Verri eglungsstange has a coupling means which is in the second Verrieglungsstellung the Verrieglungshandhabe with a corresponding coupling means of the swing door engaged, so that a rotational movement of the rotary sliding wing prevents the locking rods, but a displacement of the door leaf element is enabled. This makes it possible to realize a particularly simple and ergonomically favorable locking or control function on a rotary sliding door within a sliding wall system.

The second gear arrangement comprises at least a first lever and a second lever, wherein the first lever is mounted articulated on the second Verrieglungsstange and is mounted articulated on the second lever, wherein the second lever is slidably received in the horizontal door leaf frame of the door leaf. As a result, a particularly simple and low-friction and thus power-saving for the user use of the lock is possible.

The second lever is coupled to the locking bar. This is favorable in terms of production as well as with regard to the choice of material, since the second lever and the locking rod can be made of different materials.

The third locking bar is slidably guided in the horizontal door leaf frame. This makes it possible in particular to arrange the third Verrieglungsstange within the horizontal profile frame.

In order to further reduce the force required to operate the Verrieglungssystems, the Verrieglungsstange is at least one, preferably two Coupled sliding elements which are slidably received in the horizontal door leaf frame of the door leaf.

Thus, in particular, the thermal separation is not adversely affected by the Verrieglungssystem, the at least one sliding element has a thermal thermal conductivity of 0.1-2 W m-1 K-1, preferably 0.1-1.5 W m-1 K-1, particularly preferably 0.1-1 W m-1 K-1 at 20 ° C determined according to DIN 52612 and a thermal expansion coefficient of 0.1-2, preferably 0.5-1.5, particularly preferably 0.5-1.0 * 10-6 K-1 at 20 ° C measured according to ISO 11359 on ,

A structurally simple as well as secure embodiment of the invention preferably results from the fact that the third Verrieglungsstange has a coupling means which comprises a groove-like receptacle, in which a corresponding coupling means of the swing door can be positively brought into engagement.

Further, it is advantageous that the first Verrieglungsstange and the second Verrieglungsstange are arranged in alignment on a common vertical axis, whereby a uniform pivot axis of the swing door can be realized.

It has proven to be ergonomic particularly favorable and advantageous that the Verrieglungshandhabe is arranged on a vertical frame, the band side.

In order to further improve the reliability of the Verrieglungsmechanik for the horizontal sliding wall system, may be provided in particular that the first Verrieglungsstange is vertically guided in at least one guide and / or that the second Verrieglungsstange is guided vertically in at least one guide.

In order to ensure a simple installation and adjustability of the guide, it is preferred that the guide is arranged detachably within a vertical frame. In this context, it is also particularly preferred that the guide is slidably disposed within the vertical frame. Furthermore, it is particularly advantageous if the guide can be fixed in force and / or in a form-fitting manner within the vertical frame.

In order to further optimize the thermal separation effect of the horizontal sliding wall system, it is particularly preferred that a guide has a thermal thermal conductivity of 0.1-2 W m-1 K-1, preferably 0.1-1.5 W m-1 K-1, particularly preferably 0.1- 1 W m-1 K-1 at 20 ° C determined according to DIN 52612 and a thermal expansion coefficient of 0.1-2, preferably 0.5-1.5, particularly preferably 0.5-1.0 * 10-6 K-1 at 20 ° C measured according to ISO 11359 has.

In a further embodiment of the sliding wall system according to the invention a stationary pivot bearing in the ceiling guide and / or the building ceiling is formed.

Fig. 1

eine schematische, vereinfachte frontale Ansicht eines Schiebewandsystems gemäß der vorliegenden Erfindung;

Fig. 2

eine Querschnittsansicht durch die Deckenführung des Schiebewandsystems

Fig. 3

eine Querschnittsansicht eines vertikalen Türrahmens eines Türflügelelements des Schiebewandsystems

Fig. 4

eine Querschnittsansicht eines horizontalen Türrahmens eines Türflügelelements des Schiebewandsystems

Fig. 5

eine Querschnittsansicht durch die Drainageschiene des Schiebewandsystems

Fig. 6

eine Detailansicht einer in einem Türflügelelement ausgebildeten nutartigen Aufnahme für einen Isoliersteg

Fig. 7

eine Funktionsskizze einer Verrieglung für eine Schiebeschwenktür im Verschiebezustand

Fig. 8

eine Funktionsskizze einer Verrieglung für eine Schiebeschwenktür im Schwenkzustand

The invention will be explained in detail with reference to the accompanying drawings. Showing:

Fig. 1

a schematic, simplified frontal view of a sliding wall system according to the present invention;

Fig. 2

a cross-sectional view through the ceiling guide of the sliding wall system

Fig. 3

a cross-sectional view of a vertical door frame of a door leaf element of the sliding wall system

Fig. 4

a cross-sectional view of a horizontal door frame of a door leaf element of the sliding wall system

Fig. 5

a cross-sectional view through the drainage rail of the sliding wall system

Fig. 6

a detailed view of a formed in a door leaf element groove-like receptacle for a Isoliersteg

Fig. 7

a Funktionsssizizze a Verrieglung for a sliding door in the sliding state

Fig. 8

a Funktionsssizizze a Verrieglung for a sliding swing door in the swivel state

Fig. 1 shows a perspective view of a sliding wall system 100 according to the present invention. The sliding wall system 100 according to the invention comprises a ceiling guide 200 and four door leaf elements 400a, 400, b, 400c, 400d, which are arranged side by side in the longitudinal direction L of the sliding wall system 100 in the ceiling guide 200. The ceiling guide 200, which is formed as a one-piece slide rail 300, has a length which is four times the width of the door leaf elements 400a, 400, b, 400c, 400d. Alternatively, the ceiling guide 200 may be composed of a plurality of ceiling guide elements.

The ceiling guide 200 may be attached directly to the ceiling of the building 201. The method of the door leaf elements 400 can be done manually and / or motor.

In particular, the inventive sliding wall system 100 of Fig. 1 a first door leaf element 400a, a second door leaf element 400b, a third door leaf element 400c, and a fourth door leaf element 400d, which may be provided with certain functions. The second door leaf element 400b and the fourth door leaf element 400d are pivotally arranged, wherein the first door leaf element 400a and the third door leaf element 400c in the ceiling guide 200 can only be displaced. Further, the second door panel 400b is pivotally and slidably disposed in the ceiling guide 200. Thus, the first door leaf element 400a and the third door leaf element 400c serve as sliding sash, the fourth door leaf element 400d as a rotary wing or pendulum wing and the second door leaf element 400b as a rotary sliding sash.

The gap between the door panel members 400a, 400b, 400c, 400d and the ceiling guide 200 or the building floor 101 may vary due to mounting tolerances and / or over time due to frequent use or relative movement as well as thermal expansion or contraction. This gap is optically and thermally sealed by means of horizontally extending brushes 490a, 490b, with the brushes 490a, 490b on the ceiling-side horizontal door leaf frames 410ab, 410bb, 410cb, 410db and / or the bottom horizontal door leaf frames 410aa, 410ba, 410ca, 410da of the door leaf elements 400a , 400b, 400c, 400d are arranged.

The brushes 490a, 490b may comprise a plastic film which may be disposed approximately centrally in the brush 490a, 490b.

Preferably, the plastic film is made of polyethylene. In particular, polyethylene has a high toughness and elongation at break, a good sliding behavior, a low wear, a high temperature resistance and a very low water absorption. The plastic film may in particular also be formed in two layers.

The plastic film preferably has a film thickness between 30 .mu.m and 200 .mu.m, particularly preferably between 50 .mu.m and 150 .mu.m. The material thickness can be used to control the flexibility of the brushes 490a, 490b. The specified film thicknesses show an optimum sealing effect.

