DE19653633A1 - Structural prefabricated building design - Google Patents

Abstract

The bearing and non-bearing elements of the prefabricated structure consist of profiled and in part thinwalled beams (10,11) made of homogenized wood and faced in plates (13) of the same material to give a thinwalled box structure of extreme rigidity, precision and insulating properties. The abutted outside walls make up an integrated highly insulating and windproof three-chamber (2) system, or again a two-chamber system of similar properties. The abutted chamber elements retain their continuity and in multi-storey buildings the outside walls are protended per storey beyond that below to form a drip edge per storey and give ventilating air convection. Building prefabrication includes heat insulation, windows and doors and service lines, sanitation and air-conditioning as well as communication provision.

Description

The invention relates to the various functions of the structure low-energy construction integrating residential and commercial buildings, ge relies on load-bearing elements made of homogenized wood, with maximized front manufacturing and complete deconstruction according to the generic term of the An saying 1.

Despite the generally high priority of new technologies in an indu Striestaat like the Federal Republic of Germany dominate in housing and Commercial construction largely traditional construction and working methods, be at best, tentative developments. All new approaches, including the In initiatives by government agencies remain too much of the technology introduced arrested and do not let the changed energetic requirements in closest connection with the new economic criteria and recognize system-technically sophisticated solutions.

Thermal insulation, which stone construction only as a costly additional measure and only integrate the common timber frame construction into the building to a limited extent is one of the most popular today for economic and business reasons clearest propagated requirement. For technical-physical and sy Technically reasonable solutions, that is, statics and thermal insulation are not If you look at it sequentially, there are construction elements developed abroad and semi-finished products are available, the potential of which is hardly known here is.

The state of the art in terms of modes is still completely unsatisfactory fiction ability of buildings to the dynamics of the family structure and the Take account of space use; through to complete non-destructive Dismantling, namely the mobile home.

The traditional wooden frame and stand construction, the panel construction, but also prefabricated house construction, the beginnings of elementary building, can be a construction satisfactory price / performance ratio only in the rarest cases len reach. Justified individual wishes, an underdeveloped Lo Construction management and a decline in skilled craftsmen hen costs and time requirements.

The ecologically attractive building material wood is increasingly being used turn. The most diverse systems of wooden frame and stand construction and However, the panel construction has the disadvantage that with components made of na door wood no geometries necessary for a time-saving final assembly cal precision of the components can be achieved. So still considerable hours of craftsmen required on the construction site. That an abso lute windproofness is not achievable in the long term is obvious Lich. Cause of the sequential processing of the various tasks Work on the construction site is underdeveloped according to the state of the art celt integral construction concept, or the lack of technical-economic thinking system engineer.

This is obvious and solely because of the lack of know-how transfer the development lines, work and manufacturing methods from other industries the advantage, which is based on processed materials combinable and industrially manufactured components and consistently  support elementary building, together with a construction period and perennial Quality guarantee.

The invention is based, an energetic and economical task Lich advantageous construction to create, both for the single and multi storey apartment as well as for commercial buildings and for outbuildings. By Integration of almost all functions (statics, heat and sound insulation, Fire protection, light inlet, ventilation, electrical and sanitary equipment, Heating, communication) in industrially prefabricated components Time expenditure on the construction site minimized as well as the modification of the room layout division and dismantling in the event of a later need.

The solution to the problem according to the invention is based on clear production and user-related system specifications. These include:

• - freely selectable floor plan taking into account a minimized outer surface to volume ratio as an important requirement for the building type low energy house,
• - No restriction regarding the grid dimensions for components in any Arrangement taking into account the delivery dimensions of semi-finished products (plates, Isolation material u. a.),
• - Minimization of the constructive variety by using repetitive parts for load-bearing and non-load-bearing walls, ceiling and floor elements and ver ties,
• - Elementary construction with a high degree of integration including equipment with precise connection technology,
• - minimization of the earthwork and foundation work,
• - Monovalent and decentralized energy supply as possible (hot water, hot water tongue).

The fact that these specifications are not related to building in the Central European climate zone, but with minor Have additions adapted for arctic, tropical and arid regions, is specifically pointed out.

The implementation of this system-technical approach results in the following features and advantages of the design according to the invention.

The basic structural elements are double for single and multi-storey buildings. T-beams and sheets of high geometric precision made of homogenized wood (Residual moisture 8%) with excellent rigidity and in the case of the beams with a web thickness of z. B. 10 mm. Porters only less different dimensions are in longitudinal and transverse position in the direction of the wall expansion for the load-bearing external and internal walls and used for non-load-bearing interior walls. The preferred grid dimension guides from the dimensions of the commercially available, covering panels and the the interstices filling thermal insulation materials.

