SE451519B - Aerial or tape measure reinforcing strip - Google Patents

Abstract

The strip is pref. used to stiffen aerials or tape measures, and is of steel or some flexible material. Along the whole or parts of its length, it has at least one wave-form lengthways raised section on one side, with a corresp. recessed part on the opposite side. The wave formation runs along the strip forming raised sections in three dimensions, with waved side surfaces going together in a corresp. height level along the strip. The lowest level, the wave trough, lies above the strip's base surface or normal plane, and the side surfaces connect to the base surface in a tangent line along the strip. The tangent line's extent across the strip is less than have the width of the strip. (Provisional Basic advised week K25)

Description

Bubbles or tubers arranged next to each other in transverse or oblique rows which were mutually offset transversely, i.e. overlapped each other across the band. An example of this is shown in Fig. »U 1. When bending such a strip, this has the effect that stresses develop between the rows, because through the overlap the elongated bubbles are rotated towards each other in the overlapping area, which gives rise to« the belt receives compressive and tensile stresses between these stiffeners when it is bent. But even if the belt has become stiffer due to this stiffening, no tension forces arise until the belt is bent, ie the stiffness of the belt, bending resistance, does not take effect until the bending has become apparent.

At the curved area, the smallest possible bending radius before plastic deformation, bending, occurs, is limited by the degree of overlap. If this smallest possible radius is exceeded for elastic bending, the band will bend or be plastically deformed.

In one case, when the overlap is large in relation to the gap between the bubbles, the bending can take place at the boundary area of the tips of the overlapping bubbles, ie beyond the overlap and directly over the stiffeners or bubbles, See Fig. 1 AA, which can not be counteracted unless the gap laterally, across the band, between the stiffeners, increases, or the overlap decreases.

In the second case, when the overlap is small in relation to the space between the bubbles, a possibility of bending occurs at the area in front of the tips of the bubbles, and instead within the overlapping area, in a zic-zac shape across the band from tip to tip. See Fig. 1 AB. This previously proposed stiffening construction therefore has, in principle, two decisive limitations. Firstly, the stiffening effect does not occur until noticeable bending, which for a strip length of, for example, one meter of ordinary steel strip leads to great sway, which can only be counteracted to a certain extent in the early stage of bending by profiling the strip in C- or S- profile. Secondly, the smallest possible bending radius can only be reduced at the expense of a smaller degree of overlap, which thus results in poorer stiffening and even greater sway.

There has long been a desire to obtain an antenna that is rigid with very little sway, but which is also difficult to bend or break while it can be shortened and occupy a small volume.

The above-mentioned stiffening cannot meet these requirements for the purely principled reasons described. For if good rigidity and a small sway are to be obtained, the smallest bending radius becomes large and thus the risk of bending increases and that the winding diameter and volume of the belt becomes larger in the shortened state.

According to the present invention, a strip intended to be used, for example, as a measuring tape or radio antenna, an improved rigidity in both straight and bent position and an ability to maintain considerable elasticity during bending to a small radius without risk of bending, by the strip, along the whole or parts of its length are formed with at least one wavy longitudinal elevation on one side of the belt, and with corresponding depression on the other side of the belt, whose wave propagation runs along the belt forming elevations in three dimensions with wavy side surfaces joining in a corresponding wavy height line along the belt, the lowest level , wave valley, lies above the base surface or normal plane of the belt, and whose side surfaces connect to the base surface in a tangent line along the band, where the extent of the tangent line across the band is less than half the bandwidth, see Fig. 2a.

Because the scale with its lowest point does not touch or descend anywhere along the length of the belt or goes down in the normal plane or base surface of the belt, a generally elevated level is obtained, which in a straight straightened state acts as a stiffening that extends along the entire length of the belt.

When such a belt is bent to a small radius, for example two millimeters, the belt obtains very large tensile and compressive stresses which seek to restore the original waveform of the belt and thereby straighten the belt from the bent state. Because the own length of the scale is always longer than the extent of the belt, this allows, when bending from the side the scale is formed on, that the scale can be stretched and form a smaller wave on its outside, the radius of which is calculated from the center of the bend is larger than the radius of the bend of the base surface or normal plane of the belt. This means that even in a curved belt section, the wave valley can maintain a generally elevated level along the entire curved belt section and on to the straight parts of the belt, see Fig. 2b.

Figuratively, the change of the wave when bending the band in this direction can be described as the amplitude of the wave decreases, ie the height distance between top and valley decreases, and the height of the wave itself above the base surface decreases, which in turn causes the band width in the bent area increases. If the band is instead bent in the opposite direction, ie so that the side on which the scales are formed is bent inwards, this bending means that the scales are instead compressed, compressed, along the band in the bent area. The result of this bending is that the amplitude of the wave becomes larger, in that the wave valley will be pushed down towards the base surface and that the wave crest will be pushed up from the base surface, and that the wave height above the base surface decreases and thus the band width expands in the bent area 2c.

