NO328381B1 - Door or window welding with a fall rudder - Google Patents

Abstract

There is a downcomer (1) in a door or window lock. which is rotatable with a handle square pin (11). and which is made of a somewhat elastic material ,. preferably entirely or almost entirely of plastic or similar material. For fitting the square pin (11), the downcomer (1.) has a somewhat undersized in relation to the square pin ,. substantially square hole (2), as well as at or near this hole an elastic area which springs to the side when mounting the square pin (11). The elastic area around the hole (2) for the square pin comprises the limiting surface of the hole and at least one, preferably at least two cavities (7, 8) arranged near this surface in the downcomer (1).

Description

The invention relates to a door or window lock according to the preamble of patent claim 1.

The bolt or bolt in a door or window lock is usually operated with a handle, which is manually turned 15 - 60° to pull the bolt or bolt into the lock box. The handle is usually horizontal in its initial position. In order to provide an overall well-functioning and robust door operating device, it is important that the clearance between the square pin and the handle as well as the clearance between the square pin and the lock's drop tube is as small as possible. Even a small clearance is often perceived by the user as a circumstance that reduces the product's quality.

The clearance between the square pin and the downpipe is almost always relatively large in known locks. This is due to, among other things, that the lock manufacturer is usually different from the handle manufacturer. The square pin is normally square in cross-section and has a nominal dimension of 8 x 8 mm. In practice, however, the dimension of the square pin is usually somewhat smaller than the nominal dimension. In the downpipe there is a square hole, in which the square pin is mounted, and this hole is usually approx. one tenth of a millimeter larger than the nominal dimension for the square pin. There is then inevitably a slack or clearance between the square pin and the downpipe. This practice in dimensioning has arisen so that one can be sure that the installation of the square pin in the lock can be carried out without difficulty.

There are a number of known designs intended to eliminate the clearance between the downpipe and the square pin. E.g. publication CH 599 43S shows a downpipe which has a special screw with a conical part, which via an intermediate piece effectively reduces the clearance between the square pin and the downpipe. The construction with its many parts is complicated and expensive to produce and also requires assembly work both in the lock factory and when the handle is assembled. The publication DE 3805878 shows a downpipe construction with a metal downpipe, which is surrounded on both sides by cylindrical bearing parts of softer material. These bearing parts are provided with one or more radial slots, which make the bearing parts radially compliant. In the bearing parts, there is a narrowly sized hole for the square pin, so that the clearance between the drop tube and the square pin can be eliminated by the bearing part's dimensioning. However, the radial slits significantly weaken the bearing parts, which is why one cannot expect that

this construction lasts for long-term use.

The purpose of the invention is to provide a quality lock, in which the drop tube, due to its shape and dimensioning, is practically free of clearance connected to the handle's square pin. Another purpose is that the installation of the square pin should be simple and can be carried out without tools. The construction must also be cheap to manufacture and assemble, as well as being dimensionally suitable to be used together with a reinforcing metal downpipe support if necessary. Furthermore, a drop tube according to the invention without other precautions than appropriate dimensioning must be suitable for use in several modern lock models.

The purpose of the invention is achieved in the manner stated in claim 1.

By, according to the invention, arranging one or more cavities in the downpipe near the hole for the square pin, the downpipe, without its overall strength being significantly weakened, can be made just so flexible that the hole for the square pin can be suitably undersized in relation to the cross section of the square pin, so that the square pin is retained in the downpipe hole practically without clearance. As the hole in the drop tube gives in at the stage when the square pin forces the surface of the hole to elastically spring to the side, the power transfer between the handle and the locking mechanism will occur almost completely without clearance, and the user knows that the lock responds with precision to the movement of the handle. In order to achieve such a good quality overall impression, the clearance between the handle and the square pin must of course also be almost zero. Furthermore, the lock's internal mechanism must also be of good quality.

By arranging cavities close to at least two adjacent sides of the hole in the downpipe, the most effective clearance-free connection between the square pin and the downpipe is achieved.

It has proven to be important that the contact between the square pin and the downpipe hole is good at the corners of the hole. The corners should preferably continuously rest against the square pin when it is mounted in place. By arranging cavities near two adjacent sides of the downpipe's hole, such a suspension is achieved in the downpipe that the corner parts of the hole in particular get good contact with the square pin.

