FI12286U1 - Pipe shaft element and base floor construction for a building - Google Patents

Abstract

A pipe shaft element (10, 10a) having a first end and a second end, a cavity (12) in the longitudinal direction of the element, in which cavity (12) there is at least one utility water pipe (14, 16, 18) or hot water pipe ( 20, 22) arranged in the element and a heat insulating lid (24) which can be opened which is substantially as long as the cavity (12), characterized in that the tube shaft element (10, 10a) comprises a first side wall (30), a second side wall (32) and an upper wall (34), said side walls (30, 32), upper wall (34) and lid (24) defining the tubular cavity (12), and the first side wall (30) comprising a first edge beam (31). ) and the second side wall (32) comprise a second edge beam (33), said edge beams (31, 33) extending from the first end of the tube shaft element (10, 10a) to the other end of the tube shaft element (10, 10a). In addition, the protection requirements 2-15.

Description

Pipe shaft element and bottom floor structure of the building

The invention relates to a tubular shaft element having a first terminal and a second terminal, which encloses a longitudinal cavity of the element, the cavity having at least one hot water pipe or a heating water pipe attached to the element. The invention further relates to a lower floor structure of a building having at least one pipe shaft element according to the invention.

The apartments in the residential buildings are supplied with cold and warm tap water via tap water pipes. In buildings with a water-circulating heating system, the conduits required by the heating system are additionally supplied with a return and return pipe. In multi-apartment buildings, hot water and hot water inlet pipes are placed side by side into a pipeline to branch water pipes to individual apartments. In buildings with a vented bottom, the pipelines are typically placed in the aeration space below the base and suspended on the underside of the base. The ventilation space is an unheated space, which is why all pipes must be insulated to prevent partitioning. In general, the ventilation space on the underside is additionally shallow and cramped, which makes it difficult and slow to install the pipes. The tubes can also be placed inside the base structure. However, this prevents or at least complicates the use of prefabricated technology in the construction of subfloors, which increases the cost of construction. Inspection and maintenance of water pipes placed inside the underfloor structure always require the dismantling of the underfloor structures, which makes it difficult to detect and repair leakage damage and increase costs.

The object of the invention is to disclose a pipe shaft element and a lower floor structure of a building which can alleviate the problems associated with the prior art.

The objects of the invention are achieved by a shaft shaft element and a lower floor structure of a building which are characterized by what is disclosed in the independent protection requirements. Advantageous embodiments of the present invention are set forth in the dependent claims.

The invention relates to a tubular shaft element having a first pole and a second pole. The pipe shaft element encloses a longitudinal cavity of the element having at least one hot water pipe or a heating water pipe arranged in the element. The element further comprises a heat insulated, removable lid of substantially cavity length. Through the opening cover it is possible to fast and inspect the tube or tubes in the cavity. The heat insulation of the lid ensures that the lamp does not escape from the cavity to the lid blade. In addition, the tubular shaft element encloses a first sidewall, a second sidewall, and a top wall which together define a tubular cavity. The first sidewall encloses the first edge beam and the second sidewall encloses the second edge beam extending from the first to the shaft shaft element to the second shaft of the shaft shaft element. Thus, the tubular shaft element may be supported in bake-bearing structures, such as building foundations. The edge beams have sufficient bending strength so that the tubular shaft element does not need to be supported over the shoulder area. The bending strength of the edge beams may be as high or the bending strength of the first edge beam may be substantially greater than that of the second edge beam. At that time, other building components, such as ventilated underframe beams, can be supported on the first edge beam. Preferably, the first and second edge beams are made of wood or substantially wood-based material.

In a private preferred embodiment of the pipe shaft element according to the invention, the cavity comprises at least a hot water hot water supply pipe, a hot water hot water circulation pipe and a cold hot water supply pipe. Preferably, the cavity further comprises a hot water outlet pipe and a hot water return pipe.

In a second preferred embodiment of the pipe shaft element according to the invention, the cavity has a first bore which opens into the first bore of the pipe shaft element and the freshwater pipes and / or heating water pipes in the cavity have a first bore extending substantially into the pipe shaft element. Preferably, the cavity further comprises a second bar which opens to a second bar of the tubular shaft element and the freshwater pipes and / or hot water pipes in the cavity have a second bar which extends substantially to the plane of the other end of the tubular shaft element. The hot water and heating water pipes in the cavity are thus substantially the same length as the pipe shaft element. The pipe shaft elements can thus be lined up and the hot water and hot water pipes in the cavities can be connected to the bake to form a single pipe with conventional squeeze fittings.