The geometric design of the double-T beams with a thickness of the top and lower flange of z. B. about 40 mm enables wall construction as an advantage three-chamber system. On the outer paneling is a Lathing of the rear ventilation space created. The cover leaves out all freedoms of the known and future exterior front designs. The middle chamber forms approximately in the thickness of the web height of the supporting profile the essential thermal insulation layer. The third chamber, the installation came mer, in the thickness of the flange facing the interior provides in addition to Task of another thermal insulation layer space for all utilities power lines.

In the grid to be adapted, windows of the various fit precisely constructive and thermal variants. The frame contributes to the Aus stiffness of the wall construction.

Floor, ceiling and roof are constructed in almost the same way, with too additional soundproofing can be introduced as required.

The corner and longitudinal connection of walls as well as the horizontal connection of wall / ceiling / floor / roof are designed to be form-fitting, e.g. B. by in a wide longitudinal groove, slightly conical track wood. The complements zende non-positive connection provide accessible and / or locking mechanism that can only be operated during assembly and disassembly men. Both, form and power shot, guarantee the windproofness and the  Solvability, also due to the fact that it cannot be changed over the entire service life Chen dimensional stability of all components. That the ability to change the use of space and simple repairs to complete destruction easy dismantling and thus mobility of the entire building is implemented constructively non-destructively, is another advantage of described construction.

Insulation quality and windproofness lead to a heat transfer coefficient, including walls, floor and roof, of less than k = 0.15 W / m ² , K. This means that the present construction method can be located in the lower range of the low-energy constructions with regard to the energy requirement.

Strip or point foundation types are suitable as the foundation if in the cellar is dispensed with in an economically sensible manner additional space available functionally more advantageous in the building is integrated. The ground floor, possibly also the basement ceiling thermal insulation, are therefore part of the Bauwei invention se. Without a basement, the structure is from below with this embodiment ventilates and the wind loads to be approached are reduced.

From the specific heat requirement of the low-energy house, min at least in the case of a family home, the convenience of a monoval ten, namely exclusively electrical energy supply. In individual cases are the influences of tariff structure, heat storage capacity of the house and the interior, air changes and possible energy management search. It is geared towards energy consumption and comfort supplied low-temperature radiant heating is a preferred solution the heat supply. Heating foil, power supply, bus lines and control tion can be constructed in a structurally simple manner in the installa mentioned arrangement chamber for both original equipment and retrofitting nen. The VDE guidelines Rech worn.

The more technically complex, water-flow tube arrangement he also allows partial air conditioning if in addition to the use of the cooling capacity of the non-heating domestic water a chiller instal is gated.

Also regenerative energy supply technologies (photovoltaics, solar thermal, Geothermal energy) can be coupled into the described basic system. Under The transition to Passi can thus be retained while maintaining the constructive concept vhaus can be easily implemented.

The design of the walls, ceilings and roof meet the requirements of elementary building, namely maximizing the added value in the company brication room and the waste-free final assembly on the construction site. The units to be transported, the dimensions of which are determined solely by the trans port regulations do not only include the supporting structure and Thermal insulation, but also windows, electrical and plumbing u. a. This means that all trades have their essential contribution to prefabrication Afford. During the final assembly, these specialists are only used to connect, to close and commissioning required.

The relevant DIN, VDE, fire and noise protection regulations are met by the appropriate choice of materials and the construction itself. Finally, with a view to an ecological-economic overall bi lance on the complete problem-free disposal ability of the building according to the described construction.

Embodiments of the invention and structural details are in the following drawings are shown, with further details parts are described.

Show it

Fig. 1 shows the structure of the outer wall with the right-angled connection of two outer walls in horizontal section,

Fig. 2, the joints of the corner joint prior to assembly of the two walls, in horizontal section,

Fig. 3 shows a part of a load-bearing interior wall and its connection with an outer wall, in horizontal section,

Fig. 4 is a vertical section through the Deckenauflager, the ceiling and the attached outer wall,

Fig. 5, the three components of Fig. 4 prior to assembly,

Fig. 6, the displacement of two superimposed floors in vertical section,

Fig. 7, the ceiling support with an upper floor ceiling and two Au ßenwandelemente in vertical section.

The horizontal section through the outer corner, on which the outer walls 1 and 2 meet, Fig. 1, illustrates the box-shaped structure of the wall. The wall thickness is essentially formed by the web height of the double T-Pro file 10 and 11 , which differ for reasons to be explained in the flange cross sections. The outward wall side is closed by the vapor-open plate 12 , the inward wall side by the plate sections 13 , which act as a vapor barrier and are glued airtight on the underside of the flange. With this structure, the isolation chambers 3 are formed , the centerpiece of the three-chamber wall structure. The ventilation spaces 4 result with the laths 14 and the stiffening plate 15 , which also accommodates the outer skin (not shown in FIG. 1), the execution of which (e.g. plaster, brick, stone or metal plates, wooden formwork) is left to the client remains. For the components Plattenab sections 13 , laths 14 and 15 plates, the same material is preferably chosen Ma, namely a modified and homogenized wood, which is characterized by an almost constant humidity of about 8%.

