RU2199634C2 - Partition of prefabricated structure - Google Patents

Abstract

FIELD: construction industry, specifically, erection of internal partitions. SUBSTANCE: partition of prefabricated structure has two insulation walls 1, 2 of different thickness separated by space in which cellular structure 3, 103 carrying protrusions 7, 107 and forming separate cells 8, 9, 108, 109 is positioned. Each protrusion includes walls and extremity. Cellular structure 3, 103 is attached to both insulation walls 1, 2 on tops of protrusions. Insulation walls has no holes and walls of each individual cell are not parallel one another. EFFECT: improved sound and acoustic insulation properties of such structure. 8 cl, 6 dwg

Description

 The technical field to which the invention relates.

 The present invention relates to the field of construction and, in particular, to a partition wall of a prefabricated structure.

 The prior art.

 Partitions are known, consisting of two panels based on gypsum of a given thickness, between which there are intersecting cardboard strips. The intermediate part, in which the cardboard is located, is a vacuum section located at regular intervals. This creates a cellular structure that is attached to gypsum panels.

 In general, these panels consist of gypsum walls, on each side of which a cardboard sheet is fixed. These sheets improve the strength of the gypsum wall. For a partition with a thickness of approximately 7 cm, each of the gypsum-based panels has a thickness of approximately 1 cm.

 The new rules currently used in construction are aimed at reducing noise levels. Measurement techniques have been developed experimentally by transferring noise from one room to another. Moreover, in order for the building structure to be launched onto the market, the measured degree of noise transmission must be less than a predetermined threshold value.

 In practice, in cases of exceeding the threshold, additional sound insulation should be installed, for example, in the form of insulating plates on partitions. This requires additional costs and reduces the area of the room.

 Partitions intended for sound insulation are known from GB-A-1205295. This document describes an insulating panel designed to form or cover part of a wall, ceiling, partition or door. This panel consists of two walls, between which a molded structure is placed, having cavities whose shape approximately corresponds to a truncated pyramid and which, with their holes, alternately extend onto one and the other side of the structure. The alternate exit of the holes of these identical cavities is achieved due to the location of the cavities in a checkerboard pattern with the exit of their holes on one or the other side, respectively. The result is a molded structure that is symmetrical with respect to its mid-plane. To receive the absorbed sound, slots are made on one or both walls, through which the sound enters the cavities, the openings of which are facing them. Then the sound is transmitted through closed adjacent cavities in which it attenuates.

 Builders strive for each of the elements used to contribute to the isolation of sound in the building.

 SUMMARY OF THE INVENTION

 Therefore, it is an object of the present invention to provide a partition wall of a prefabricated structure, the cost and dimensions of which are substantially identical to conventional prefabricated partitions, but which has significantly better sound or acoustic insulation properties, limiting the transmission of noise generated from one side of the partition through the partition.

 The objective of the present invention is solved thanks to the partition wall of the prefabricated structure containing two walls separated by a space in which a cellular structure containing protrusions that form individual cells is placed. Each protrusion of the cellular structure in accordance with the present invention contains walls consisting of transverse walls, curved walls, side faces and / or non-planar faces, as well as a tip. The cellular structure is fixed on both insulating walls at the ends of the protrusions.

 In accordance with the present invention, the insulating walls have no holes and the walls of each individual cell are not parallel to each other.

 Such a device in accordance with the present invention can provide protection against the occurrence of a standing wave and, thus, improve the efficiency of sound insulation of the wall.

 Recall that the standing wave phenomenon is an interference phenomenon that occurs due to the overlapping of two or more oscillations with the same or multiple periods. When a partition is located between the insulating walls of the structure, in which there are no or essentially no surface elements parallel to each other or parallel to the surfaces facing the two insulating walls, standing waves will not arise in the space between the insulating walls.