In a private third preferred embodiment of the pipe shaft element according to the invention, at least one hot water pipe or Lammi water pipe in the cavity has a branching piece in the region between the first end and the second end of the pipe shaft element. The branch pipe is connected to the branch piece so that the branch pipe has a first terminal connected to the branch piece and a second terminal extending outside the pipe shaft element. The hot water and heating water pipes of the manhole element are intended to serve as multiple manifolds, from which hot water or hot water is led to different operating points, such as different flats in the building, through branch pipes. Typically, hot and cold domestic hot water is required in each installation, with branch pipes and branch pipes installed in each domestic hot water pipe and in the domestic hot water circulation pipe. If the apartment has a water-circulating heating system, the branch pieces and branch pipes are also installed in the heating water supply pipe and the heating water return pipe. The lengths of the branching pipes are dimensioned so that they extend without joints to the manifolds of the buildings or the ponds. Preferably, the second end of the branch pipe is guided to the outside of the pipe shaft element by a sidewall or top wall blade.

In yet another preferred embodiment, the tubular shaft element of the invention has a top wall and side walls enclosing a layer of insulating material. In this case, all longitudinal walls of the tubular shaft element are heat insulated, which allows the tubular shaft element to be placed in a completely unheated space.

The building base structure according to the invention has a foundation, a heat-insulated load-bearing slab with a base and an edge resting on the foundations. Below the load-bearing slab is a ventilation space. The bottom sole structure has at least one tubular shaft element as described above.

In a private preferred embodiment of the lower base structure according to the invention, the tubular shaft element is hung on the underside of the load-bearing plate so that the lid is limited to the ventilation space.

In a second preferred embodiment of the lower base structure according to the invention, the carrier plate has an upper surface and the tubular shaft element is located at least partially between the upper surface and the lower surface of the carrier plate with the lid limited to the ventilation space. Thus, in this embodiment, the tubular shaft element is located, at least in part, inside the load-bearing plate.

In a private third preferred embodiment of the base structure according to the invention, the tubular shaft elements are supported from the first and / or the second bar to the foundation of the building. The tubular shaft elements thus function in a structured manner, in one direction, as load-bearing, roast-supported tile elements.

In yet another advantageous embodiment of the base structure according to the invention, the load-bearing plate has support beams having an upper edge and the edge beams of the pipe shaft element having an upper edge. The tubular shaft elements are arranged in a load-bearing plate such that the tops of the support beams and the tops of the edge packs are substantially in the same plane. The height and width of the edge beams can be dimensioned to be the same as the height and width of the support beams, so that the edge beams and the support beams have the same bending strength. The edge beams of the tubular shaft element thus serve as support beams for the load-bearing slab in the finished bottom structure.

In yet another preferred embodiment of the base structure according to the invention, the bearing plate comprises support beams having a first pole supported on the foundations and a second pole secured to the first edge beam of the tubular shaft element. The edge beams of the tubular shaft element may be dimensioned to have different bending strengths such that the first edge beam receiving the support beams support reactions has a greater bending strength than the second edge beam.

An advantage of the invention is that it significantly accelerates the installation of hot water pipes and Lammi water pipes in ventilated underfloor structures and allows for an increase in the pre-fabrication rate of the underfloor structures. This shortens the time needed to build subfloors and reduces construction costs.

A further advantage of the invention is that it enables the inspection of hot water pipes and heating water pipes and the maintenance of the pipes after the installation, quickly and without dismantling the structures.

The invention will now be described in detail. With reference to the accompanying drawings, in which Fig. 1a is an exemplary cross-sectional view, Fig. 1b is a cross-sectional view, Fig. 1c is an exemplary cross-sectional view, Fig. 2b shows an exemplary embodiment of the tubular shaft element shown in Fig. 2a, in sectional view AA, Fig. 2c is an exemplary batch view of another bottom floor according to the invention and Fig. 3 is a top view of the bottom floor according to the invention.

Fig. 1a is an exemplary cross-sectional view of a pipe shaft element 10 according to the invention, and Fig. 1b is a horizontal sectional view of the same pipe shaft element in sectional plane A-A. In the following, both pictures are explained simultaneously.