This material property, which the carriers 10 and 11 also have, is one of the essential prerequisites for the stability of the dimensional accuracy of the components achieved with industrial prefabrication, even under different environmental conditions (air temperature, humidity) during manufacture, transport, possibly storage and assembly.

The so-called. Installation chamber 5 , the third of the three-chamber structure, and its depth, which results from the thickness of the support flange, completes the plate 17 forming the inner wall of the room. For this, while maintaining a contribution to wall stiffening z. B. a wooden cladding, gypsum plaster or a wallpaper carrier can be selected.

This wall structure, composed of the chambers thermal insulation 3 , rear ventilation 4 and the installation 5 , integrates the functions of carrying, insulating and sealing in a permanently dimensionally stable box structure, in particular by means of the double T-beam, which is dimensioned according to both static and thermal requirements . It follows that infol ge of the glued connection of the carrier 10 and 11 with the plate portions 13 , and this in a corresponding manner by the connection with threshold and frame, the installation chamber 5 against the isolation chamber 3 is completely sealed. Thus, the problem of a draftsy connection of the supply lines (power supply, signal lines, heating, domestic water, gas, central vacuum cleaner) between the interior and the isolation chamber can not occur.

The most sensible choice of beams with different flange cross-sections 10 and 11 (with the same overall height) is derived from the need for increased rigidity where windows interrupt the through wall and with the connection of a second wall a rough shape is formed becomes.

The design of the corner contributes to the necessary rigidity speed and dimensional accuracy of the requirement bill that according to the claim an economically buildable and operated low energy house here too the insulation cross section without any thermal bridges must be carried out commonly.

In Fig. 2, the corner parts 1 and 2 of the outer walls described with Fig. 1 are pulled apart, or shown in an arrangement before assembling. The dividing line or joint runs between the flanges of the carriers 10 'and 10 ''and 10 ''' and 11 '. The butt or Ver connection surfaces are covered with the sealing tapes 20 , consisting of non-rotting material. The projection 21 of the wall 1 formed by the outer wall cladding engages in the offset 22 of the outer wall cladding of the wall 2 , this joint also being covered with sealing tape 23 . The space 24 , Fig. 1, which arises at the connection, is filled with insulation material when assembling the walls 1 and 2 .

The non-positive connection of abutting walls is accomplished, for example, by a device (not shown here) arranged in the surface of the seals 20 . With the help of an external force that can be supplied by an auxiliary device (mechanical, hydraulic, pneumatic, electrical), the wall elements fit together positively and non-positively. Alternatively, a screw connection can also be provided, as shown by the dash-dotted lines 25 and 26 . According to the invention, in the interest of the possibility of dismantling, the connections are permanently secured and releasable.

The horizontal section in Fig. 3 shows in the lower part of the constructive formation from a supporting inner wall, which abuts an outer wall in the upper part. The double-T beam 10 of the same dimensions as in the Außenwän, are here in the interest of a low thickness of the inner walls Längsge. The beams are connected by a threshold and frame. The cover on both sides is provided by boards 30 and 31 , for example wood or gypsum fiber boards. In addition, when choosing the material and the wall thickness, sound-technical aspects can also be taken into account. The spaces 32 between the carrier web and the plate and 33 between the flanges of adjacent carriers are expediently filled with insulating material. Part of the room remains free for better sound insulation. The supply lines 34 can be arranged both in the free and in the area filled with insulating material.

The inner wall described abuts the outer wall 6 in a sound-insulated manner with the insertion of the insulation board 35 . The bilateral insert 36 around the carrier 10 , which is attached to the prefabrication, is necessary for the BEFE stigung the plates 37 and 38 .

For accessibility of the lock between the abutting flanges of the carrier's 10 recesses are provided in the plates 30 and 31 .

The vertical section through the ceiling support 40 , the ceiling 41 and the wall 42 , Fig. 4, shows that the thermal insulation is performed up to close to the outer surface. This also largely applies to the cutting direction rotated by 90 degrees.

The ceiling support 40 , made of modified wood, is designed as a ring threshold, which is placed on the strip foundation or the basement wall 43 and anchored. With the help of the track wood 44 and the counter piece 45 , which is attached to the prefabricated ceiling plate 46 , a dimensionally accurate guide results in the final assembly.