In the surface that limits the hole for the square pin in the downpipe, there should ideally be approximately flat surfaces on at least one, preferably on two adjacent sides of the hole, which in relation to the square pin show slightly inclined parts, between which there are a boundary area which is arranged to be continuously in contact with the square pin when it is mounted in place. This contributes to good and clearance-free contact between the square pin and the downpipe.

By dimensioning the hole of the downpipe so that when the square pin is installed in place there is a spring of 0.03 - 1 mm, preferably 0.1 - 0.4 mm, the square pin can be put in place without special precautions, and yet the square pin's fixing support is appropriate choice of material and dimensioning very safe, but still not too tight.

By designing the hole of the downpipe so that at least one, preferably two, of the side surfaces of the hole run somewhat obliquely in relation to the center of the hole, the square pin gets a good fixing support, but can still be mounted relatively easily and without problems without special tools or other events.

By designing the downpipe hole at least over a certain portion of converging cross-section, the square pin can be relatively easily wedged into place, and as a result an almost clearance-free power transmission structure is achieved.

If the downpipe's material is chosen so that the material's compliance and elasticity can be used not only during the first installation of the square pin, but also during renewed installation, no other compliant parts or structures are needed in the construction. The manufacturing costs for the downpipe can then be kept low without having to sacrifice the good properties of the lock construction.

The downpipe is preferably made of plastic. If the lock is exposed to great stress, it is recommended that the downpipe be supplied with reinforcing parts made of metal, preferably steel. It then becomes possible for parts that require special properties to combine the best properties of plastic and metal. The dimensional accuracy that can be achieved by conventional mass production is no obstacle to combining plastic and metal in the aforementioned manner.

It is also appropriate in the downpipe to arrange fixed cylindrical guide surfaces made of plastic, with the help of which the downpipe can be stored in the lock box either directly or via metal reinforcement parts. No special other bearing devices are then needed, and yet the result is a simple and reliable bearing construction with a long service life.

The downpipe can suitably be provided with chamfered surfaces at each end of the hole for the square pin. This facilitates the installation of the square pin.

The invention shall be described in the following with reference to the attached drawings, where: fig. 1 schematically shows a side view of a downpipe according to the invention,

fig. 2 schematically shows the downpipe according to fig. l in perspective,

fig. 3 schematically shows the downpipe according to fig. 1 in a plane parallel to the axis of rotation of the downpipe,

fig. 4 schematically shows a so-called exploded view of a drop pipe construction according to the invention,

fig. 5 schematically shows the device according to fig. 4 assembled together and in section.

In the drawings, 1 denotes a downpipe which, for the installation of a square pin 11, has an approximately square hole 2, at the outer edges of which there is a chamfer 3 to facilitate the installation of the square pin. By means of a short cylindrical projection 4, the downpipe 1 is stored in a locking box (not shown) or fitted between later described side pieces. The hole 2 has parts 5 and 6 where the sides of the hole curve inwards towards the center of the hole. In the drawings, this design is exaggerated to give greater clarity, as the hole's 2 sides 5 and 6 in practice deviate from the corresponding straight design only by approx. 0.01 - 1.0 mm. The cross-section of the square pin 11 is approximately square with a side length of nominally 8 mm. In practice, the side length is usually a few hundredths of a millimeter below 8 mm. The hole 2 is also designed mainly square, but at two sides 5 and 6, or at least at one of these, the dimension of the hole is less than 8 mm in order to achieve an appropriate fit between the downpipe and the square pin.

Close to the hole's 2 sides 5 and 6, cavities 7 and 8 are arranged. The hole's 2 side walls 5 and 6 as well as the downpipe material that lies between these side walls and the cavities 7 resp. 8, can be displaced towards the nearby cavity when the square pin is mounted in the hole 2. The cavities 7 and 8 can, if deemed necessary, be filled with a resilient material such as e.g. rubber, but they can be empty or e.g. be completely or partially filled with a suitable lubricant. The downpipe 1 must be dimensioned in such a way that the hole 2 can expand sufficiently when the square pin is mounted. The cavities 7 and 8 must be sufficiently wide, but the structure must still be durable. It is also conceivable to arrange cavities near one or preferably two of the hole's 2 corners. In such a construction, one or more of the corners in the hole 2 would be able to spring out and provide an approximately clearance-free force transfer between the downpipe and the square pin. It is appropriate that at least two of the 2 corners of the hole continuously rest against the square pin when this is mounted in place.