The tubular shaft element is an elongated hollow structural member having a first side wall 30, a second side wall 32, a top wall 34, and a cover 24. The side walls, top wall, and cover are 12. The side walls, the top wall, and the lid are made of a sandwich-type insulating board with a 100 mm thick layer of laminate insulation 36 between two metal plates. The lamellar insulation may be made of polyurethane, polystyrene or mineral wool. The sidewalls are fastened at the front edge to the edges of the upper wall with galvanized metal corner strips and the seams are sealed from the inside with sealing compound. The opening cover 24 is secured at its edges to the other edges of the side walls 30, 32 by fastening screws 25. The cover screws can be completely removed by removing the cover screws so that the cavity 12 is completely open on one side.

Inside the cavity there is a hot water supply pipe 20 and a hot water return pipe 22, as well as a cold water supply water supply pipe 14, and a hot water supply water circulation pipe leading back to the pond room. Hot water inlet pipes are, as they are called, intended for the supply of cold and hot water. The hot water circulation pipe from Lampima is used to return hot water back to the hot water distribution room. The first tubes of the tubes are flush with the first end of the tube shaft element and the second tubes of the tubes are flush with the second end of the tube shaft element, i.e. the tubes and cavity 12 are of equal length. The tubes may be made of plastic, composite material or metal such as copper or steel. The outer surface of the tubes has a tube insulation which may be mineral wool, polyurethane or cellular plastic. The tubes are supported by tube supports 21 on select supports 35, which are secured to the side walls 30, 32 of the frying pan.

In the area between the first and second ends of each pipe there is a branching piece 26 to which a branching pipe 28 is attached. The first end of the branching pipe is secured to the branching piece and the second end is guided outside the second side wall of the tubular element. Branching pipes along the hot water as well as cold and hot water can be supplied from the hot water inlet pipes and the hot water supply pipe to the apartments, and the hot circulation water and the cooled hot water can be returned from the apartments to the hot water circulation pipe and hot water return pipe.

Fig. 1c is an exemplary cross-sectional view of a bottom sole structure according to the invention. The base structure is so called. a ventilated bottom with a heat-insulated load-bearing slab 102, below which is a ventilation space 106. The load-bearing slab has a lower surface 104, an upper surface 105, and a base resting on the foundations (not shown in the figure). In the space between the lower surface and the upper surface, there are support beams 108 and a lamella insulation layer 36. The tubular shaft element 10 described in Figures 1a and 1b is suspended on the underside of the carrier plate so that the cover 24 is limited to the ventilation space. The individual tubular shaft elements can be formed into a longer pipeline by queuing the tube elements and connecting the tubes of the tubes of the successive tubular tube elements to one another by means of suitable connecting means, such as squeeze fittings. To make pipe joints, the pipe shaft element cover 24 is opened, whereby the joints can be made from the ventilation space. The height of the ventilation space, i.e. the distance between the lower surface 104 of the bearing slab and the surface 110 of the ground, must of course be large enough to accommodate the ventilation space. The opening opening of the pipe shaft element allows for checking and maintaining the functioning of the pipes and joints in the cavity, even after installation, for example in the case of annual outages.

Fig. 2a shows, by way of example, a preferred embodiment of the pipe shaft element according to the invention in cross-sectional view, and Fig. 2b shows the same element in horizontal section through the section plane A-A. In the following, both pictures are explained simultaneously.

2a and 2b, the pipe shaft element 10a embodiment has the same structural parts as the one described in Figures 1a and 1b, and the same names and reference numerals are used throughout the description. The embodiment shown in Figures 2a and 2b differs from the element shown in Figures 1a and 1b in that the side walls 30, 32 and the top wall are not made of sandwich-type insulating board. Instead, the first side of the tubular shaft element has a first edge bar 31 and a second edge bar 33, which form the side walls of the tubular shaft element. Between the edge beams there is a trough formed of a metal plate, the entire length of the shaft shaft having a bottom 38, a first side 39 and a second side 40. The first side of the trough engages with the first edge beam and the second side with the second edge beam. Between the edge beams, on the other side of the base, there is a lammon dielectric layer 36. The cover 24 is a plate-like portion of substantially the entire length of the cavity secured by fastening screws 25 to the bottom edge of the edge beams. The lid is made of an insulating board with a layer of laminate insulation between two metal sheets.

