NO154892B - FRAME FOR BUILDING ELEMENTS - SPECIAL DOORKARM. - Google Patents

Description

In the production, storage and handling of standardized building elements, including door frames, it is important that these are easy to assemble, that they are as stable as possible, while at the same time the number of required variants is kept as low as possible and can be used for several application options.

This is especially important for door frames, since the door industry today largely wants to use symmetrical components.

With the help of symmetrical fittings, the door leaf and door frame can today be stored separately and the direction of the door is only determined when the frames are assembled together with the door leaf. Can you use several types of thresholds, e.g. flat threshold, slot threshold, etc. together with the standard long arm and top pieces, you can thus also reduce the retailers' or users' inventory to a minimum, while the manufacturer can increase his series sizes and reduce the necessary inventory, which improves the economy in the entire chain from producer to consumer.

The traditionally manufactured frame has a tenon/slot connection.

In order for such a frame to be symmetrical, the rebate in the top piece and threshold must be equal, and this means that the threshold (which is made of expensive, hard materials) must be made of thicker materials than necessary, which makes the product more expensive and makes the threshold higher, which is not desirable. And if such a frame uses a flat threshold, you can no longer use the same long frame, but must make a special long frame with a different slot for this purpose. The same applies if you are not going to use a threshold at all.

Different methods have been developed to avoid these problems, for example connections with center pins and joint blocks. Another method is described in NO patent no. 136 218. Here the pin has been removed in the long frame. The top piece is tapered and contains a milled groove that will take up the long frame's rebate projection. The threshold is counter wedged and lies between the long frames without any corresponding step-off as in the top piece.

What characterizes the properties of the different methods is that the tenon/slot connection is far more stable and therefore easier to handle and transport without damage, while, for example, the last described method manages with fewer variants. However, it is not easy to assemble and falls apart more easily during transport and assembly before it is nailed to the wall. As the door leaves are often transported with assembled frames lying horizontally in high pallets, transport damage is relatively frequent.

Present inventions retain all the advantages of the same component covering several areas of use while ensuring significantly better stability both during assembly and handling. The invention involves a special "locking device" of the corner connections which means that the sub-components will not be pushed apart during transport and storage.

The invention thus relates to the features specified in the characterizing parts of the patent claim.

In addition to the above mentioned advantages, frames according to the patent claim are cheaper to produce than other symmetrical frames. This is because during the production process you can use standard double tapping machines in series with the profile planer and make all corner connections automatically in the same production gate without interruption, something you cannot otherwise do. The frame's "lock connection" also requires less time when nailing together, as not so many nails are needed to ensure stability during transport and handling.

The profile of the frame can be easily dimensioned so that with a normal construction saw you can easily change a frame with, for example, 92 mm width to, for example, 68 or 72 mm or other desired widths. This entails a significant simplification of stock levels and series sizes.

Reference is made to the drawings which show a preferred embodiment

of the invention where fig. 1 preferably shows a side carmel element with a raised profile projection 3 and where fig. 2 preferably shows a top piece for the frame. Fig. 3 shows a joined corner connection.

The side frame with raised profile protrusion 3 is straight cut off with a recess 4 which is taken out over the entire width of the frame, preferably in a width of 4 - 10 mm and with a depth of 2 - 5 mm,

so that the frame ends with two end faces.

The corresponding top piece for the frame is also provided

with a similar profile projection 3 as the side frame and is provided with a recess 5 preferably in the entire depth of the frame.

The width of the cut-out corresponds approximately to the width of the profile projection 3 and the distance from the end surface 9 of the frame element or top piece to the end surface 6 in the cut-out 5 preferably corresponds to the thickness of the corresponding frame element with the profile projection 3. The frame element as shown in fig. 2 is further provided with projections 7 on each side of the milling cut-out 5. These projections are further provided with an elevation 8 with a height of preferably 2-5 mm and a width of preferably 4-10 mm, which elevation 8 fits the milling cut-out 4 in the corresponding frame element.

It will be understood that the top piece can be designed as the side element described here and that the side element can be designed as the top piece described here.

By joining the frame elements described here is achieved

a stable corner connection which is locked in all directions and which can easily be nailed together during assembly, for example.

Claims (1)

Frame for building elements - especially door frames - designed so that the individual parts are symmetrical and can be used for both impact directions which allow the use of different types of thresholds, such as e.g. profile projection (3) is cut straight off with a milling cut (4) taken out over the entire width of the frame so that the frame element ends in two end surfaces and that the corresponding frame element is provided with a milling cut (5) preferably in the entire depth of the element and with a width as in essentially corresponds to the width of the profile projection (3) and with a distance from the frame's end surface (9) to the end surface (6) which essentially corresponds to the thickness of the associated first element and with a projection (7) preferably on both sides of the milling out (5) with elevations (8) that match the milling (4) in the corresponding first frame element.