In this context, it is advantageous if the plastic film in the state arranged in the brush 490a, 490b are set back by 2% to 20%, preferably by 5% to 10%, in relation to the brush height inwards, toward the base region of the brush 490a, 490b , In this way, a good sealing effect is effected while at the same time minimizing the friction effect of the brushes 490a, 490b and minimized noise development.

In order to ensure sufficient tightness without damaging the bottom and / or the ceiling guide 200, preferably, each of the brushes 490a, 490b contacts the floor and / or with a contact pressure of 0.01 N / mm ² to 0.5 N / mm ² the ceiling guide 200.

Further, it is preferable that the brushes 490a, 490b in the door leaf members 400a, 400b, 400c, 400d are substantially identical.

Out Fig. 1 It will also be appreciated that the horizontal sliding wall system 100 includes a door leaf element 400a, 400b, 400c, 400d having at least two vertical door frames 440a, 440b and at least two horizontal door frames 410a, 410b, wherein a vertical door frame 440a, 440b comprises a first vertical frame profile 450a and at least one second horizontal frame profile 450b, and wherein a horizontal door frame 410a, 410b comprises a first horizontal frame profile 420a and at least a second horizontal frame profile (420b), and wherein all abutting edges of ceiling guide 200, horizontal frame profiles 420a, 420b, and vertical frame profiles 450a, 450b form in the assembled state of the sliding wall system 100 exclusively horizontal or vertical joints, creating a particularly harmonious and aesthetic appearance of the sliding wall system 100 is formed.

Fig. 2 shows a cross section through the ceiling guide 200 of the Fig. 1 known sliding wall system 100. The ceiling guide 200 is fixed to the building ceiling 201. The ceiling guide 200 comprises a running rail 300 in which a roller carriage 500 is displaceably arranged. On the roller carriage 500, a door leaf element 400 is arranged hanging.

The running rail 300 is substantially U-shaped, with the free legs of the U-shaped running rail 300 forming the end faces 301a, 301b of the running rail 300. Further, in particular at the distal end of the free legs of the U-shaped running rail 300 running surfaces 302a, 302b for guiding the roller carriage 500 are formed.

The rail 300 is formed of a first material having a thermal conductivity of 75-235 W m ^-1 K ^-1 and a thermal expansion coefficient of 21-24 * 10 ^-6 K ^-1 .

Preferably, both end faces 301a, 301b of the running rail 300 have a surface roughness parallel to the extrusion direction of Ra 0.1-3, preferably Ra 0.2-2, particularly preferably Ra 0.75-1.8 measured according to DIN EN ISO 4287 , As a result, particularly advantageous adhesive and contact properties for the thermal separation profile to be fastened to the running rail, which will be explained in more detail below, can be achieved.

The thermal separating profile 320 is arranged on an end face 301b of the running rail 300 via a fastening means 325, in particular a screw, clamping or glued connection. Although in Fig. 2 only a thermal separation profile 320 is disposed on one of the end surfaces 301b, it is of course possible and advantageous to provide a thermal separation profile on both end faces 301a, 301b.

The thermal separation profile 320 abuts against the end face 301b of the running rail 300. For installation, the thermal separation profile 320 comprises a plurality of mutually separated contact surfaces 321a, 321b, 321c, 321d between the thermal separation profile 320 and the end face 301b of the slide rail 300. In order to further improve the thermal separation, it is preferred that the entire contact surfaces 321a , 321b, 321c, 321d of the thermal separation profile 320 correspond to 1-10% of the area of an end face 301b of the track rail 300.

On the side facing the running rail 300 side 301b, the thermal separation profile 320 at least one open channel-like recess 322a, 322b, 322c, whereby the structural stability of the thermal release profile 320, as well as its thermal release properties can be further improved. In the embodiment shown, a first channel-like recess 322a, a second channel-like recess 322b and a third channel-like recess 322c are formed.

For fixing a runner panel 350, the thermal separation profile 320 has at least one connection means 323a, 323b, preferably at least two connection means 323a, 323b for receiving a runner panel 350 with corresponding connection means 351a, 351b for detachably connecting the thermal separation profile 320 to the runner panel 350.

The thermal separation profile 320 further has a contact leg 324 which bears against the outer horizontal rail section 303 of the running rail 300. The plant leg 324 secures by the system on a horizontal surface of the running rail 300 a defined positioning of the thermal separation profile 320 on the running rail 300th

At the plant leg 324, a groove-like guide 326 may be provided for receiving the free bristle ends of a brush 490a. The guide 326 is formed in such a way that the free bristle ends of the brush 490a arranged beneath the running rail 300 in the horizontal door leaf frame 410 are enclosed at least in sections by the groove-like guide 326. This results in a visually appealing joint image of the sliding wall system 100, since fraying of the bristle ends of the brush 490a, which usually occurs during operation of sliding wall systems, is visually obscured by the groove-like guide 326. Furthermore, the groove-like guide 326 causes an improvement in the wind-tightness of the sliding wall system, since by fixing the free end of the bristles of the brush 490a, this has an improved mechanical stability.

The thermal separation profile 320 is formed of a second material having a thermal conductivity of 0.02-0.1 W m ^-1 K ^-1 and a thermal expansion coefficient of 40-300 * 10 ^-6 K ^-1 .

The thermal separation profile 320 is in particular integrally formed. Preferably, the thermal separation profile 320 extends over 50-100%, preferably 75-100%, particularly preferably 90-100% of the length L _{LS of} the running rail 300. Further, it is preferred that the thermal separation profile 320 exceeds 50-100%, preferably 75-100%, particularly preferably 90-100% of the height H _{LS of} the running rail extends.

The runner 350 is on the connecting means 351a, 351b which with the corresponding connecting means 323a, 323 of the thermal separation profile 320 a positive and / or positive connection produce releasably fixed to the thermal separation profile 320.

The runner 350 is formed substantially L-shaped and has at its ceiling-side distal end a groove 352 for receiving a sealant 350-01 for sealing the runner 350 against the ceiling structure 201 of a building.

The runner 350 is formed of a third material having a thermal conductivity of 75-235 W m ^-1 K ^-1 and a thermal expansion coefficient of 21-24 * 10 ^-6 K ^-1 .

Out Fig. 2 It can also be seen that the door leaf element 400 includes a horizontal frame profile 420 into which a brush 490 is received for sealing the horizontal gap between the door leaf element 400 and the track rail 300, wherein within the horizontal frame profile 420 means for vertical adjustment of the brush 490a in the frame profile 420 are provided. These means for vertically adjusting the brush 490 in the horizontal frame profile (420) comprise according to the in Fig. 2 shown embodiment, a brush profile 491, in which the brush 490 is received and a substantially U-shaped receptacle 432 in the horizontal frame profile 420, in which the brush profile 491 in the vertical adjustment and / or latched is added. The brush profile 491 has a first latching means 492 which cooperates with the corresponding second latching means 433 of the U-shaped receptacle 432 such that an adjustable latching of the brush profile 491 in the receptacle 432 is effected. For this purpose, at least one spring element 493a, 493b is arranged on the brush profile 491, which is supported for generating a spring force in the receptacle 432 such that the brush profile 491 is fixed in the receptacle 432. A spring element 493a, 493b may in particular be integrally formed with the brush profile 491.

Fig. 2 shows a roller carriage 500 within the ceiling guide 200 of the sliding wall system 100 according to the present invention. The roller carriage 500 is connected to a door leaf element 400 by means of a connecting element in the form of a pad 436, which is inserted into the ceiling-side horizontal door leaf frame 410 and is supported against the shoulder 434. As a result, the door leaf element 400 in the ceiling guide 200, which is formed of rail rails 300 and possibly switches (not shown), arranged displaceable. In the sliding wall system 100, a plurality of roller carriage 500 is provided. All door leaf elements 400a, 400b, 400c, 400d preferably have identical roller carriages 500. Preferably, a door leaf element 400a, 400b, 400c, 400d is guided by at least two, preferably exactly two roller carriages 500 in the track rail 300.

