HORIZONTAL STRUCTURE FOR GEBAÜDE

The present invention is related to a horizontal frame structure for a building, said structure being based on floor joists/beams which are placed over the area supported by the horizontal frame structure and arranged into a single- or multi-layer staggered array. Said horizontal frame structure can be used in a ground floor, party floor or top-level floor. The horizontal frame structure according to the invention facilitates the division of the area or space supported by said horizontal frame structure into subareas or segregated spaces which are effectively insulated from each other against flanking transmission of sound.

The present horizontal frame structure is particularly intended for use in lightweight buildings for the purpose of preventing flanking transmission of sound via structural elements between the spaces supported by the present horizontal frame structure. While the present invention is primarily intended for use in timber buildings, the invention may also be adapted to frame structures implemented by means of other materials.

Transmission of structurally propagated sound called flanking transmission between the different areas and spaces of a building is a problem particularly in buildings erected with lightweight materials lacking such inertial masses that normally provide sound insulation.

A conventional method to overcome this problem in floor constructions is disclosed in the publication WO 91/19064. The construction incorporates the use of sound attenuating material. The material is formed onto a special assembly block to be placed between the floor boards and the joists supporting the board construction.

A more effective insulation against flanking transmission between segregated spaces of a single storey in a lightweight building can be implemented by providing each space to be sound-insulated with an unconnected vertical frame structure to which the load-bearing floor joists of each isolated space are then supported. Such a bordering principle of sound-insulated spaces based on unconnected vertical frame structures makes the space reservations of superimposed spaces to be dependent on each other and destroys the flexibility of space-layout.

Furthermore, such a sound-insulating frame structure raises a need for an essentially over dimensioned foundation with respect to the overall weight of the building, since the support structures of the building's vertical frame are erected at points determined by the structural grid of the sound-insulated spaces onto the building's square area footprint, and each load-bearing column requires a separate load-receiving reinforcement in the building's foundation.

It is an object of the present invention to overcome the above-described drawbacks by virtue of the horizontal frame structure according to the invention. A particular benefit of the invention is therein that it permits independent layout of the sound-insulated areas and spaces partitioned over the area of the present horizontal frame structure regardless of the location of the supporting structures. This same freedom in the location of structures applies to both the spaces on the same level with the horizontal frame structure and those located there above and thereunder. The horizontal frame structure according to the invention facilitates the use of a simple frame structure, wherein the factors affecting the location of the vertical frame members are rationally based on the load-bearing capability of vertical frame building elements rather than on the need for sound insulation. The essential specifications of the horizontal frame structure according to the invention are disclosed in annexed claim 1. Additional specifications of the invention are disclosed in annexed claims 2 and 3.

In the following the invention is described in greater detail with reference to annexed diagrammatic drawings in which

1. Figure 1 shows a basic embodiment of the invention; and
2. Figure 2 shows alternative embodiments of the invention.

Referring to Fig. 1, therein is shown diagrammatically a sectional view of a building party floor illustrating an exemplifying embodiment of the principle of the invention.

The party floor comprises load-bearing joists 1 and 1' which are spaced over the party floor area according to a structural grid based on the load-bearing capacity required from the floor. The span of the joists in the party floor can be, e.g., a full modular length of the building frame or, for a larger building, the party floor joists can be provided with intermediate support to limit the unsupported span of the joists to reasonable lengths. The supporting of the party floor joists is accomplished by girders 2 and 2', which further are supported by the vertical frame. According to the basic concept of the invention, each of the girders 2, 2' supports only one of the areas 4 and 4', or alternatively, only one of the spaces which are bordered by said areas and are intended to be sound-insulated from each other against flanking transmission.

Supporting with isolation against flanking transmission separately for each area can be implemented at each load-supporting point by virtue of spacers 10, 10' placed in a staggered manner over the girders 2, 2', whereby the spacers are located so that one sound-insulated area 4 is supported by one girder-group 2 only, while the other soundinsulated area 4' is supported by the other girder-group 2' alone.