The bottom and sides of the gutter and the openable lid that closes the open side of the gutter define a tubular cavity 12 having a hot water inlet pipe 20, a hot water return pipe 22, a hot water inlet water inlet 14, 1a and 1b and are supported by tubular brackets on a support bracket 35 connecting the trough sides 39, 40 to one end of the branching tubes 28 through holes drilled in the other edge beam 33 outside the cavity 12.

Fig. 2c is an exemplary cross-sectional view of a preferred embodiment of the bottom sole structure according to the invention. The base structure is so called. a ventilated bottom with a heat-insulated load-bearing plate 102, below which is a ventilation space 106. The load-bearing plate has a lower surface 104, an upper surface 105, and a base resting on the foundations (not shown). In the space between the lower surface and the upper surface there are support beams 108 and a lamella dielectric layer 36. In this embodiment, the lower base structure has tubular fiber elements shown in Figures 2a and 2b partially disposed between the upper and lower surface of the carrier slab. The tubular shaft elements 10a are arranged in a bearing plate such that the upper edges of the support beams 108 and the upper edges of the edge beams 31, 33 are substantially in the same plane. The height and width of the edge beams are dimensioned to be the same as the height and width of the support beams, so that the edge beams and support beams have the same bending strength. The edge beams of the tubular shaft element serve as support beams for the load-bearing slab in the finished bottom structure. The building board on the top surface of the load-bearing slab is fixed to the top surface of the supporting beams and edge beams.

Also, in this embodiment, the individual tubular member may be formed into a longer pipeline by queuing the tubular elements and connecting the boats of the successive tubular member tubing to each other by suitable connecting members, such as squeeze fittings. To make pipe joints, the pipe shaft element cover 24 is opened, whereby the joints can be made from the ventilation space.

Fig. 3 shows an exemplary bottom sole structure according to the invention in a top view. The bottom floor structure shown in the picture is the bottom floor of a terraced house with three apartments. The underfloor structure includes a foundation 100 that runs along the exterior wall line of the building and along the wall line between the apartments. On the foundations, there is a bearing plate 102 formed of lower base elements 120 and tubular shaft elements 10a. The lower base structure shown in the figure has three tubular elements 10a arranged in the lower base so that they form a uniform pipeline throughout the building. The first pipeline in the pipeline is the building's larder room 130, to which the pipeline pipe boats are led. Each apartment in the building has a manhole element 10a, from which branch pipes for heating water pipes and hot water pipes are led to 28 apartments. Pipe shaft elements are always manufactured and dimensioned to suit each construction site. Thus, for example, in Fig. 3, the pipes and cavity of the tubular element at the other end of the pipeline need not extend to the bad leaning on the foundation of the outer wall of the tubular element, but suffice for the cavity and its inner tubes to extend to the outlet. Likewise, the pipes of the manhole element extending to the flocking room are provided with riser pipes connecting to the flocking equipment and the water supply.

Each tubular shaft element is supported on the foundation of the building, making them functionally structurally similar to load-bearing tile elements. The first longitudinal side of the bottom sole structure has bottom sole members which rest on the first curb foundation and on the second cantilever the first edge beam. The first edge beam is dimensioned so that it has sufficient bending and shear resistance to carry the loads from the lower base members. On the other longitudinal side of the base structure there are base elements, which, like the tubular shaft elements, rest on both sides of the foundation of the building.

Advantageous embodiments of the inventive tubular shaft element and the lower floor structure of the building have been described above. The invention is not limited to the solutions described above, but the inventive idea can be applied in various ways within the scope of the protection requirements.

Claims (15)