The roller carriage 500 of Fig. 2 has a base body 524 on which a plurality of rollers 525a, 525b, 525c, 525d and a plurality of guide rollers 526a, 526b is arranged. How out Fig. 2 As can be seen, the roller carriage 500 comprises four rollers 525a, 525b, 525c, 525d and four guide rollers 526a, 526, b, 526c, 526d (the guide rollers 526c, 526c being concealed by the guide rollers 526a, 526b), the rollers 525a, 525b , 525c, 525d are arranged perpendicular to the guide rollers 526a, 526, b, 526c, 526d. Thus, a fail-safe displacement and guidance of the door leaf element 400 in the ceiling guide 200 can be ensured.

The rollers 525a, 525b, 525c, 525d, which are of identical design, each have a roller body 527 with a roller surface 528, wherein the roller bodies 527 roll on two running surfaces 302a, 302b of the track rail 300.

The main body 524 has a modulus of elasticity at 20 ° C of 70 kN / mm2 to 100 kN / mm2, preferably about 85 kN / mm2, according to EN ISO 6892-1: 2009, a shear modulus at 20 ° C of 20 kN / mm2 60 kN / mm 2, preferably about 40 kN / mm 2 according to DIN 53445, and a density at 20 ° C. of 2 g / cm 3 to 7 g / cm 3, preferably about 6.7 g / cm 3, according to ISO 527-1 / -2, up.

The roller body 527 has a modulus of elasticity at 20 ° C. of 2 kN / mm 2 to 4 kN / mm 2, preferably about 3 kN / mm 2, according to ISO 527-1 / -2, a shear modulus of 0.5 kN at 20 ° C. mm2 to 1 kN / mm2, preferably about 0.8 kN / mm2, according to DIN ISO 1827: 2010-07 and a density at 20 ° C of 1 g / cm3 to 2 g / cm3, preferably about 1.4 g / cm3, according to DIN EN ISO 1183. Furthermore, the roller surface 528 of the roller body 527 has a surface roughness Ra of 0.01 to 3 .mu.m, preferably from 0.05 .mu.m to 2 .mu.m according to DIN EN ISO 4287.

The roller body 527 preferably further has a diameter of 16 mm to 20 mm, particularly preferably 18.5 mm. The roller surface 28 of the roller body 27 preferably has a roller surface width of 5 mm to 9 mm, preferably 7 mm.

The roller body 527 also has a water absorption of 0.3% in normal climate according to ISO 62. The water absorption in normal climates refers to the percentage weight gain of a body by water absorption when stored at a temperature of 23 ° C and humidity of 50%. The water absorption of the reel body is kept low in normal climate. High water absorption leads to a high Abplatten of the roller body 527, whereby noise when rolling the roller body 527 of the roller 525 on the running surface 529 of the ceiling guide 200 are caused.

The roller body 527 further has a water absorption of 1.4% with water storage according to ISO 62. The water absorption in water storage refers to the percentage increase in weight of a body by water absorption when stored in water. The roller body 527 of a roller 525 is designed such that its water absorption is kept low when stored in water. Thus, a flattening of the reel bodies 527, e.g. reduced in a sliding wall system 100, which is arranged in an outer space. This ensures a quieter operation under different weather conditions.

Furthermore, the reel body 527 has a flattening smaller than 0.7% with respect to the diameter of the reel body 527 after 8 hours of standstill of the reel body 527. The low allowable flattening of the roller body 527, the smoothness of the sliding wall system 100 is significantly increased. The flattening of a roller body 527 is measured by exerting a test load of 200 N in the vertical direction on the roller body 527 arranged on a support. Particularly preferably, the roller body 527 with a diameter of 18.5 mm has a maximum flattening of 0.12 mm after 8 hours of standstill. The running surfaces 529 of the ceiling guide 200 each have a modulus of elasticity at 20 ° C. of 60 kN / mm 2 to 80 kN / mm 2, preferably about 70 kN / mm 2, according to EN ISO 6892-1: 2009, a shear modulus of 10 at 20 ° C. up to 40 kN / mm 2, preferably about 27 kN / mm 2, according to DIN 53445 and a density at 20 ° C of 2 to 5 g / cm 3, preferably about 3 g / cm 3, according to ISO 527-1 / -2. Furthermore, the running surfaces 529 have a surface roughness Ra of 0.05 to 1.0 μm, preferably about 0.5 μm, measured according to DIN EN ISO 4287.

The running surfaces 302 each have inner surface grooves substantially parallel to the direction of displacement V of the door leaf element 400. As Innenflächenrillung is a substantially line-shaped surface structure of a plurality of parallel line-shaped depressions on the running surface 302 to understand, which is produced by the extrusion process. Furthermore, the running surfaces 302 of the ceiling guide 200 are formed integrally with the ceiling guide 200. Thus, a compact design is possible. Furthermore, potential assembly errors, such as misalignments are eliminated, which noise when rolling the door leaf elements 400 in the ceiling guide 200th could be caused. The ceiling guide 200 has a density of 2 to 5 g / cm 3, preferably about 3 g / cm 3, according to ISO 527-1 / -2. The running surfaces 302 of the ceiling guide 200 each have a tread width which is larger than the roller surface width of the roller surfaces 528 of the roller body 527.

Each of the roller bodies 527 is mounted in particular on the roller carriage 500 by means of a closed ball bearing. The roller body 527 has an axis with two knurls, by means of which the roller body 527 is secured against rotation on the main body 524 of the roller carriage 500. The axle also serves as the inner ring of the ball bearing. The ball bearing has seven balls, which are greased about with lithium soap grease.

Furthermore, the static surface pressure between a roller 527 and the running surface 529 of the ceiling guide 200 is at least 2.5 kg / mm 2, preferably between 2.5 and 100 kg / mm 2. This leads to a removal of squeaking noises in the process of the door leaf elements 400.

The average travel speed of the roller carriage 500 is between 0.05 and 0.5 m / s, preferably about 0.2 m / s.

Furthermore, the starting moment of a door leaf element 400, which is arranged displaceably in the ceiling guide 20, such as the door leaf element 400a, 400b and / or 400c of Fig. 1 , 8N to 15N, preferably 10N to 14N, more preferably 11N to 13N, with a weight of the door leaf member 400a, 400b and / or 400c of 175kg. After 100,000 cycles, the starting moment of the door leaf element 400a, 400b and / or 400c continues to be 15N to 21N, preferably 16N to 20N, most preferably 17N to 19N.

By the roller carriage 500 and the running surfaces 529 of the ceiling guide 200, a low-noise movement of the sliding wall system 100 is made possible. The abrasion of the roller body 527 is reduced and thus the service life of the roller carriage 500 is significantly increased. In addition, squeaking of the rollers 525 can be eliminated.

Fig. 3 shows a vertical door frame 440 of a door leaf element 400 of the sliding wall system 100 according to the invention.

The door leaf element 400 includes at least two vertical door frames 440a, 440b. Preferably, the vertical door frames 440a, 440b are formed substantially geometrically, in particular also substantially materially identical.

A vertical door frame 440a, 440b includes a first vertical frame profile 450a and at least a second vertical frame profile 450b, both of which are substantially rectangular in cross-section are formed and each have two opposite narrow sides 453a, 454a, 453b, 454b and two opposite longitudinal sides 451a, 452a, 451b, 452b have.

