NO885268L - SELF-DRILLING SCREWS. - Google Patents

Description

The invention relates to a self-drilling screw with a screw shaft which has an operating end and a screw tip and with at least two threaded sections, one of which starts from the screw tip.

Such a screw is already known. It has two sections with different diameters, and both threads are designed as wooden threads. With such screws, formwork structures or the like can be attached at a distance to a base or a support structure. A prerequisite, however, is that the structures placed at a distance from each other are already fixed. When using the known screw, the structural part to be attached must be provided with finished bores. This means additional work operations, which lead to an increase in the cost of such fastenings. For fixing lath constructions or the like at a distance from a support element, it is known to use screws where the screw head is connected in one way or another to the construction part to be fixed, so that by turning the fixing screw an adjustment can be achieved. In this connection, there are screws where a rotatable sleeve is placed immediately behind the head (DE-OS 35 40 413), or screws where the screw shaft behind the head has a thread without pitch, formed by several circumferential ribs. With these so-called adjustable distance screws, the screw is inserted into a drilled hole in the construction part to be fixed, and is then screwed into the substructure. The force exerted in the axial direction will pull the sleeve or rib part of the screw shaft into the bore in the structural part to be fixed. As soon as the screw is pulled in deep enough, so that it does not protrude, by turning the screw to the left, the construction part can be moved out from the base, until it has reached the desired position. In this way, you can carry out an adjustment using only the fixing screw without additional aids. However, in the case of construction parts with large surfaces or large lengths, such adjustable distance screws must be screwed in at all places where such a screw is to sit, and the adjustment can only take place after all screws have been screwed in. If, for example, for reasons of stability, it subsequently turns out that the space between two screws must be supported, then this is no longer possible with such adjustable screws, because screwing in will cause the element to be pulled in the direction of the substrate.

The purpose of the invention is to provide a self-drilling screw, which has a simple structure and is cheap to manufacture and makes it possible in a quick and simple way to fasten a frame element and the like placed at the desired position distance to a substrate, without the fastening occurs, a tension or other stress on the element in the direction towards the substrate. Assembly must also be possible without the use of additional aids. A self-drilling screw is here understood to be a screw that has a wood thread or a similar thread, i.e. threads that, under a certain amount of pressure, will screw themselves into the wood.

To achieve this, according to the invention, a screw is proposed where a threaded section extends all the way to the operating end of the screw, and where both threaded sections have the same pitch and the same outer diameter. As both threads have the same outer diameter, additional pre-drilling of the frame structure to be attached is avoided. For example, if the screw has a normal diameter of 6 mm, it will in many cases be possible to screw the screw directly into the wood in the frame or another structural part that is to be fixed at a distance to the substrate, without the use of a pre-drill. If pre-drilling is necessary, this can be done both in the frame as well as in the substrate, because the screw basically has the same diameter everywhere. Due to the fact that both thread sections, i.e. both the thread section in the area at the drill tip as well as the thread section in the area at the operating end have the same pitch, the penetration of the screw into both the structural part and the substrate will occur at the same speed, so that no force is exerted on the structural part in the direction towards the substrate or away from the substrate. The construction, on the other hand, is retained and fixed in its position, despite the distance between the construction part and the substrate, solely because of the thread in the area at the screw's operating end. A tension-free distance assembly is thus achieved.

In particular, the screw can be such that its operating end has a screw head, preferably a countersunk head. This head is drawn into the wood in the structural part, despite the fact that no force is exerted against the structural part as such. To improve penetration, the screw head can be provided with ribs, cutting edges or the like on its underside.

According to a further development of the invention, both threaded sections can be separated by a thread-free section, the length of which is preferably at least 2 mm.

According to a further development of the invention, both thread sections can be mutually phase-shifted, so that the thread in one section does not represent a geometric continuation of the thread in the other section. Furthermore, the thread-free section can be approximately cylindrical in design. The diameter can preferably be larger than the core diameter in the threaded sections. In contrast, the outer diameter of the thread is advantageously larger than the diameter of the unthreaded section. In particular, the diameter in the unthreaded section can correspond to the flank diameter of the threaded sections. According to a further development of the invention, the threaded section placed at the operating end of the screw can have an axial length independent of the total screw length. The axial length for the screw head thread section is advantageously chosen so that it roughly corresponds to the normal thickness of the structural part to be attached. This means that for screws intended for fixing window or door frames, the axial length of the screw head thread section will be approximately 50 mm, which is a common thickness for window and door frames.

If, on the other hand, the screws are used for fixing formwork, plate constructions or the like, then the screw head thread section is advantageously given a length corresponding to the usual thickness of such construction parts, i.e. around 25 mm.

While the axial length of the thread section at the screw head is independent of the screw's total length, it is proposed according to the invention that the axial length of the thread section at the screw tip should be dependent on the screw's total length, at least to a certain extent.