Because the wave valley does not touch or descend in the normal plane or base surface of the belt in any of the curved positions, a stiffening running along the belt is thus also obtained in these positions, acting throughout the curved area, which acts as a lever for the tensile and compressive stresses. to straighten the strap.

The cross-sectional profile of the road will also change at both of these different bending positions. For by the stiffening being in the form of a wave-like elevation, which is wavy in three dimensions and connected to the base surface in a round concave arc, this allows not only changes along the height line of the wave but also a change in the wavy tangent line along the band at the connection to the base surface. which also in turn allows the wavy side surfaces or walls of the stiffener 10 15 20 25 SO 35 451 519 to be changed, see Fig. 2d. In this way, the stiffening can compensate for the material excess and material deficit that arises during the amplitude change of the wave peaks and wave valleys, when the stiffening is stretched or compressed.

There are thus two effects that apply to bending, partly a lowering of the level of the stiffener over the base surface, which results in a widening of the band and the stiffness at the base surface, partly a change in amplitude in all three dimensions, ie a change in the height line, side surface and tangent line wave amplitude. The waveform therefore enables the belt to be imparted a considerable stiffening with an elasticity close to that of a flat unalloyed belt, which is bent to its smallest possible radius, before plastic deformation or bending occurs.

The invention will be described in more detail below by exemplifying various embodiments with reference to the accompanying drawings.

Fig. 1 shows a plan view of a strip embossed according to per se known principles, Fig. 2a schematically shows a portion of a strip according to the invention on an enlarged scale, Figs. 2b and 2c show the same strip portion in profile when it is bent from the Fig. 2d shows a cross section of the wave-shaped stiffening and shows from it connects to the base surface in a round concave arc, Fig. 5a shows a band with an advantageous embodiment intended for use as a radio antenna according to the invention, 451 519 Fig. 3b shows the size of this embodiment in relation to a smaller radio apparatus, and an application embodiment of the angular and shortening device of the band antenna, Fig. 4 shows an advantageous embodiment of a band according to the invention which can be used as a measuring tape, where the stiffening has been given space for the measuring scale.

The antenna shown in Fig. 3b and the measuring tape in Fig. 4, consists of a tape with a length in the order of 0-5 - 2.0 meters, and an everywhere equal width in the order of 0.1 - 0.17 millimeters. The material in the strip is steel, for example of approximately the same type as in the steel measuring tape.

In an advantageous embodiment, the band antenna may have a cross section which is largely formed by two tangentially arcuately connecting circular arcs, each with a center point angle of 15 ° - 35 °.

The left longitudinal half of the band in Fig. 3a and Fig. 3b is cupped, cupped, convex towards the spectator, and the right is concave towards the spectator.

In a strip antenna of this embodiment, according to the invention, a number of waves longitudinally with the strip have been pressed over the entire or larger part of the length and width of the strip.

The portions offset from the smooth base surface are in the form of a narrow longitudinal wave propagation through the strip which lies above the base surface on one side of the strip and below the base surface on the other side of the strip. The corrugatedly displaced portions along the belt have a height and a depth, respectively, which are at least equal to the belt thickness and which are preferably a few times larger than this. This impression may have been formed by profile rolling or similar manufacturing methods.

Suitably, adjacent waves can be allowed to lie close together, so that the waves occupy as little width as possible when connected to the base surface, in order to thereby be able to increase the packing density, as shown in Fig. 2a. The largest distance between the waves is therefore advantageously smaller or approximately equal to the wave amplitude of their tangent line at the connection to the base surface.

In connection with longitudinal indentations being made from one and the same side, it is usually noticed that the band curves transversely to an arcuate shape.

This arcuate shape is straightened in a limited area when the band is bent at the lumbar region.

The stiffeners, each of which is in the form of a narrow longitudinal wave propagation, have, to enable changes in the waveform, been connected to the base surface in a round arc shape which provides a movable tangent point at the base surface, so that the wave can increase or decrease its height above the base surface. reduce or increase its width, see Fig. 2d.

Because the cross section of the scale from the base is concave at the sides and then towards the top and valley of the scale changes to a convex shape, this means that in a number of longitudinal impressions with this cross-sectional shape the band obtains a transverse curvature in an arcuate with small elevations to it. convex side. The cross section of the strip hereby obtains an arcuate shape which is superimposed with small waves. This means that the arc shape itself is stiffened by the small waves, without reducing the elasticity of the belt, and without increasing the risk of bending.