The two vertical frame profiles 450a, 450b are connected by the two insulating webs 480a, 480b spaced apart.

The first vertical frame profile 450a or / and the second vertical frame profile 450b is in particular formed from a material that has a thermal conductivity of 75-235 W m ^-1 K ^-1 at 20 ° C. determined according to DIN EN ISO 10456 and a thermal expansion coefficient of 21-24 * 10 ^-6 K ^-1 at 20 ° C determined according to DIN 51045.

Preferably, the ratio of the thermal conductivity of the first vertical frame profile 450a to the thermal conductivity of the second vertical frame profile 450b is between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferably about 1: 1.

Furthermore, it is preferable that the ratio of the thermal expansion coefficient of the first vertical frame profile 450a to the coefficient of thermal expansion of the second vertical frame profile 450b is between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferably approx. 1: 1 ,

It is also advantageous that the ratio of thermal conductivity of the first and / or second vertical profile frame 450a, 450b to the thermal conductivity of the first and / or second insulating web 480a, 480b is between 50: 1-800: 1, preferably between 75: 1 -750: 1.

According to a further preferred embodiment of the invention, the ratio of wall thickness of the first vertical frame profile (450a) to the wall thickness of the second vertical frame profile (450b) is between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferred about 1: 1st

The first vertical frame profile 450a and the second vertical frame profile 450b have at least one narrow side 453a, 454a, 453b, 454b a groove-like receptacle 458a, 458b, 459a, wherein preferably the groove-like receptacles 458, a, 458b, 459a in cross section substantially geometrically are identical.

The first vertical frame profile 450a and the second vertical frame profile 450b each have at least one, preferably at least two, more preferably at least three groove-like receivers 455a, 456a, 457a, 455b, 456b, 457b on at least one of the outwardly directed longitudinal sides 451a, 452a, 451b , 452b, wherein at least one groove-like receptacle 455a, 456a, 455b, 456b, preferably at least two groove-like receptacles 455a, 456a, 455b, 456b for non-positive and / or positive reception of Isolierstegen 480a, 480b are formed.

The groove-like receptacles 455a, 456a, 455b, 456b are preferably formed substantially geometrically identical.

Two of the groove-like receptacles 455a, 456a, 455b, 456b are formed geometrically substantially identical and each at the distal end of the outwardly directed longitudinal side 451a, 452a, 451b, 452b of the vertical frame profile 450a, 450b arranged and for non-positive and / or positive reception an insulating web 480a, 480b formed.

How out Fig. 3 Furthermore, at least one of the longitudinal sides 451a, 452a, 451b, 452b, preferably exactly one of the longitudinal sides 451a, 452b, of the vertical profile 450a, 450b comprises an extension 460a, 460b which is aligned with the longitudinal side 451a, 452a, 451b, 452b End of the extension 460a at least one groove-like receptacle 461a, in particular for receiving a sealing profile is formed.

The ratio of wall thickness of the first vertical frame profile 450a to the wall thickness of the extension 460a of the first vertical frame profile 450a is preferably between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferably about 1: 1 and in particular also the Ratio of wall thickness of the second vertical frame profile 450b to the wall thickness of the extension 460b of the second vertical frame profile 450b between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferably ca.1: 1.

The first vertical frame profile 450a advantageously has a ratio of frame profile height (H _VR1 ) to frame profile width (B _VR1 ) of 1.1: 1-5: 1, preferably 2: 1-4.5: 1, particularly preferably 3: 1-4: 1, most preferably about 3.67: 1 on. The second vertical frame profile 450b further preferably has a ratio of frame profile _height (H _VR2 ) to frame profile _width (B _VR2 ) of 1.1: 1-5: 1, preferably 2: 1-4: 1, particularly preferably 2: 1-3: 1 , most preferably about 2.89: 1 on.

Further, it is preferable that the ratio of frame profile height (H _VR1 ) to frame profile width (B _VR1 ) of the first vertical frame profile 450a to the ratio of frame profile _height (H _VR2 ) to frame profile _width (B _VR2 ) of the second vertical frame profile 450b is between 1.1: 1-2 : 1, preferably 1.1: 1-1.5: 1, particularly preferably about 1.27.

It may also be preferred that the first vertical frame profile 450a has a ratio of frame profile height (H _VR1 ) to frame profile _{wall thickness} (WS _VR1 ) of 10: 1-50: 1, preferably 20: 1-40: 1, particularly preferably 25: 1 -35: 1, most preferably about 33: 1. In an advantageous further development of the invention, it is also preferable for the second vertical frame profile 450a to have a ratio of frame profile _height (H _VR2 ) to frame profile _{wall thickness} (WS _VR2 ). of 10: 1-50: 1, preferably 10: 1-30: 1, more preferably of 20: 1-30: 1, most preferably about 26: 1.

How out Fig. 3 Furthermore, one of the insulating webs 480a, 480b comprises in cross-section at least one cavity, which is preferably substantially rectangular in shape and moreover preferably has a plurality of substantially rectangular cavities. As a result, the thermal separation effect and the structural rigidity of Isolierstegls 480 b is increased.

The insulating web 480a is strip-shaped and has in cross-section at its distal ends in each case a shoulder.

The insulating webs 480a, 480b have in cross-section at their distal ends means for producing a positive and / or non-positive connection with the groove-like receptacles 455a, 456a, 455b, 456b of the first and second vertical frame profile (450a, 450b).

In the mounted state of the insulating strips 480a, 480b, these form a substantially flat surface in the groove-like receptacles 451a, 452a, 451b, 452b of the vertical frame profiles 450a, 450b.

The ratio of the width (B _VIS ) of the insulating webs 480a, 480b in a vertical door leaf frame 440 to the width (B _VR1 ) of the first vertical frame profile 450a is preferably between 1: 1-3: 1, preferably 1.5: 1-2.5: 1, in particular preferably 1.75: 1-2.25: 1.

The first vertical frame profile 450a has a first vertical viewing height (H _VS1 ) and the second vertical frame profile 450b has a second horizontal viewing height (H _VS2 ), wherein the ratio of viewing heights (H _VS1 ): (H _VS2 ) is between 1: 1-1 : 2, preferably 1: 1-1: 1.5.

Preferably, the ratio of the vertical viewing width (B _VS ) of a vertical door leaf frame 440 to the vertical viewing height (H _VS1 ) of the first vertical frame profile 450a is 1: 1-1: 3, preferably 1: 1-1: 2, particularly preferably 1: 1.2- 1: 08.01.

Furthermore, it is also preferred that the ratio of the vertical viewing width (B _VS ) of a vertical door leaf frame 440 to the horizontal viewing width (B _HS ) of a horizontal door leaf frame 410 is between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferably about 1: 1.

The groove-like receptacles 455a, 455b, 456a, 456b are designed for non-positive and / or positive reception of the insulating webs 480a, 480b. The groove-like receptacles 455a, 455b, 456a, 456b are in particular formed geometrically substantially identical.

Fig. 4 shows in the cross-sectional view of a horizontal door leaf frame 410a, 410b of a sliding wall system 100th

A door leaf element 400a, 400b, 400c, 400d comprises at least two horizontal door frames 410a, 410b, wherein a horizontal door frame 410a, 410b comprises a first horizontal frame profile 420a and at least a second horizontal frame profile (420b). Both horizontal frame profiles 420a, 420b are substantially rectangular in cross-section and there are two respective opposite narrow sides 423a, 424a, 423b, 424b and two opposite longitudinal sides 421a, 422a, 421b, 422b.

The two horizontal frame profiles 420a, 420b are connected by at least two insulating ribs 480a, 480b spaced apart.