According to the invention, the thread-free section can advantageously have a length which is dependent on the length of the screw.

The invention also proposes the use of a described screw as a screw for fixing formwork, plate or frame constructions or the like made of wood or plastic, at a distance from a substrate. This screw can in all cases be used when the screw can engage directly in the substrate, i.e. no dowel is required in the substrate. The substrate can be wood, but aerated concrete is also a relevant material. Concrete can also be a substrate material, when suitable screws are used.

The invention also relates to a method for attaching formwork, plate or frame constructions or the like made of wood or plastic at a distance from a substrate of such material. According to the invention, a structural part, i.e. for example a window frame, is held against the base and brought into the desired position on this. Then screws of the new type are inserted for fastening in as many places as are deemed necessary. If the screws are small enough (diameter), they can simply be screwed in with a screwdriver, until the head is flush with the front or upper side of the frame. This is possible even in places where it was not previously intended to insert screws. In total, when using the same number of screws, the costs for fastening the frames are lower, because the screws proposed according to the invention have a simple structure.

In particular, it will advantageously be possible for the initial adjustment of a plate structure to adjust these using adjustable distance screws, for example according to DE-OS 35 40 413. The plate structure is therefore screwed to the substrate using a small number of such screws, as the screws are tightened so that their pitch-free thread sections are drawn into the wood. The plate construction is then brought to the desired position by turning these few screws to the left, i.e. the plate construction is brought to the desired vertical or possibly horizontal position. Then screws according to the invention are screwed in between the already existing spacer screws. This entails the further advantage that the adjustment is also simplified, because during the adjustment one only needs to influence a significantly smaller number of screws than if the frame were to be fixed in all places with adjustable screws. The working hours per attachment of a plate construction is thus reduced, so that the total constants can thereby be further reduced.

Further features, details and advantages of the invention will emerge from the patent claims, the subsequent description of a preferred embodiment of the invention, as well as from the drawings, where: Fig. 1 shows a view of a screw according to the invention, fig. 2 shows a side view of a modified screw head, and fig. 3 schematically shows the use of the screw for

attachment of a frame.

The one in fig. 1 shown screw has a screw shaft 11 if in fig. 1 lower end is designed to be pointed and forms a screw tip 12. The other end, the operating end 13, is used to actuate the screw to screw it into the wood or plastic. In the present example, the operating end 13 has a screw head 14 designed as a countersunk head.

The screw shown has a first thread section 15 which extends from the screw tip 12 and over approximately 2/3 of the screw shaft 11's total length. In this threaded section 15, the screw is provided with a normal right-hand thread 16. With the help of this thread, the screw can be screwed into a wooden substrate.

After this threaded section 16 follows a cylindrical section 17, i.e. the screw shaft 11 has no threads there. This unthreaded section is significantly shorter in the design example than the threaded section 16. In this area, the screw shaft 11 is, as mentioned, unthreaded and therefore has a cylindrical outer surface with a uniform diameter. After this thread-free section 17, a second thread section 18 follows towards the screw head 14 where the shaft 11 has a thread 19. This thread practically extends all the way to the underside 20 of the screw head 14. The thread 144 in the first thread section 15 and the thread 19 in the second thread section 18 has the same pitch and also the same outer diameter and the same core diameter. However, it is not necessary that the screw lines in the two threads match, i.e. form extensions of each other. In other words, a phase shift between the two gangs is possible and permitted.

As can be seen from the drawing figure, the diameter of the thread-free section 18 is somewhat larger than the core diameter of the two threaded sections 15,18, but considerably smaller than the outer diameter of the threads.

In fig. 1, a frame structure 21 and a base 22 are indicated. The frame structure 21 can for example be a window frame. The mutual arrangement of the frame and the base 22 is such that the screw is completely screwed in. The threaded section 15, which goes out from the screw tip 12, is thus assigned to the substrate 22, while the threaded section 18 which is located by the operating element is assigned to the frame 21. If the frame must be fixed at a greater distance from the substrate 22, then a correspondingly longer screw is used . In the case of such a longer screw, however, the threaded section 18 need not be longer, but can have the same length. This length is usually determined only by the usual thickness of the window frame. Fig. 2 shows on a larger scale a second embodiment of a screw, where the underside 20 of the screw head 14 has several approximately radially extending grooves 23. The grooves 23 are limited on the respective rear sides - the arrow 24 shows the direction of rotation - by surfaces 25, which form cutting edges 26 together with the underside of the screw head 20. Such a screw head is certainly known, but this special design of the underside of the screw head is particularly advantageous in connection with the new screw proposed here. Fig. 3 shows in the form of five sketches in a simplified manner how a frame 21 can be attached to a wooden substructure 22. To simplify everything, only a single section of the frame 21 is shown. As shown in sketch A, the frame is placed on the correct place and is fixed with the help of two adjustable distance screws 27. The adjustable distance screws 27 are, possibly after pre-drilling, tightened with the help of a screwdriver. The screws will press the frame 21 against the base 22. With further tightening, the sleeves or ribs on the shaft in the area at the heads of the spacer screws will be pulled into the wood or plastic in the frame 21. You then get the one in fig. situation shown in 3b, where the adjustable spacing screws 27 are pulled into the frame. Now the frame must be adjusted. First, it is turned in fig. 3 upper adjustable distance screw 27 counter-clockwise. When the head or shaft of the screw is held in the frame, the frame 31 will remove itself from the base 22 in the upper area, as shown in fig. 3c. Then also turn the lower adjustable distance screw 27 anti-clockwise, until the frame has obtained the correct plumb position, see fig. 3d.