In the embodiment shown in Fig. 2, an alternative implementation of the invention is shown in which the isolated supporting of areas 4, 4', which are sound-insulated against flanking transmission, is accomplished by means of floor joists 1, 1' and 1'' acting primarily as secondary supports. In the embodiment shown herein, to each load-bearing point are adapted two or three parallel joists, which are isolated from each other, whereby the number of joists is determined therefrom how many sound-insulated areas or spaces partitioned above said areas are desired to be supported by said load-bearing point. The staggered support for each area separately is achieved by means of spacers 5, 5' and 5'', which are appropriately placed between the floor area 4, 4' and 4'', respectively, and each selected floor joist so as to isolate the supported floor from the adjacent joist(s) intended to support other area(s). Another means to accomplish said support is to contour the relevant joists and girders.

The party floor joists 1, 1' and 1'', which are depicted as conventional lumber joists in the above-described exemplifying embodiment of the invention, may as well be selected from the group of gluelam, laminated veneer lumber or lattice beams manufactured in a conventional manner. Also different types of hollow-core beams are suitable for use within the scope of the invention. The invention may also be implemented in a horizontal load-bearing structure based on load-bearing slabs. Obviously, the slabs must be dimensioned with respect to the overall area of the horizontal frame structure so that the supporting of the isolated subareas can be borne by slabs of reasonable dimensions. In practice, such slabs can be relatively narrow hollow-core or ribbed slabs.

In a horizontal frame structure implemented according to the invention, the spans of the joists/beams may be relatively long. Resultingly, lateral vibrations may occur in the horizontal elements. The simplest method of suppressing lateral vibrations is to make the joists/beams into wide box-section elements. Also the above-mentioned slab structure can suppress the lateral vibrations. In cases where these structures are considered unpracticable, it may be necessary to connect the joists of each isolated subarray to each other laterally. When such a lateral bracing of joists spanned between a greater number of load-bearing points is implemented, it is essential to pass the bracing beam so that it will be connected to the joists of a single sound-insulating subarray while passing without contact through the joists belonging to the other subarray(s).

Analogously, piping/ducts passed through the joists/beams such as air-conditioning, heating, water, sewer and electrical ducts must be isolated from the joists/beams in either a noncontacting or sound-insulating manner.

The connection of the joists/beams to the areas supported by them can be made in the above-described manner by means of spacers which are placed on the joist/beam thus transmitting the load of the supported area in a supporting manner to the joist/beam. In the simplest way this can be accomplished as shown in the diagram by means of spacer pieces 5, 5' and 5'', which are fixed onto the joists. The purpose of the spacer is to outdistance the structural elements serving to isolate the structures of a certain sound-insulated area from the joists serving to support the other sound-insulated areas, whereby an isolating gap against flanking transmission is created between the joist(s) carrying the spacer(s) and the other structural elements connected to the "other" supported areas.

The embodiments shown in the diagrams are related to a building party floor structure in which the structures partitioning the areas above the structure are supported to a floor structure, which is further supported from below by separate joists selected by appropriately placed spacers. The diagram of Fig. 2 also shows the party ceiling 9 of the next storey below that may in an analogous manner be supported in sound-insulated areas hung by isolated groups of supports in the same manner as the party floor above. Further analogously, the same isolation principle can be applied to the other structures of the space below that are connected to the joists of the overlying floor.

The party floor structure according to the invention allows relatively free layout of spaces sound-insulated from each other over the area of the party floor, whereby the other structures used to partition the spaces must be designed with due caution as regards the isolation of flanking transmission by conventional means. Further, the invention makes it possible to isolate a certain subarea within a certain area isolated against flanking transmission in, e.g., a flat or apartment space. An example of such an embodiment is the floor support of the washing machine space which can be isolated from the floor support of the other areas of the flat.