The first horizontal frame profile 420a or / and the second horizontal frame profile 420b is in particular formed from a material that has a thermal conductivity of 75-235 W m ^-1 K ^-1 at 20 ° C. determined according to DIN EN ISO 10456 and a thermal expansion coefficient of 21-24 * 10 ^-6 K ^-1 at 20 ° C determined according to DIN 51045.

The ratio of the thermal conductivity of the first horizontal frame profile 420a to the thermal conductivity of the second horizontal frame profile 420b is preferably between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferably about 1: 1.

The ratio of the coefficient of thermal expansion of the first horizontal frame profile 420a to the thermal expansion coefficient of the second horizontal frame profile 420b is preferably between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferably about 1: 1.

In particular, the ratio of thermal conductivity of the first and / or second horizontal profile frame 420a, 420b to the thermal conductivity of the first and / or second insulating web 480a, 480b is between 50: 1-800: 1, preferably between 75: 1-750: 1 ,

The ceiling-side horizontal door frame 410ab, 410bb, 410cb, 410db includes means 434a, 434b for connecting the horizontal door frame to the roller carriage (500). The means are in particular formed as a shoulder 434a, 434b on which a fastening element of the roller carriage 500 can engage or engage.

The first horizontal frame profile 420a and preferably also the second horizontal frame profile 420b have a groove-like receptacle on at least one narrow side 423a, 423b.

The first horizontal frame profile 420a and the second horizontal frame profile 420b also each have at least one, preferably at least two, particularly preferably at least three groove-like receptacles 425a, 426a, 427a, 425b, 452b, 427b on at least one of the outwardly directed longitudinal sides 421a, 422a, 421b, 422b, wherein at least one groove-like receptacle 425a, 426a, 425b, 426b, preferably at least two groove-like receptacles 425a, 426a, 425b, 426b for non-positive and / or positive reception of Isolierstegen 480a, 480b are formed.

Two of the groove-like receptacles 425a, 426a, 425b, 426b are formed substantially geometrically identical.

Two of the groove-like receivers 425a, 426a, 425b, 426b are respectively disposed at the distal end of the outward-facing longitudinal side 421a, 422a, 421b, 422b of the horizontal frame profile 420a, 420b.

One of the longitudinal sides 421a, 422a, 421b, 422b, of the horizontal profile 420a, 420b comprises an extension 430 aligned with the longitudinal side 421a, 422a, 421b, 422b, wherein at the distal end of the extension 430 at least one groove-like receptacle 429, in particular for receiving a sealing profile is trained.

It is further preferred that the wall thicknesses of the longitudinal sides 421a, 422a of the first horizontal frame profile 420a, the second horizontal frame profile 420b and the extension 430 are constant, wherein it is particularly preferred that the ratio of wall thickness of the second horizontal frame profile 420b to the wall thickness of the extension 430 of the second horizontal frame profile 420b is between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferably ca.1: 1, and furthermore preferably the ratio of wall thickness of the first horizontal frame profile 420a to the wall thickness of the second horizontal frame profile 420b between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferably about 1: 1.

Furthermore, it is preferred that the first horizontal frame profile 420a has a ratio of frame profile height (H _HR1 ) to frame profile width (B _HR1 ) of 1.1: 1-5: 1, preferably 2: 1-4.5: 1, particularly preferably 3: 1 4: 1, most preferably about 3.67: 1. It is further preferred that the second horizontal frame profile 420b has a ratio of frame profile height (H _HR2 ) to frame profile width (B _HR2 ) of 1.1: 1-5: 1, preferably 2: 1-4: 1, particularly preferably 2: 1-3: 1, most preferably about 2.89: 1.

According to a further preferred embodiment of the invention, the ratio of frame profile height (H _HR1 ) to frame profile width (B _HR1 ) of the first horizontal frame profile (420a) to the ratio of frame profile height (H _HR2 ) to frame profile width (B _HR2 ) of the second horizontal frame profile 420b is between 1.1 : 1-2: 1, preferably 1.1: 1-1.5: 1, more preferably about 1.27.

The ratio of the width (B _HIS ) of the insulating ribs 480a, 480b in a horizontal door leaf frame 410 to the width (B _HR1 ) of the first horizontal frame profile 420a is preferably between 1: 1-3: 1, preferably 1.5: 1-2.5: 1, in particular preferably 1.75: 1-2.25: 1.

Furthermore, the first horizontal frame profile 420a may have a first horizontal viewing height (H _HS1 ) and the second horizontal frame profile 420b may have a second horizontal viewing height (H _HS2 ), wherein the ratio of viewing heights (H _HS1 ): (H _HS2 ) is between 1: 1. 1: 2, preferably 1: 1-1: 1.5.

It is also preferred that the ratio of the horizontal viewing width (B _HS ) of a horizontal door leaf frame 410 to the horizontal viewing height (H _HS2 ) of the second horizontal frame profile 420b is 1: 1-1: 3, preferably 1: 1-1: 2, particularly preferred 1: 1.5-1: 2

How out Fig. 4 It can also be seen that the first horizontal frame profile 420a and the second frame profile 420b are of substantially identical geometrical design in cross-section, except for the extension 430 of the second frame profile 420b.

The groove-like receptacles 427a, 427b are in particular for the guidance and sliding bearing of a guide means 808,809

• o ein Bürstenprofil 491, in welches die Bürste 490 aufgenommen ist, und
• o eine im Wesentlichen U-förmige Aufnahme 432 im horizontalen Rahmenprofil 420, in welche das Bürstenprofil 491 in der Vertikalen verstell- und/oder verrastbar aufgenommen ist.

Furthermore, it is off Fig. 4 combined with Fig. 2 It can be seen that in a horizontal frame profile 420 at least one brush 490 for sealing the horizontal gap between the door leaf element 400 and the running rail 300 or the building floor 101 is receivable, within the horizontal frame profile 420 means for vertical adjustment of the brush are provided in the frame profile, wherein the means for vertically adjusting the brush 490 in the horizontal frame profile 420 include:

• o a brush profile 491, in which the brush 490 is received, and
• o a substantially U-shaped receptacle 432 in the horizontal frame profile 420, in which the brush profile 491 is accommodated in the vertical adjustment and / or latched.

The horizontal and / or vertical frame profiles 420,440 have a surface roughness Ra of 0.05 to 1.0 .mu.m, preferably about 0.5 .mu.m, measured according to DIN EN ISO 4287 and a Innenflächenrillungen substantially parallel to the in particular in the Isolierstegaufnahmen 425,426,455,456 Lengthwise extension of the frame profiles 420,440 of a door leaf element 400. As a result, sliding of the profiles relative to the insulating web is simplified in order, in particular, to compensate for thermal stresses and expansions of the profiles in the sliding door system 100.

The horizontal and / or vertical frame profiles 420,440 preferably each have a modulus of elasticity at 20 ° C. of 60 kN / mm 2 to 80 kN / mm 2, preferably about 70 kN / mm 2, according to EN ISO 6892-1: 2009, a shear modulus at 20 ° C of 10 to 40 kN / mm2, preferably about 27 kN / mm2, according to DIN 53445 on.

The insulating webs 480a, 480b preferably have a modulus of elasticity at 20 ° C. of 2 kN / mm 2 to 4 kN / mm 2, preferably about 3 kN / mm 2, according to ISO 527-1 / -2, a shear modulus at 20 ° C. of 0, 5 kN / mm 2 to 1 kN / mm 2, preferably about 0.8 kN / mm 2, according to DIN ISO 1827: 2010-07. Furthermore, the surface of the insulating webs 480a, 480b, in particular in the receiving area to the frame profiles 420,440 has a surface roughness Ra of 0.01 to 3 .mu.m, preferably from 0.05 .mu.m to 2 .mu.m according to DIN EN ISO 4287.