The present invention may contain the following features both individually and in all technically possible combinations:
- the protrusions are arranged in a matrix in columns and in rows so that the vertices of the protrusions in two adjacent rows are oriented in opposite directions, while the openings of the cells formed by the protrusions extend in each of the rows alternately in the direction of both insulating walls;
- the shape of the protrusions corresponds, essentially, when choosing one of the options paraboloid, cone or pyramid, the extremities of which are sufficiently deformed to form a contact surface for fixing the cellular structure on the insulating walls;
- cells exiting through openings to one insulating wall and cells exiting through openings to another insulating wall are formed in such a way that a mesh structure of an asymmetric configuration in cross section is formed;
- the cellular structure is formed in such a way that allows pipes and / or cables to pass through without drilling through the cells;
- preferably, the protrusions are formed in such a way that passages are formed between the respective protrusions and the walls facing them along the entire length and / or width of the wall;
- the cellular structure is made of cellulose formed by vacuum;
- insulating walls have different thicknesses;
- preferably the ratio of the thickness of both walls is not a multiple of 0.5.

 The cellular structure made of molded cellulose, as well as the different thicknesses of both insulating walls, contribute to an additional improvement in sound insulation. The formed cellulose has a rough surface on at least one side, thereby reducing the degree of reflection of the waves. And different wall thickness solves the resonance problem.

- the cellular structure is made in the form of a single part;
- the cellular structure is made of a set of separate panels;
- individual panels are installed in the form of strips that are offset in relation to each other;
- the partition on all sides around the perimeter has a thin wall to improve its mechanical strength, especially to improve resistance to distortions;
- at least one insulating wall is made of a gypsum panel to which cardboard sheets are attached. Other advantages and properties in accordance with the present invention will be disclosed in the following description of two embodiments of the present invention, made in accordance with the attached drawings.

 The list of figures drawings.

The figure 1 shows a perspective view in partial section of a partition of a prefabricated structure in accordance with the first embodiment of the present invention;
figure 2 shows in detail the cellular structure of the septum of figure 1;
figure 3 is a perspective view in partial section of a partition of a prefabricated structure in accordance with a second embodiment of the present invention;
in figure 4 - part of the form for obtaining the cellular structure of the septum in figure 3;
figure 5 is a cross section along the line VV of the part of the cellular structure obtained using the form of figure 4.

 Figure 6 schematically depicts a front view of a portion of a cellular structure consisting of individual panels.

 In various drawings, common elements are indicated by indices with the same numbers.

 Information confirming the possibility of carrying out the invention.

 The partition wall of the prefabricated structure in accordance with the present invention contains two insulating walls 1 and 2, separated by the space in which the cellular structure 3 or 103 is located.

 The height or thickness of the cellular structure corresponds to the distance between both walls 1 and 2.

 The configuration of the cellular structure is different in different embodiments of the present invention, but the structure always contains protrusions or indentations, depending on the direction of observation, arranged in a matrix and defining the outlines of individual cells.

 The cellular structure 3 shown in FIG. 2 contains protrusions 7, and each protrusion 7 has a vertex 15. The protrusions 7 are arranged so that all the vertices are oriented on the same side of the structure 3, in the presented example, on the side that should be facing the insulating wall 1. The protrusions 7 generally have the original shape and dimensions and together form separate cells 8, the openings of which extend to the side opposite to the vertex 15, while the openings of the cells 9 extend to the same side as the vertices 15 .

 Obviously, industrial production is simplified by repeating the same structure. However, changing shape and size can improve product quality.

 Each cell 8 is defined by a curved wall 10 with a bend around axis A and two transverse walls 11 and 12 located in planes extending across axis A. In the presented example, cell 8 looks more or less like half a straight cylinder, while its sectional plane is parallel to the axis A. The transverse walls 11 and 12 are essentially, but not necessarily, flat and are located in planes that are not parallel to each other, for example, so that the two transverse walls of the cell are slightly inclined with respect to each other, as seen from on the side of the cell top.

 Due to the above arrangement, the cellular structure as a whole, as well as each of the individual cells, does not contain any parallel walls either in the direction of the axes A or in the transverse direction T, which are the main directions of transmission of sound waves. In other words, the walls of each of the individual cells are not parallel to each other.

 Cells 8 of the cellular structure 3 are arranged in the form of a matrix, while sets of consecutive cells are located along the same axis A, and rows of sets of cells are parallel to each other.

 Cells 8 of this set are separated from each other by a free gap 13, and each of the gaps 13 is determined by the transverse wall 11 of the cell 8 and the transverse wall 12 of the next cell. Each free gap 13 is connected in a direction transverse to the axis A with a corresponding gap 13 of sets of neighboring cells.