The connection between the ceiling 41 and the wall 42 is constructed in a similar manner with a guide the central web 47 . For the positive connection of these components, the same or similar locking mechanisms are used as described with reference to FIGS. 1 and 2.

As can be seen in FIG. 4, the plate 17 forming the inside of the outer wall stands back in order to ensure the accessibility of the installation chamber and thus the laying of the supply lines. The screwable rubbing strip 48 is provided to cover the circumferential gap.

An exemplary floor structure with crosswise arranged in two layers bearing wood 49 , the floor 50 and the supply lines 51 are additionally shown schematically.

Fig. 5 shows the separation, or the joining together of the components described with Fig. 4. Neither measuring devices nor special joining devices are required for this, but only the known lifting devices with corresponding load-bearing capacity and radius. The elementary construction relocates compliance with the dimensional accuracy to the workshop and clearly specifies the sequence of the final assembly.

In the case of multi-storey buildings, it may be advisable to translate the upper floor, all the way around or only on the weather side, to a small extent, Fig. 6 keep the outside walls away. The offset 60 leads to tearing off and dripping off of the water film which extracts heat from the building. At the same time, this constructive solution provides a rear ventilation 4 on each floor.

The wall opening 61 is provided for a window. The dashed circles 62 and 63 indicate possible web breakthroughs in the double-T beams for laying supply and disposal lines.

The representation of Fig. 7 corresponds to that of Fig. 4, here the Dec kenauflager 70 with an upper floor ceiling 71 and two outer wall elements 72 and 73 is shown. The structure of the floor ceiling 71 corresponds to that of the outer wall, special attention being paid here to sound insulation. The cut 74 runs at right angles through the floor ceiling 71 . The known longitudinal sound transmission of the ceiling through the partitions into the interior is significantly reduced by the present design. The same applies to the transmission between superimposed rooms due to the low web thickness of the double-T girder, which is sufficient in terms of strength with the selected material. All acoustic limits are clearly undercut.

Thermal insulation should be further improved for passive houses this is easily possible. Introduce without new design features The need to have a larger web is simply due to the choice of double-T beams height to increase the thickness of the thermal barrier coating. The for static reasons then the required greater web thickness changes the thermal technology in a first approximation nically decisive ratio of web thickness to height is not.

Claims (8)

1. Constructive and production-oriented design of wall, floor, ceiling and roof elements according to the prefabricated wooden element construction, preferably for residential and commercial construction according to the category of low-energy house, characterized in that the load-bearing and non-load-bearing structural elements of different wall thicknesses largely the same semi-finished products, namely profiled, partially thin-walled carriers, preferably consist of homogenized wood and are covered by plates made of preferably the same starting material, whereby a thin-walled box structure with high rigidity, high thermal insulation and precision is formed. 2. Prefabricated wood element construction according to claim 1, characterized records that the structure of the outer walls an integrated, highly thermally The windproof, three-chamber system forms the rear with the functions ventilation, structure and thermal insulation, and installation of building services Equipment. 3. Prefabricated wood element construction according to claim 1, characterized records that the structure of the load-bearing and non-load-bearing inner walls Thermal and sound-insulating two-chamber system forms with the functions Structure, insulation and installation of building services equipment. 4. Prefabricated wood element construction according to claims 1 to 3, because characterized in that the chamber-shaped structure even when two Exterior wall elements, given inside and outside corners, especially the Insulation cross-section is completely consistent. 5. Prefabricated wood element construction according to claims 1 to 3, because characterized in that in the case of multi-storey buildings, the Au outer walls of a storey, at least on the one exposed to the rain Weather side compared to that of the floor below around the Be are preferred to the outside, which is necessary in order for expiration Rainwater to form a drip edge by the floor and around the floor Fresh air enters for convective airflow through the rear air enable chamber. 6. Prefabricated wood element construction according to claims 1 to 3 and 4, characterized in that for the structural components (parts with load-bearing and seals forming function) such materials are used, the natural origin through a process engineering process acts or were homogenized that they individually and in combination with al len occurring climatic environmental conditions their geometric Ge Maintain accuracy over the life of the construction. 7. Prefabricated wood element construction according to claim 1 to 6, characterized ge indicates that the connection of the wall, floor and ceiling elements form-fitting through an exact geometric positioning in longitudinal and Transverse direction and non-positive by means of the interior in the body-in-white and later accessible and lockable Ver with little effort locking mechanisms are heat and windproof. 8. Prefabricated wood element construction according to claims 1 to 3, because characterized in that the industrial prefabrication according to the principle of the elementary building the supporting structure, thermal insulation, windows, Doors and all lines, control, regulating and distribution devices for Energy and sanitation, air conditioning and communication includes.