protection Requirements 1. The rorschaktelement (10, 10a), som har en forsta give och en andra give, en halighet (12) i elementets langdriktning, i wanna halighet (12) det finns atminstone et bruksvattenror (14, 16, 18) eller varmevattenror ( 20, 22) anordnat i elementet och et varisisererat lock (24) som kan oppnas, som vasentligen ar lika langt som haligheten (12), kantetecknat av att rorschaktelementet (10, 10a) dartill omfattar en forsta sidovagg (30), en andra sidovagg (32) och en ovre vagg (34), wolf sidovaggar (30, 32), ovre vagg (34) och lock (24) avgransar den rorlika haligheten (12), och den forsta sidovaggen (30) omfattar en forsta kantbalk (31) ) och den andra sidovaggen (32) omfattar en andra kantbalk (33), lively kantbalkar (31, 33) stracker sig fran rorschaktelementets (10, 10a) andsta giving till rorschaktelementets (10, 10a) andra giving. A pipe shaft element (10, 10a) having a first terminal and a second terminal, a longitudinal cavity (12) of the element having at least one freshwater pipe (14, 16, 18) or a hot water pipe (20, 22) arranged in the element. ) and a heat-insulated openable lid (24) of substantially cavity (12) length, characterized in that the tubular shaft element (10, 10a) further comprises a first side wall (30), a second side wall (32) and a top wall (34). ), a top wall (34) and a cover (24) defining a tubular cavity (12) and a first side wall (30) defining a first edge beam (31) and a second side wall (32) defining a second edge beam (33) extending from the edge beams (31, 33). a first shaft of the shaft shaft element (10, 10a) to a second shaft of the shaft shaft element (10, 10a). Rorschaktelement (10, 10a) enligt skyddskrav 1, kantetecknat av att i haligheten (12) finns atminstone et inloppsror (14) for karmut bruksvatten, for circulation (16) for karmt bruksvatten and for inloppsror (18) for kallt bruksvatten. Pipe shaft element (10, 10a) according to claim 1, characterized in that the cavity (12) comprises at least a hot water supply pipe (14), a hot water supply pipe (16) and a cold water supply pipe (18). Rorschaktelement (10, 10a) enligt skyddskrav 1 eller 2, a lidecknat av att i haligheten (12) finns dartill et utloppsror (20) for auxiliary and a returror (22) for auxiliary. Pipe shaft element (10, 10a) according to claim 1 or 2, characterized in that the cavity (12) further comprises a hot water outlet pipe (20) and a hot water return pipe (22). 4. Rorschaktelement (10, 10a) enligt nagot av skyddskraven 1-3, kantetecknat av att haligheten (12) har en forsta giving, som oppnar sig i rorschaktelementets (10, 10a) forsta giving, and bruksvattenroren (14, 16, 18). och / eller varevattenroren (20, 22) i haligheten (12) har en forsta giving, som stracker sig vasentligen till Nivan av rorschaktelementets (10, 10a) forsta giving. Pipe shaft element (10, 10a) according to one of the claims 1 to 3, characterized in that the cavity (12) has a first piston which opens into the first piston of the pipe shaft element (10, 10a) and in the supply tubes (14, 16) in the cavity (12). , 18) and / or the hot water pipes (20, 22) have a first pole extending substantially to the first end plane of the pipe shaft element (10, 10a). 5. Rorschaktelement (10, 10a) enligt nagot av skyddskraven 1-4, kantetecknat av att haligheten (12) har en andra giving, som oppnar sig i rorschaktelementets (10) andra giving, och bruksvattenroren (14, 16, 18) och / eller verification (20, 22) i haligheten (12) har en andra giving, som stracker sig vasentligen till Nivan av rorschaktelementets (10, 10a) andra giving. Pipe shaft element (10, 10a) according to one of the claims 1 to 4, characterized in that the cavity (12) has a second shaft which opens into the second shaft of the pipe shaft element (10) and in the drinking water pipes (14, 16, 18) and / or the heating water pipes (20, 22) have a second pole extending substantially to the plane of the other end of the pipe shaft element (10, 10a). 6. Rorschaktelement (10, 10a) enigt node av paneldskraven 1-5, kittecknat av attminstone et bruksvattenror (14, 16, 18) eller verevattenror (20, 22) i haligheten (12) har et forgreningsstycke (26) i omradet mellan rorschaktelements (10, 10a) forsta give och andra give, till vilket forgreningsstycke (26) har kopplats et forgreningsror (28), sa att forgreningsroret (28) har en forsta give kopplad till forgreningsstycket (26) och en andra give som stracker sig utanfor rorschaktelementet (10, 10a). Pipe shaft element (10, 10a) according to one of the claims 1 to 5, characterized in that at least one hot water pipe (14, 16, 18) or hot water pipe (20, 22) in the cavity (12) has a branching element (26). 