 Cells 8 of two adjacent sets are separated from each other by a free gap 14, each of the free spaces 14 being defined by parts of the faces of the curved walls 10 of two neighboring cells. Each of the free spaces 14 is connected in a direction parallel to the axes A with a corresponding gap 14 formed between two subsequent cells.

 In addition, successively located free gaps 14 and adjacent free gaps 13 defined between the four cells 8, form an elementary rectangular matrix of cells connected to each other, as well as with adjacent free gaps 13 and 14. Free gaps 13 and 14 form cells 9.

 On the side opposite the vertices 15 of the cells 8, the cells are connected to each other by thin elements, which will be referred to below as ribs 16 and 17, regardless of their actual shape and embodiment of the present invention. The ribs 16 and 17 are enlarged in figures 1 and 2 in relation to the size of the cell for a better understanding of the image shown in the drawing. The ribs 16 are oriented parallel to the axis A of the cells, and the ribs 17 are oriented in the transverse direction with respect to the axis A, at the same time making up the bottom of the free gap 13, as well as the free gap 13 and the vertices of the cells 9. Thus, the rib 16 connects the curved walls 10 of two adjacent cells 8, and a rib 17 connects the transverse wall 11 of the cell with the transverse wall 12 of the next cell.

 The cellular structure 3 is fixed on the insulating walls 1 and 2 at the ends, namely, on the peaks 15 and the ribs 16 and 17 of the protrusions 7. Obviously, the peaks 15, as well as the ribs 16 and 17 can be completely fixed to the corresponding insulating walls 1 or 2 partially, for example, using glue stains.

 Due to the configuration and arrangement of cells 8 and 9, their ends are arranged so that the ends on one side of the cellular structure are not located opposite the ends facing the other side of the cellular structure. In accordance with this, the insulating walls 1 and 2 of the wall in accordance with the present invention are connected by elements that, with the exception of the curved walls of 10 cells, are located in planes that are not perpendicular to the planes of a larger area of the insulating walls 1 and 2, which contributes to a significant improvement in the insulating properties of the partition .

 The insulating walls can be made, for example, from gypsum panels coated on both their large sides with a cardboard sheet.

 Such gypsum-based walls preferably have different thicknesses to eliminate any resonance phenomena. Moreover, to eliminate resonance at one harmonic, the thickness ratio of both insulating walls should not be a multiple of 0.5. Preferably, they can be of type BA 13 and BA 10 (commercial designation describing the wall thickness, respectively 13 and 10 mm).

 The cellular structure 103 is shown in FIG. 4 and in more detail in FIG. 5 by a mold 100 that can be used in its manufacture. According to the representation of the structure 103 in FIG. 3, the configuration of the upper surface of the mold 100 corresponds to the lower surface of the honeycomb structure 103. To simplify the drawing and description in FIGS. 4 and 5, the mold 100 is represented only by the part corresponding to the protrusions of the structure 103 forming separate cells. Additional parts necessary for installing the mold in the machine and for its operation are omitted. Accordingly, the following description of the mold 100 with respect to the configuration and arrangement of the protrusions, cells and ribs also refers to the structure 103.

 The mold 100 contains protrusions 107, the configuration of which essentially corresponds to a pyramid, the apex of which was slightly deformed to obtain contact surfaces on the cellular structure for fixing on insulating walls 1 or 2, for example, using glue. The extremities or vertices of the protrusions 107 are indicated by indices 115 and 118.

 Each protrusion 107 has the shape of a truncated pyramid with four large side faces 151-154 in the form of a trapezoid, four smaller side faces 155-158 connecting large beveled transverse faces, and a non-planar face 159 corresponding to the truncated part of the pyramid. The base of the pyramid is the opening of a cell formed by a protrusion.

The inclination of the large lateral faces with respect to the axis of symmetry B of the truncated pyramid is chosen so that the angle α formed by two large opposite faces is approximately 40 to 50 ^o .

 In the non-planar faces 159, which correspond to the bottom parts 115 and 120 of the cells formed by the protrusions, a hole is made, designated 119 or 118 in accordance with the cell in question. These holes or passages allow the formation of a cellular structure 103 using a vacuum process, as will be described below.