In particular, it is preferred that the surface pressure between the insulating webs 480a, 480b and the Isolierstegaufnahmen 425,426,455,456 between 120 - 200 N / mm ² . As a result, on the one hand, a sufficiently good structural connection between the insulating webs 480a, 480b is effected and also a sliding of the components against one another is permitted to compensate for thermally induced stresses and material expansions.

Fig. 5 shows a cross section through the drainage rail 600 of the sliding wall system 100. The drainage rail 600 may optionally be present to the sliding wall system 100. In principle, it is possible to design the sliding wall system 100 without a drainage rail 600.

The horizontal sliding wall system 100 thus preferably has a drainage rail 600, which is embedded in the building floor 101 and which is arranged essentially flush below the travel path of a door leaf element 400. The drainage rail 600 comprises a first drainage profile 610 and at least a second drainage profile 620 and a first insulating bar 480a and at least one second insulating bar 480b, wherein the first drainage profile 610 and the second drainage profile 620 are fixed spaced from each other by the first insulating bar 480c1 and the second insulating bar 480c2.

Preferably, the drainage rail 600 is formed substantially flush with the building floor 101.

As in Fig. 5 can be clearly seen, the first drainage profile 610 and the second drainage profile 620 are formed in cross-section substantially rectangular.

The first drainage profile 610 or / and the second drainage profile 620 are formed from a material that has a thermal conductivity of 75-235 W m ^-1 K ^-1 at 20 ° C. determined according to DIN EN ISO 10456 and a thermal expansion coefficient of 21- 24 * 10 ^-6 K ^-1 at 20 ° C determined according to DIN 51045 has. At least one, preferably each Isoliersteg 480c1,480c2 is molded from a material that has a thermal conductivity of 0.02-0.1 W m ^-1 K ^-1 at 20 ° C. determined according to DIN EN ISO 22007 and has a thermal expansion coefficient of 40-300 * 10 ^-6 K ^-1 at 20 ° C determined according to DIN 51045.

Preferably, the first drainage profile 610 and the second drainage profile 620 are geometrically identical. In this context, it is furthermore advantageous that the ratio of the thermal conductivity of the first drainage profile 610 to the thermal conductivity of the second drainage profile 620 is between 0.9: 1-1.1: 1, preferably 0.95: 1-1.05: 1, particularly preferably approx. 1: 1 is.

As can be seen from a synopsis of Fig. 1 and Fig. 5 a door leaf element 400 comprises at least two vertical door frames 440a, 440b and at least two horizontal door frames 410a, 410b, the two vertical frame profiles 450a, 450b of a vertical door frame 440a, 440b being formed by at least two insulating webs 480a, 480b having a substantially identical width B _VIS are connected to each other at a distance (see FIG. Fig. 3 ) and the two horizontal frame profiles 420a, 420b of a horizontal door frame 410a, 410b are interconnected by at least two insulating ribs 480a, 480b of substantially identical width B _HIS (see FIG. Fig. 4 ), and the drainage profiles (610, 620) of the drainage rail (600) are connected by at least two insulating bars 480c1, 480c2 having a substantially identical width B _DIS , with B _VIS = B _HIS = B _DIS .

Further, it will be appreciated that a door panel member 400 includes at least two vertical door frames 440a, 440b and at least two horizontal door frames 410a, 410b, wherein the two vertical frame profiles 450a, 450b of a vertical door frame 440a, 440b are spaced apart by at least two insulating ribs 480a, 480b (comp. Fig. 3 ) and the two horizontal frame profiles 420a, 420b of a horizontal door frame 410a, 410b are interconnected by at least two insulating bars 480a, 480b (cf. Fig. 4 ), wherein at least one of the insulating ribs 480a, 480b, 480c1,480c2 in a vertical door frame 440a, 440b, a horizontal door frame 410a, 410b and the drainage rail 600 geometrically formed substantially identical.

It is also preferred that the door leaf element 400 comprises at least two vertical door frames 440a, 440b and at least two horizontal door frames 410a, 410b, wherein the two vertical frame profiles 450a, 450b of a vertical door frame 440a, 440b are spaced apart by at least two insulating ribs 480a, 480b are (see. Fig. 3 ) and the two horizontal frame profiles 420a, 420b of a horizontal door frame 410a, 410b are interconnected by at least two insulating bars 480a, 480b (cf. Fig. 4 ), wherein at least one, preferably all of the insulating bars 480a, 480b, 480c1,480c2 in a vertical Door frame 440a, 440b, a horizontal door frame 410a, 410b and the drainage rail 600 materially formed substantially identical.

In another preferred embodiment of the invention, the door leaf element 400 comprises at least two vertical door frames 440a, 440b and at least two horizontal door frames 410a, 410b, wherein the two vertical frame profiles 450a, 450b of a vertical door frame 440a, 440b have a substantially identical width B _VR1 (comp. Fig. 3 ) and the two horizontal frame profiles 420a, 420b of a horizontal door frame 410a, 410b have a substantially identical width B _HR1 (see FIG. Figure 4 ) and the drainage profiles 610, 620 of the drainage rail 600 have a substantially identical width B _DP1 , wherein furthermore B _VR1 = B _HR1 = B _DP1 .

Finally, in order to further improve the thermal separation in the floor area, it is also preferred that the door leaf element 400 comprises a horizontal frame profile 420 into which is accommodated at least one brush 490 for sealing the horizontal gap between the door leaf element 400 and the building floor 101 the horizontal frame profile 420 means are provided for vertical adjustment of the brush in the frame profile.

How out Fig. 5 can also be seen, the substantially rectangular profile in the interior have connecting webs between the longitudinal sides, which are preferably integrally formed, in particular monolithic with the profile. In this way, on the one hand, the structural stability of a drainage profile 610, 620 can be increased; on the other hand, a defined drainage of drainage water can take place through the thus formed channels within a drainage profile 610, 620.

For deriving the drainage water, the upper insulating web 480c1 has at least one opening 481, through which drainage water can flow into the drainage rail 600. For controlled drainage of the drainage water, at least one of the drainage profiles 610, 620 has at least one opening 612 which connects the interior of the drainage rail to the interior of a drainage profile 610, 620. Furthermore, at least one further opening 611 may be arranged on the outwardly directed side of the drainage profile 610, 620 if the drainage of the drainage water is to take place outside the drainage profile 610, 620.

The drainage profiles 610, 620 each have a shoulder 614, 624 on their facing sides. These shoulders 614,624 are used for fastening in particular a fixed pivot bearing for a rotary sliding sash 400b. For this purpose, in particular a fastening element can be inserted into the drainage rail 600, which rests on the shoulders 614,624 or at least partially surrounds them. In this recording then the stationary pivot bearing formed, for example by a sleeve in which the bolt 804 of the rotary sliding door 400b is stored rotatably guided.

The upper insulating web 480c1 has on the building ceiling 201 side facing a channel-like, substantially U-shaped surface contour, whereby the drainage water is collected and controlled the openings 481 for controlled discharge is fed.

On or in a side wall of the drainage profile 610,620 groove-like receptacles 615,625 are provided for receiving at least one insulating web. The groove-like recordings are in particular as in Fig. 7 shown, so that reference is made to the corresponding description.

The drainage profiles 610, 620 also have receptacles 613, 633 on the ceiling side, into which a cover profile 627 can be fixed in a positive-locking and / or force-locking manner. The cover profile 627 may be formed in particular L-shaped, wherein for covering preferably a cover profile 627 is positioned in the receptacle 613 and 623. This is in Fig. 5 indicated at the right drainage profile 610. The cover profile 627 in particular allows an aesthetically pleasing bottom end of the drainage rail 600.