In fig. 2 it can be seen that the downpipe in the middle part of the hole 2 has a boundary surface 15, from which the hole 2 has an axially slightly divergent shape in the direction from the middle part outwards to both sides. In fig. 2 also shows the cylindrical shape of the projection 4 and its relatively low height in relation to the diameter.

In fig. 3 you can see that the downpipe 1 has protrusions 4 on each side in order to obtain good support from the lock box or from the support elements that will be described in the following section via these protrusions.

In fig. 4, metallic support elements 9 and 10 are mounted on each side of the downpipe 1, in which, by partial punching, pin-shaped projections 12 are formed which fit into recesses 13 in the downpipe 1 and thereby prevent rotation between the support elements 9 and 10 and the downpipe 1. Support elements are used in particular when the lock is intended for use where it is exposed to heavy loads and when a plastic drop pipe would not withstand excessive wear and tear and demanding use well enough. The cylindrical side projection 4 of the downpipe fits into the corresponding recesses 14 of the support elements 9 and 10, so that the support elements 9 and 10 and the downpipe 1 in the assembled position form an approximately fixed and with respect to all parts durable combination structure. The square pin 11 (shown briefly in the figures) is inserted into the hole 2 of the downpipe 1 as well as through corresponding holes in the support elements 9 and 10 when the handle is connected to the lock. If support elements are not used, the outer surfaces of the drop tube are designed so that the drop tube as such provides the lock's mechanism with the necessary control and power transmission inside the lock box when the lock is maneuvered via the handle.

In fig. 5 can be seen more clearly than in fig. 2 see the position of the boundary surface 15 and the slightly sloping parts 16 and 17 of the hole 2 as well as the chamfers 3. The cavity 7 is compressed somewhat because the square pin li is mounted in place, and the material is displaced due to the insertion of the square pin. The support elements 9 and 10 have outwardly directed cylindrical guide surfaces 18, which are stored in a corresponding opening in the lock box. The turning movement of the downpipe 1 will then take place in a controlled manner and without major friction.

The invention is not limited to the embodiments shown, since several variants and modifications are conceivable within the scope of the subsequent patent claims.

Claims (10)

1. Door or window lock with a drop tube (1) which can be turned with a handle's square pin (11) and which is made of a somewhat elastic material, preferably entirely or almost entirely of plastic or a similar material, and which, for fitting the square pin, has a continuous, in relation to the square pin somewhat undersized, mainly square hole (2), as well as at or near this hole an elastic area which springs to the side when the square pin (11) is mounted, characterized in that the elastic area around the hole (2) for the square pin comprises the limiting surface of the hole and at least one, preferably at least two cavities (7,8) arranged close to this surface in the downpipe (l). 2. Lock according to claim 1, characterized in that the elastic area around the hole (2) for the square pin comprises one or more cavities (7,8) arranged near two adjacent sides of the hole (2) for the square pin. 3. Lock according to claim 2, characterized in that at least two of the boundary areas between two adjacent sides of the hole (2) for the square pin are arranged to continuously rest against the square pin (11) when this is mounted in place. 4. A lock according to one of the preceding claims, characterized in that in the surface which limits the hole (2) for the square pin, there are approximately flat surfaces on at least one, preferably on two of the adjacent sides of the hole, as in relative to the square pin exhibits slightly inclined portions, between which there is a boundary area (15) which is arranged to be in continuous contact with the square pin (11) when it is mounted in place. 5. Lock according to one of the preceding claims, characterized in that the surface around the hole (2) for the square pin is arranged so that when the square pin (11) is mounted, it springs to the side 0.03 - 1 mm, preferably 0.1 - 0.4 mm . 6. Lock according to one of the preceding claims, characterized in that in the hole (2) for the square pin at least one, preferably two, of the side surfaces of the hole are slightly inclined in the direction towards the center of the hole. 7. Lock according to one of the preceding claims, characterized in that the hole (2) for the square pin has convergent cross-sections at least over a limited portion. 8. Lock according to one of the preceding claims, characterized in that the downpipe (1) at parts which are exposed to stress, comprises one or more reinforcement parts (9,10) of metal, preferably of steel. 9. A lock according to one of the preceding claims, characterized in that the drop tube (1) comprises cylindrical guide surfaces (4), whereby the drop tube is rotatably stored in the lock either directly or by means of reinforcement parts (9,10) made of metal. 10. Lock according to one of the preceding claims, characterized in that the outer ends of the hole (2) for the square pin have chamfers (3).