 The protrusions 107 are arranged in a matrix of columns C and rows L so that their ends are oriented alternately on one or the other side, which should face each of the two insulating walls of the partition in accordance with the present invention. In the presented example, all the protrusions 107, the edges of which are indicated by the index 115 and which correspond to the cells 108, are oriented so that the openings of the cells extend downward. On the honeycomb structure 103, this corresponds to the side that should face the insulating wall 1. Similarly, the openings of the protrusions 107, the ends of which are indicated by the index 118 and which form the cells 109, extend upward, which corresponds to the side of the structure 103, which will face the insulating wall 2.

 To simplify the description, the protrusions 107 are shown in figures 3 and 4 so that the individual cells 108 and 109 have the same shape and dimensions. However, it is obvious that in order to obtain an asymmetric structure, such protrusions can be made in which the cells 108, for example, are larger than the cells 109.

 Similarly, in accordance with the embodiment of FIG. 4, the mold 100 comprises ribs 116, 117 extending between the protrusions forming the cells with the same designation.

 More specifically, FIG. 4 shows ribs 116 extending between protrusions forming cells 109 of one column of protrusions and ribs 117 extending between protrusions forming cells 109 of one row of protrusions. The shape of the ribs 116 and 117 can be arbitrarily selected in accordance with the curvature of the curved section. So the curvature of the ribs 116 and 117 may be underlined, as shown in figure 4, or may be less pronounced. In addition, any of them can be essentially straight and, thus, correspond to the ribs 16 and 17 in accordance with the first embodiment of the cellular structure 3. Finally, the ribs 116 and 117 can be made on either side of the form or on both sides.

 In accordance with the configuration and dimensions of the ribs 116 and 117 between the cells of the structure 103 obtained using the mold 100, tubes and / or cables in one or the other direction can be laid on any of the insulating walls 1 and 2. Due to this, the cellular structure, consisting of protrusions 107, forming cells 108 and 109 of identical shape and size, which do not have any ribs 116, 117 or have very curved ribs, allows you to install a wide selection of tubes and / or cables between cells of the structure 103 with side of any of the insulating walls 1 and 2.

 Regardless of the size and shape of the cells 108 and 109, the mesh structure 103 preferably has two different surface states on one side and the other.

 Indeed, the cellular structure 103 is obtained from the pulp, which is applied to a mold, the configuration of which corresponds to the form shown schematically in FIG. 4. The through-pass channels 119, 120 of the mold allow a vacuum to be applied to the mold so that the pulp is firmly pressed against the mold surface.

 The molding of the cellular structure 103 using a vacuum process on a mold that is a single piece, compared with molding using two forms of a complementary configuration between which the pulp is pressed, makes it possible to give the cellular structure 103 a smooth surface on one side and a rough surface on the other side. It is obvious that a smooth surface can be replaced by a non-smooth surface, reproducing, complementing it, the configuration of the surface of the form.

 Due to the rough surface of at least one side of the cellular structure, the thickness of the material of the cellular structure is not constant, but randomly varies throughout the cellular structure. Variation in the thickness of the material, as well as surface roughness (s), improves the overall soundproofing of the partition in accordance with the present invention. While varying the thickness of the material helps to suppress the transmission of sound through the material of the cellular structure, the uneven surface weakens the reflection of sound between the cellular structure and the insulating wall to which the cellular structure is attached on the side of the rough surface.

 Regarding the choice of material for the manufacture of the cellular structure, as well as the preparation of the pulp constituting the material of the cellular structure, we give the following remarks.

 Molded cellulose is preferred over paper and paperboard, as molded cellulose contains fibers of various sizes and, importantly, they are slightly oriented. It contains a wide variety of inclusions, originating, for example, from recycled paper or cardboard.

 The density of the molded cellulose in the dry state is about 0.3.

Molded cellulose is obtained essentially in four stages, that is:
- boiling, grinding old paper and cardboard in an aqueous mixture containing approximately 15% cellulose and 85% water;
liquefying the mass to obtain a cellulose concentration of about 1%, i.e. 99% water;
mass application on the mold and vacuum molding;
- drying.

 The filling ratio is approximately 14%, the mass containing mechanical pulp in approximately the same proportion as pulp for newsprint or chemical pulp.

 Similarly to the cellular structure 3, the cellular structure 103, as shown in FIG. 3, is fixed to the insulating walls 1 and 2 at the ends 115 and 118 of the cells 108 and 109. The insulating walls can be of the types indicated by BA 13 and BA 10.