The drainage profiles 610, 620 have a surface roughness Ra of 0.05 to 1.0 .mu.m, preferably about 0.5 .mu.m, measured according to DIN EN ISO 4287 and an internal surface grooves substantially parallel to the longitudinal extension of the drainage profiles 610, 620, in particular in the region of the insulating web receptacles 625, 626, 615, 616 , As a result, sliding of the profiles relative to the insulating web is simplified in order, in particular, to compensate for thermal stresses and expansions of the profiles in the sliding door system 100.

The drainage profiles 610, 620 preferably each have a modulus of elasticity at 20 ° C. of 60 kN / mm 2 to 80 kN / mm 2, preferably approximately 70 kN / mm 2, according to EN ISO 6892-1: 2009, a shear modulus at 20 ° C. of 10 to 40 kN / mm 2, preferably about 27 kN / mm 2, according to DIN 53445.

The Isolierstege 480c1,480c2 preferably have a modulus of elasticity at 20 ° C of 2 kN / mm2 to 4 kN / mm2, preferably about 3 kN / mm2, according to ISO 527-1 / -2, a shear modulus at 20 ° C of 0, 5 kN / mm 2 to 1 kN / mm 2, preferably about 0.8 kN / mm 2, according to DIN ISO 1827: 2010-07. Furthermore, the surface of the insulating webs 480c1,480c2, in particular in the receiving area to the drainage profiles 610,620 has a surface roughness Ra of 0.01 to 3 .mu.m, preferably from 0.05 .mu.m to 2 .mu.m according to DIN EN ISO 4287.

Fig. 6 shows a detailed view of a formed in a door leaf element 400 groove-like receptacle 455a, 455b, 456a, 456b for a Isoliersteg 480a, 480b.

The groove-like receptacles 455a, 455b, 456a, 456b are substantially U-shaped, with a first free leg 701, a second free leg 702 and a base side 703 protrude from the starting the free legs 701.702. The opposing surfaces of the free legs 701,702 of the U-shaped groove-like receptacle 455a, 455b, 456a, 456b are at an angle β1 and β2 between 25 ° -85 °, preferably 45 ° -75 °, most preferably 50 ° -75 ° opposite to the base side 703 of the groove-like receptacle 455 a, 455 b, 456 a, 456 b facing each other employed. It is very particularly preferred that the angle β1 is between 50 ° -60 ° and the angle β2 is between 60 ° -80 °.

It's also preferable, as is it Fig. 6 it can be seen that the free legs 701, 702 of the U-shaped groove-like receptacle 455a, 455b, 456a, 456b protrude from the longitudinal side 452a and the base side 703 of the groove-like receptacle 455a, 455b, 456a, 456b is aligned with the longitudinal side 452a.

The base side of the groove-like receptacle 455a, 455b, 456a, 456b has a width B _AGS and an opening portion with a width B _AOF , wherein the ratio of B _AGS to B _{AOF is} between 2.5: 1-1.5: 1, preferably 2: 1. 1.5: 1.

The first free leg 701 has a height H _AS1 and the second free leg has a height of H _AS2 , wherein the ratio of H _AS1 to H _{AS2 is} between 1.1: 1-2: 1, preferably 1.25: 1-1.75: 1.

The first free leg 701 has at its foot a width B _AF1 and at the head a width B _AK1 , wherein the ratio of B _AF1 to B _{AK1 is} between 0.8: 1-1.2: 1

The second free leg 702 has at its foot a width B _AF2 and at the head a width B _AK2 , wherein the ratio of B _AF2 to B _{AK2 is} between 2: 1-1.4: 1, preferably 2.25: 1-3: 1.

The longitudinal side 452a of the profile 450 has a thickness of S _HR2a , wherein the ratio of the thickness S _HR2a to the width B _{AF2 of} the second free leg 702 is between 1.25: 1-2: 1, preferably 1.25: 1-1.75: 1.

The groove-like receptacle 455a, 455b, 456a, 456b preferably extends over the entire length of a profile.

It is particularly preferred that all groove-like recordings
455a, 455b, 456a, 456b, 425a, 425b, 426a, 426b for receiving insulating webs 480a, 480b in vertical and horizontal door leaf frame 410,440 within the sliding wall system 100 are formed substantially identical.

Furthermore, it is preferred that all groove-like recordings
455a, 455b, 456a, 456b, 425a, 425b, 426a, 426b for receiving insulating webs 480a, 480b in vertical and horizontal door leaf frame 410,440 and all groove-like receptacles 615a, 615b, 616a, 616b for receiving Isolierstegen 480a, 480b are formed in a drainage rail 600 within the sliding wall system 100 substantially identical.

Fig. 7 shows a functional sketch of a lock for one Fig. 1 known Schiebeschwenktür 400b in the sliding state. The ceiling guide 200 is fixed to a building ceiling 201. The door leaf element 400b, in which the subsequently explained in more detail Verrieglung is added, is slidably and pivotally mounted in the ceiling guide 200 and formed as a rotary sliding sash 400b. The rotary sliding sash 400b includes a swing door 401 (see also FIG Fig. 1 ) which is pivotally mounted on the horizontal frame profile 410bb and / or the vertical frame profile 440ba of the rotary sliding panel 400b.

The rotary sliding panel 400b further includes a locking handle 800 which is rotatable between a first locking position and a second locking position. In the exemplary embodiment shown, the locking handle 800 is configured as a handle which can be rotated through 180 ° and which can be pivoted between a position facing the building floor 101 and into a position directed toward the corner of the building 201. The two locking states are in Fig.7 and Fig. 8 shown, where Figure 7 the shift state and Fig. 8 shows the pivot state of the rotary sliding wing 400b.

A first gear assembly 810 (not visible) is coupled to the lock handle 800, with the first gear assembly 810 converting the rotational movement of the lock handle 800 into a vertical, translational movement of a first lock bar 801 and a second lock bar 802.

The second gear assembly 820 is coupled to at least one of the locking rods 801, 802 such that the vertical translational movement of one of the locking rods 801, 822 is converted to a horizontal movement of a third locking rod 803. In the exemplary embodiment shown, the second locking bar 802 is coupled to the second geared arrangement 820.

The second locking bar 802 has at its cover-side, distal end a locking bolt 805, which engages in the first Verrieglungsstellung the Verrieglungshandhabe 800 in a fixed pivot bearing. This condition is in Fig. 8 shown. The stationary pivot bearing can be formed in the ceiling guide 200 and / or the building ceiling.

The first locking bar 801 also has at its bottom end a locking bolt 805, which engages in the first Verrieglungsstellung the Verrieglungshandhabe 800 in a bottom-side stationary pivot bearing, so that a rotational movement of the Drehschiebeflügels 400b around the Verrieglungsstangen 801,802 effected and a displacement of the door leaf element 400b is prevented (see. Figure 8 ). In the second locking position of the locking handle 800, rotational movement of the rotary sliding wing 400b about the locking bars 801, 802 is prevented and sliding of the door leaf element 400b is possible, which is described in US Pat Fig. 7 is shown.

The bottom-side stationary pivot bearing can in particular also be arranged in a drainage rail 600. For this purpose, it may be provided to arrange a bearing sleeve in which the locking bolt 805 engages, on and / or in the drainage rail 600. For this purpose, a corresponding opening may be provided in an insulating web 480c into which the bearing sleeve is inserted and fixed in place. By this also in the bottom-side pivot bearing continuing thermal separation, the insulating effect of the sliding wall system can be further improved.

As based on Fig.7 and Fig. 8 clearly recognizable, the first locking bar 801 and the second locking bar 802 are arranged in alignment on a common vertical axis.

