This application is a national stage application under 35 U.S.C. 371 and claims the benefit of PCT Application No. PCT/EP2017/000517 having an international filing date of 25 Apr. 2017, which designated the United States, which PCT application claimed the benefit of German Patent Application No. 10 2016 007 912.6 filed 30 Jun. 2016, the disclosure of each of which are incorporated herein by reference.
The invention relates to a drywall construction system with spring rails. In particular the invention relates to a drywall construction system with sound insulation properties, in which spring rails are arranged between the metal supports and the panelling.
Drywall construction systems which also meet sound insulation requirements are known from the art. The sound insulation properties of lightweight walls constructed from metal posts and beams with panelling on both sides are essentially determined by the so-called mass-spring-mass principle. Speaking in generalised terms, the following two statements apply:
An example for a high-performance sound-Insulation wall system based on these principles, is the W112 Knauf wall system with two-layer panelling on both sides using Knauf Diamant Boards (gypsum plasterboards with a raw density of >1000 kg/m3) of 12.5 mm nominal thickness as well as a substructure of CW 100/50/06 Knauf Profiles (“acoustic”-C-Profile with good springiness or resilience for the wall) at an axial distance of 625 mm and cavity sound-proofing with mineral wool with a filling level of 80%. This construction achieves a sound reduction index Rw of 63.2 dB on the test bench.
Such a wall system, however, cannot cope with any systematic building loads, because the CW profiles (100/50/06 profile) with a steel sheet thickness of only 0.6 mm are structurally unsuitable for this. A load-bearing wall requires profiles with a greater sheet thickness, such as the C 97/50/1.5 Cocoon profile. This lightweight steel profile has a sheet steel thickness of 1.5 mm. When using this profile with an otherwise unchanged wall design, the sound reduction index deteriorates significantly to a test bench value of only Rw 51.1 dB. The reduction in sound insulation is caused by the use of C 97 profiles with greater sheet thickness.
The greater sheet thickness of the C 97 profiles leads to a distinct increase in spring stiffness as compared to the CW 100 profiles used in dry construction systems taking into account the acoustics, the CW 100 profiles having a sheet thickness of only 0.6 mm.
Furthermore a spring rail or resilient bar is known in the art, which is used in the field of loft conversions with wooden frames where the spring rails are to compensate for the high acoustic stiffness of the wooden frames, in order to achieve sufficient sound insulation. To our knowledge, however, this spring rail is used exclusively in this area.
The object of the invention consists in proposing a drywall construction system with improved sound insulation, in particular in areas, where load-bearing walls are constructed according to the drywall principle (lightweight steel construction).
This object is achieved by means of a drywall construction system for sound insulation according to claim 1. Advantageous further developments of the invention are specified in the sub-claims.
The drywall construction system according to the invention comprises a plurality of metal profiles, which are clad with panels, at least on one side, using dry construction boards. Spring rails are arranged between the metal profiles and the dry construction boards at least on this one side. The spring rails acoustically decouple the panelling of the drywall construction system from the profiles, thereby strengthening the spring effect in the above described mass-spring-mass system.
The metal profiles are preferably lightweight steel profiles with a sheet thickness between 1 mm minimum and 3 mm maximum. Preferably the sheet thickness is greater than 1.5 mm and a maximum of 3 mm. These profiles are suitable for use in load-bearing structures. Due to their high sheet thickness, however, they are comparatively stiff against bending, and therefore additional sound-insulation measures are required in order to comply with today's sound-insulation standards. The decoupling, which is due to the spring rails arranged between the profiles and the panelling, compensates for the acoustic disadvantage of higher sheet thicknesses, in fact, it overcompensates for it.
The drywall construction system according to the invention with use of the spring rail as a decoupling element can be used to advantage also in conventional drywall construction systems. The metal profiles used here are so-called spring profiles, which have particularly good acoustic properties. The sheet thickness of these spring profiles is between 0.4 mm and 1 mm. Due to using the spring rail between these spring profiles and the dry construction boards used for the panelling a further increase in the sound reduction index can be achieved.
According to a particularly preferred embodiment of the invention the spring rail is a top-hat rail. It comprises a base with shanks adjacent to the base on both sides, wherein the shanks project at an angle from the base. The shanks are joined to flanges, which again extend at an angle therefrom.
The flanges and the base are used to attach the spring rail to the metal profile/the construction board. The angled shanks provide for the spring effect of the spring rail.
The spring rail preferably comprises recesses in the metal. The recesses lead to a higher flexibility of the spring rail and to less contact between the spring rail and the metal profile, and thus further improve the decoupling between the metal profiles and the panelling. Particularly preferably the recesses may be provided in the vicinity of the shanks. A round or oval shape of the recesses is particularly preferable because it promotes a particularly good relationship between stability and flexibility of the rail.
The drywall construction system is suitable for both one-sided and two-sided panelling using dry construction boards. A one-sided panelling system is predominantly used as a facing shell in an already existing construction. Panelling on both sides or on two sides is, for example, used, when (load-bearing) partitions are to be constructed. Furthermore such systems are suitable also for use in modular construction systems, both for constructing partitions and for constructing outside walls.
According to a typical embodiment of the invention the spring rails are arranged perpendicularly to the metal profiles. The construction boards can then be attached to this profile grid.
Particularly preferably the spring rails are fastened to the metal profiles, for example they can be fastened by means of screws to the flanges of the metal profiles. The construction boards can be fixed to the spring rails. Particularly preferably the construction boards are fixed to the spring rails in such a way that they are not fixedly connected to the metal profiles. This embodiment allows for a maximum decoupling of the construction boards from the metal profiles and therefore also results in the highest sound reduction index which can be achieved with this system. Admittedly, however, stability by comparison is less with this system, and therefore the other embodiments cannot be excluded from the invention.
According to a further development of the invention the cavities can be filled with insulation material in order to increase sound insulation further. The insulation materials are placed into the cavity enclosed by the spring rails and into the cavity between the spring rails. Besides or in addition, it is possible the dispose insulation materials between the metal posts and thus fill the cavity between the boards wholly or at least partially with insulation material. Particularly preferably up to 80% by volume of the space between the dry construction boards is filled with insulation material.
Mineral wool is a preferred insulation material in terms of this invention. But other acoustically effective insulation materials can be equally used or used in combination with each other.
The invention will now be described in more detail by way of an exemplary embodiment, in which:
In
Number | Date | Country | Kind |
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102016007912.6 | Jun 2016 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/000517 | 4/25/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/001539 | 1/4/2018 | WO | A |
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Number | Date | Country | |
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20190211550 A1 | Jul 2019 | US |