However, since the total length of the frame 21 is too large for the two spacer screws 27 to provide sufficient fastening, the space between them must be secured. This happens by screwing in one or more, in this case three screws 28 designed according to the invention. This situation is shown in fig. 3rd. The screws can be screwed in easily, possibly without pre-drilling, and they will not cause the frame to bend in one direction or another. Screws according to the invention can also be inserted in such places where one had not previously intended to have any screws, so that one thus gets a more universal applicability, which gives further advantages.

Incidentally, the use of several adjustable distance screws 27 would complicate the adjustment, because in that case one would have to carry out step-by-step co-adjustment of all the adjustable distance screws.

Instead of the combined use of adjustable and non-adjustable distance screws, it will of course also be possible to place the frame 21 in the one in fig. 3d showed position by means of other means and then fix the frame exclusively by means of the non-adjustable distance screws proposed by the invention.

If you denote the total length of the screw by L, the length of the thread section in the area at the screw head 14 by A and the thread section at the screw tip 12 by B, the table below shows that for all applicable cases you will be able to manage with a relatively low number of screws. All lengths here are 1 mm. The screw diameter, i.e. the outer thread diameter, is preferably 6 mm, but can, however, also be in the range from 5-7, possibly from 4-8 mm.

Claims (18)

1. Self-drilling screw with a screw shaft (11) with an operating end (13) and a screw clamp (12), and with at least two threaded sections (15,18), of which one threaded section (15) exits from the tip (12), characterized in that the second thread section (18) extends all the way to the screw's operating end (13) and both thread sections (15,18) have the same pitch and the same outer diameter. 2. Screw According to claim 1, characterized in that the operating end (13) has a screw head (14), preferably a countersunk head. 3. Screw according to claim 1 or 2, characterized in that the two threaded sections (15,18) are separated from each other by a thread-free section (17). 4. Screw according to one of the preceding claims, characterized in that the two thread sections (15,18) are mutually phase-shifted. 5. Screw according to claim 3 or 4, characterized in that the thread-free section (17) is approximately cylindrically designed. 6. Screw according to one of claims 4-5, characterized in that the thread-free section (17) has at least a length of approx. 2 mm. 7. Screw according to one of claims 3-6, characterized in that the diameter of the thread-free section (17) is larger than the core diameter of the threads (16,19). 8. Screw according to one of claims 4-7, characterized in that the diameter in the thread-free section is smaller than the outer diameter of the threads (16,19). 9. Screw according to one of the preceding claims, characterized in that the threaded section (19) placed at the operating end (13) has an axial length which is independent of the total screw length. 10. Screw according to claim 9, characterized in that the axial length of the thread section (19) at the operating end (13) is chosen so that it corresponds approximately to the usual thickness for the structural parts to be fixed. 11. Screw according to one of the preceding claims, characterized in that for screws for fastening window frames or the like, the axial length of the threaded section (19) at the operating end is approximately 50 mm. 12. Screw according to one of the claims 1-10, characterized in that in the case of screws for fixing formwork or the like, the axial length of the threaded section (19) at the operating end (13) is approximately 25 mm. 13. Screw According to one of the preceding claims, characterized in that the threaded section (15) arranged at the screw tip (12) has one of the screw's lengths At least a regionally dependent length. 14. Screw according to one of the preceding claims, characterized in that the threadless section (17) has a length that is at least partially dependent on the length of the screw. 15. Use of a screw according to one of claims 1-14 as a screw for distance mounting of formwork, plate or frame constructions or the like made of wood or plastic, at a distance from a substrate. 16. Method for fixing formwork, plate or frame constructions or the like made of wood or plastic at a distance from a substrate, characterized in that the structure is held in front of the substrate, brought into the desired position and then fixed with screws (28) according to one of the claims 1- 14. 17. Method according to claim 16, characterized in that the structure to be fixed is brought to the desired position by screwing it to the substrate (22) using a sufficient number of adjustable distance screws (27) for the geometric fixation and then adjusting it using these adjustable distance screws (27). 18. Method according to claim 17, characterized in that the screws (28) are screwed into the space between the adjustable distance screws (27).