The third locking bar 803 has a coupling means 806 which, in the second locking position of the locking handle 800, engages with a corresponding coupling means 807 of the swing door 401 so as to prevent rotational movement of the rotary sliding panel 400b about the locking bars 801,802 but displacing the door leaf member 400b is possible (see. Figure 7 ).

The second gear assembly 820 includes at least a first lever 821 and a second lever 822, the first lever 821 being hinged to the second latch bar 802 and hinged to the second lever 822, the second lever 822 being slidable in the horizontal door leaf frame 410bb of the door leaf 400b is received. The second lever 822 is coupled to the locking rod 803, for example by means of a screw and / or latching connection.

The third locking bar 803 is slidably guided in the horizontal door leaf frame 410bb. For this purpose, the third locking bar 803 is coupled to two sliding elements 823, 824, which are slidably received in the horizontal door leaf frame 410bb of the door leaf 400b. That is, the third Verrieglungsstange 803 contacts the profiles of the horizontal door frame exclusively on the sliding elements 823,824, to thereby ensure in particular a good thermal separation between the inside and the outside of the horizontal frame profile. For this purpose, a sliding element 823, 824 has a thermal thermal conductivity of 0.1-2 W m-1 K-1, preferably 0.1-1.5 W m-1 K-1, particularly preferably 0.1-1 W m-1 K-1 at 20 ° C. determined DIN 52612 and one thermal expansion coefficients of 0.1-2, preferably 0.5-1.5, particularly preferably 0.5-1.0 * 10-6 K-1 at 20 ° C measured according to ISO 11359 on.

The sliding elements 823, 824 are guided in particular in the groove-like receptacles 427a, 427b of the horizontal door leaf profile 410bb

The third locking bar 803 further has a coupling means 806, which comprises a groove-like receptacle, in which a corresponding coupling means of the swing door 401 can be positively brought into engagement.

In the FIGS. 7 and 8 Locking handle 800 shown is arranged on a vertical frame, band side.

The first locking bar 801 and the second locking bar 802 are vertically guided in at least one guide 808,809. The guide 808, 809 is detachably and slidably disposed within a vertical frame 440bb of the door panel member 400b. The guide 808.809 can be fixed in the vertical frame 440bb in a positive and / or positive manner.

In order to ensure a sufficiently good thermal separation on the vertical frame 440bb, a guide 808.809 has a thermal heat conductivity of 0.1-2 W m-1 K-1, preferably 0.1-1.5 W m-1 K-1, particularly preferably 0.1-1 W m-1 K-1 at 20 ° C determined according to DIN 52612 and a thermal expansion coefficient of 0.1-2, preferably 0.5-1.5, particularly preferably 0.5-1.0 * 10-6 K-1 at 20 ° C measured according to ISO 11359 on.

Claims (10)

1. A horizontal sliding wall system (100), comprising a ceiling guide (200) with at least one running rail (300), as well as at least one door leaf element (400), which is connected to a roller carriage (500), which is disposed in the ceiling guide (200) to be displaceable, wherein

   • at least one door leaf element (400b) is configured as a swing sliding leaf (400b) to be pivotable and displaceable in the ceiling guide (200),

   • wherein the swing sliding leaf (400b) comprises a swing leaf door (401), as well as

   • an interlocking handle (800), which is rotatably embodied between a first interlocking location and a second interlocking location, and

   • a first gear arrangement (810), and

   • a second gear arrangement (820),

   wherein the first gear arrangement (810) transforms the rotary movement of the interlocking handle (800) into a vertical translatory movement of a first interlocking rod (801) and of a second interlocking rod (802), wherein the second gear arrangement (820) is coupled to at least one of the interlocking rods (801, 802), such that the vertical translatory movement of one of the interlocking rods (801, 802) is transformed into a horizontal movement of a third interlocking rod (803),
   the second interlocking rod (802) at the ceiling sided distal end thereof includes an interlocking bolt (805), which in the first interlocking location of the interlocking handle (800) engages into a stationary rotary bearing, and the first interlocking rod (801) at the floor-sided end thereof includes an interlocking bolt (804),
   which in the first interlocking location of the interlocking handle (800) engages into a floor-sided stationary rotary bearing such that a rotary movement of the swing sliding leaf (400b) around the interlocking rods (801, 802) may be effected, and a displacement of the door leaf element (400b) is prevented, wherein in the second interlocking location, the interlocking handle (800) prevents a rotary movement of the swing sliding leaf (400b) around the interlocking rods (801, 802) and allows for a displacement of the door leaf element (400b), wherein
   the third interlocking rod (803) includes a coupling means (806), which in the second interlocking location of the interlocking handle (800) is in engagement with a corresponding coupling means (807) of the swing leaf door (401), such that a rotary movement of the swing sliding leaf (400b) around the interlocking rods (801, 802) is prevented, however a displacement of the door leaf element (400b) is enabled,
   characterized in that
   the second gear arrangement (820) comprises at least one first lever (821) and a second lever (822), wherein the first lever (821) is articulately supported at the second interlocking rod (802) and is articulately supported at the second lever (822), wherein the second lever (822) is displaceably accommodated in the horizontal door leaf frame (410bb) of the door leaf (400b), wherein the second lever (822) is coupled to the third interlocking rod (803),
   wherein the third interlocking rod (803) is displaceably guided in the horizontal door leaf frame (410bb),
   wherein the third interlocking rod (803) is coupled to at least one preferably two sliding elements (823, 824), which are displaceably accommodated in the horizontal door leaf frame (410bb) of the door leaf (400b), and wherein the at least one sliding element (823, 824) has a thermal conductivity of 0,1 to 2 W m-1 K-1, preferably of 0,1 to 1,5 W m-1 K-1, in particular preferred of 0,1 to 1 W m-1 K-1, and a thermal linear expansion coefficient of 0,1 - 2, preferably of 0,5 - 1,5, in particular preferred of 0,1 to 1,0 * 10-6 K-1.
2. The horizontal sliding wall system (100), according to claim 1, characterized in that the third interlocking rod (803) includes a coupling means (806), which comprises a groove-like reception, into which a corresponding coupling means of the swing leaf door (401) may be introduced in a positive engagement.
3. The horizontal sliding wall system (100), according to any of the preceding claims, characterized in that the first interlocking rod (801) and the second interlocking rod (802) are disposed in true alignment on a common vertical axis.
4. The horizontal sliding wall system (100), according to any of the preceding claims, characterized in that the interlocking handle (800) is disposed on the hinge-side on a vertical frame.
5. The horizontal sliding wall system (100), according to any of the preceding claims, characterized in that the first interlocking rod (801) is vertically guided in at least one guide (808) and/or in that the second interlocking rod (802) is vertically guided in at least one guide (809).
6. The horizontal sliding wall system (100), according to claim 5, characterized in that the guide (808, 809) is releasably disposed within a vertical frame (440bb).
7. The horizontal sliding wall system (100), according to any of the claims 5 or 6, characterized in that the guide (808, 809) is displaceably disposed within a vertical frame (440bb).
8. The horizontal sliding wall system (100), according to any of the claims 5 to 7, characterized in that the guide (808, 809) is non-positively and/or positively fixable within the vertical frame (440bb).
9. The horizontal sliding wall system (100), according to any of the claims 5 to 8, characterized in that the guide (808, 809) has a thermal conductivity of 0,1 to 2 W m-1 K-1, preferably of 0,1 to 1,5 W m-1 K-1, in particular preferred of 0,1 to 1 W m-1 K-1, and a thermal linear expansion coefficient of 0,1 to 2, preferably of 0,5 to 1,5, in particular preferred of 0,5 to 1,0 * 10-6 K-1.
10. The horizontal sliding wall system (100), according to any of the preceding claims, characterized in that a stationary rotary bearing is formed in the ceiling guide (200).

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