10a) in the region between the first end and the second end, to which the branch pipe (28) is connected with a branch pipe (28) having a first terminal and a second terminal extending outside the pipe shaft element (10, 10a). The rorschaktelement (10, 10a) of the genomic sidovaggen (30, 32) eller den Ovre vaggen (34). Pipe shaft element (10, 10a) according to claim 6, characterized in that one end of the branch pipe (28) is guided outside the pipe shaft element (10, 10a) by a flap of a side wall (30, 32) or a top wall (34). The rorschaktelement (10, 10a) of the embodiment shown in FIGS. 1-7, which can be applied to the housing (34) and sidovaggarna (30, 32) omfattar et varmeisoleringsskikt (36). Pipe shaft element (10, 10a) according to one of the claims 1 to 7, characterized in that the top wall (34) and the side walls (30, 32) enclose the lammonium barrier layer (36). The rorschaktelement (10, 10a) of the first panel (8), the panel of the panel (8), the panel of the panel (8), the panel of the panel (31), the panel of the panel (31). Pipe shaft element (10, 10a) according to one of the claims 1 to 8, characterized in that the bending resistance of the first edge beam (31) is substantially higher than that of the second edge beam (33). The rorschaktelement (10, 10a) of the invention (9, 10a), respectively, comprising a panel (1, 9, 9), a frame member (31, 33) or a frame assembly of a material. Pipe shaft element (10, 10a) according to one of the claims 1 to 9, characterized in that the first and second edge beams (31, 33) are made of wood or a material substantially wood-based. 11. En Byggnads nedre bottenstruktur, som har en grund (100), en varisisolerad barande platta (102), som har en nedre yta (104) och en mot grunden (100) stodande kant, och ett ventationsutrymme (106) under den barande Plattan (102), the cantilever is shown in the frame structure (10, 10a), the node or panel 1-10. 11. A lower base structure of a building having a foundation (100), a heat-insulated carrier tile (102) having a lower surface (104) and an edge supported by the foundation (100) and a ventilation space (106) below the load-bearing plate (102), characterized in that said lower base structure having at least one tubular shaft element (10, 10a) according to any one of claims 1-10. 12. The structure of the panel 11, the lid of the panel (102), the housing (105) and the plate (10, 10a), or the placenta of the panel (102) of the panel (102). nedre yta (104), sa att Locket (24) avgransas mot ventilationsutrymmet (106). The lower base structure according to the protection claim 11, characterized in that the load-bearing plate (102) has an upper surface (105) and a tubular shaft element (10, 10a) located at least partially between the upper surface (105) and the lower surface (104) of the load-bearing plate such that the lid (24) is limited to the ventilation space (106). The Nedre bottenstruktur enligt skyddskrav 11 eller 12, kannetecknad av att rorschaktelementet (10, 10a) ar Stott vid sin forsta give and / eller sin andra give vid byggnadens Grund (100). 13. A base structure according to claim 11 or 12, characterized in that the tubular shaft elements (10, 10a) are supported on the first and / or the second pillar on the foundations (100) of the building. 14. Nedre bottenstruktur enligt nagot av skyddskraven 11-13, kantetecknad av att den barande Plattan (102) har barande balkar (108), som har en Ovre kant, och rorschaktelementets (10, 10a) kantbalkar (31, 33) har en Ovre kant, och rorschaktelementen (10, 10a) or anordnade i den barande Plattan (102) sa, att de barande balcarn (108) Ovre kanter och cantaloquarn (31, 33) Ovre kanter or vasentligen pa samma plan. Base structure according to one of the claims 11 to 13, characterized in that the bearing plate (102) has support beams (108) having an upper edge and the edge beams (31, 33) of the tube shaft element (10, 10a) and tube tube elements (10, 10a). ) is arranged in a bearing plate (102) such that the tops of the support beams (108) and the tops of the edge packs (31, 33) are substantially in the same plane. A bottom sole structure according to one of the claims 11 to 14, characterized in that the bearing plate (102) comprises support beams (108) having a first pole supported on the foundations (100) and a second pole secured to the tubular fiber element (10). 10a) to the first edge beam (31). Skyddskrav 15. Nedre bottenstruktur enligt nagot av skyddskraven 11-14, kannetecknad av att den barande Plattan (102) har barande balkar (108), som har en forsta giving, som ar stodd mot grunden (100), och en andra giving, som ar fast vid rorschaktelement (10, 10a) forsta kantbalk (31).