 Regardless of the chosen embodiment of the cellular structure, it has, for example, a thickness of 4.7 cm. The thickness of the septum in accordance with the present invention is standard 7 cm.

 The partition wall of the prefabricated structure in accordance with the present invention may have standard dimensions for this type of partition, i.e. a height of 250 cm, a width of 120 cm and a depth of 7 cm.

 Thus, transport, storage and installation equipment remains unchanged, as for commonly used partitions.

 The figure 6 schematically shows a cellular structure made up of individual panels 4 mounted by strips 5 that are offset relative to each other.

 Such panels can be squares with a side of 30 cm, which is suitable for a 120 cm wide partition.

 It is also possible to use cellular structures consisting of larger panels or panels representing a single element.

 In all cases, the cellular structure is formed in such a way that allows the laying of tubes and / or cables in the lateral or longitudinal direction without drilling through the cells.

 The edge or peripheral part of the partition is preferably closed by means of a thin wall 6 in the form of a tape or cardboard strip that closes the partition.

 This allows you to improve the mechanical strength of the partition and, in particular, resistance to distortions.

 Tests were conducted to compare the acoustic performance of a partition wall of a prefabricated structure in accordance with the present invention with various types of conventional partitions: a partition made of 7 cm thick gypsum tiles; a partition wall of a prefabricated structure 7 cm thick containing between two gypsum panels a structure consisting of intersecting cardboard strips; and finally, the partition wall of the prefabricated structure of the same type, but with a thickness of 5 cm.

 The tests were a measurement of the level of noise transmitted through each of the four partitions in question.

 These tests showed that a partition of 7 cm thickness in accordance with the present invention improves the noise transmission by 7-13 dB compared with the other three types of partitions commonly used in construction.

 The use of the partition in accordance with the present invention makes it easier to comply with the new rules without increasing the cost of materials and work, without reducing the living area.

 In addition, the cost of the partition walls of the prefabricated structure in accordance with the present invention is essentially identical to the cost of conventional partitions, since the price of raw materials, and in particular cardboard, is of decisive importance in comparison with molded cellulose.

 The reference indices given in the claims after the mentioned technical specifications are intended solely to facilitate their understanding and do not limit it in any way.

Claims (9)

 1. A partition wall of a prefabricated structure containing two insulating walls (1, 2), separated by a space in which a cellular structure (3, 103) is located containing protrusions (7, 107) forming separate cells (8, 9, 108, 109), and each protrusion has walls and a tip, and the cellular structure (3, 103) is attached to both insulating walls (1, 2) on the tops of the protrusions, characterized in that the insulating walls have no holes, and the walls of each of the individual cells are not parallel to each other, while the insulating walls (1, 2) have different thicknesses.  2. The partition according to claim 1, characterized in that the protrusions (7, 107) are arranged in a matrix in columns and rows, while the vertices (15, 16, 17; 115, 118) of the protrusions in two adjacent rows are oriented in opposite directions , while the cells (8, 9; 108, 109) formed by the protrusions (7, 107) come out openings from row to row alternately towards each of the insulating walls (1, 2).  3. The partition according to claim 1, characterized in that the cells (8, 108) that open with openings to the insulating wall (2) and the cells (9, 109) that open with openings to the other insulating wall (1) are formed in such a way which give the cellular structure (3, 103) an asymmetric configuration in its cross section.  4. The partition according to any one of claims 1 to 3, characterized in that the cellular structure (3) is made in such a way that allows you to lay tubes and / or cables without drilling through the cells.  5. The partition according to any one of claims 1 to 4, characterized in that the cellular structure (3, 103) is made of molded cellulose.  6. The partition according to any one of claims 1 to 5, characterized in that it contains a thin wall (6) around the entire perimeter.  7. The partition wall according to any one of claims 1 to 6, characterized in that at least one insulating wall is made in the form of a gypsum panel to which cardboard sheets are attached.  8. The partition wall according to any one of claims 1 to 7, characterized in that the cellular structure (3, 103) is made of a set of separate panels (4) containing individual cells.  9. The partition according to claim 8, characterized in that the individual panels (4) are arranged in the form of strips (5), offset in relation to each other.

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