In order to obtain an even stiffening with respect to bending in both directions, the longitudinal waves have been formed in one and the same direction along one half side of the belt, and in the opposite direction along the other half side of the belt, as shown in Figs. 3a and Figs. 3b. The top and valley of the wave will thereby lie outside the convex arcuate shape of the base in both cases, in that the band with these indentations will bend in such a way. This means that the base surface of the strip obtains a cross-sectional profile which consists of two arcs, which bend in opposite directions. 451 519 10 15 20 25 30 35 The embodiment described above is only an example of how the invention can be realized, and does not limit its scope, which is determined exclusively by the appended claims. The detailed features of the invention can thus be applied with substantially the same advantageous effect to bands with a cross-sectional shape different from the S-shape shown in Fig. 3a and Fig. 3b, namely for example to measuring tapes with a C-shaped cross-sectional shape, as shown in Fig. 4, or with any other cross-sectional shape. Even an initially completely flat belt can, when applying the invention, be sufficiently stiffened to be able to be used as a measuring tape or antenna. A related application is also to use this invention to increase the spring force of leaf springs or steel band springs per unit length through this flexible stiffening.

According to another embodiment, a belt which is flat in section can be provided by the belt being formed with longitudinal waves which alternately project on opposite sides of the belt. Such an embodiment is preferably used when the belt is to have a symmetrical stiffening to be used, for example, as a spring, or where only a part of the width of the belt can be occupied by elevations to make room for a measuring scale, for example.

In the case of band antennas, these have, as previously been required for larger lengths, had to be composed of two or more parallel bands in order to obtain the required rigidity, which in turn made it impossible to wind up or fold to a small volume. A belt stiffened according to the invention is self-supporting in a horizontal position and rises from an angled position as soon as it is released. Despite the increased stiffness, the belt can be wound up to a very small radius. For ordinary radios (transistor radios), reference has hitherto been made to the generally known telescopic antenna, which has the advantage of being shortable and occupying a small volume in the housing of the device, but which has the disadvantage of being easily bent or broken off. 10 15 20 25 30 35 451 519 What has hitherto made it impossible for band antennas to be used even in small and medium-sized radios has thus been that they could not be shortened, or that in the shortened, weight, state they occupied too large a volume. Their usefulness has therefore been severely limited to portable communication radios (walkie-talkies), which must be particularly resistant to impacts and shocks and where the shortening is not decisive for their practical use. This invention concerning the elastic stiffening of a band, preferably of steel, can therefore be used to great advantage as a band antenna.

Due to the fact that the elastic stiffening causes the strap to become self-supporting with great elasticity and small sway, while the elasticity of the stiffening allows the strap to be wound up to a very small radius, this enables the strap to take up such a small volume that it can be used for very small radios. This is an extremely important feature, which is thus related to the invention. For example, this band can be wound 120 cm in length into a spherical box about 25 millimeters in diameter, as shown in Fig. 3b, and thus be rotatable in the same way as a telescopic antenna, something that has not been possible before.

Claims (7)

451 519 10 15 20 25 30 35 10 PATENT REQUIREMENTS Bands for preferably antennas or measuring tapes, consisting of steel or other suitable elastic material, characterized in that the tape is formed along all or part of its length with at least one wavy longitudinal elevation on one side of the tape, and with a corresponding depression on the other side the band, whose wave propagation runs along the band forming elevations in three dimensions with wavy side surfaces converging in a corresponding wavy height line along the band, whose lowest level, wave valley, is above the base surface or normal plane of the band, and whose side surfaces connect to the base surface in wavy tangents along the band . 2. A belt according to claim 1, characterized in that the three-dimensional wavy elevation connects to the base surface of the belt in a round concave arc along the belt along the wavy tangent line of the belt thereto. (Fig. 2d) A belt according to any one of the preceding claims, characterized in that a plurality of three-dimensional wavy elevations are formed next to each other along the belt with a maximum distance between them across the belt which is less or approximately equal to the wave amplitude of their own tangent line at the connection to the base surface. . (Fig. 2a) A belt according to any one of the preceding claims wherein the belt has a wavy curved cross-sectional profile composed of an even number of arcs curved in opposite directions, characterized in that the longitudinal three-dimensional wavy elevations in the belt project from the convex side along the wavy profile of the belt. (Fig. 3b) A belt according to any one of the preceding claims, characterized in that the belt is formed with longitudinal three-dimensional wavy elevations which project alternately on opposite sides of the belt. å 10 15 20 25 30 35 451 519 11 Belt according to one of the preceding claims, characterized in that the three-dimensional longitudinal wavy elevation in the belt has a height and a depth, respectively, which is at least equal to the belt thickness and preferably a few times greater than this. (Fig. 2a, Fig. Zd) A belt according to any one of the preceding claims, characterized in that the three-dimensional longitudinal wave-shaped elevation in the belt is formed by indentation from one side of the belt, whereby a corresponding wave is formed on the other side of the belt. (Fig. 2a, Fig. 2b)