FI74849B - APPARATFOT FOER TELEFONSAPPARATER. - Google Patents

Description

1 74849

Device stand for telephones

The invention relates to a device leg for telephones, which base is in the form of an elastic, one-piece body delimited by substantially two parallel, spaced apart, vertically permeable support surfaces, the first extending in a plane, the second being convexly curved at least in the vicinity of the axis, and at least one axially jacketed surface extending between the extreme edges of both bearing surfaces, the body extending in a cylindrical cavity coaxially open from the side of the flat support surface over its entire cross-sectional surface but contrasted on the side of the curved surface by a film-like wall (cf. DE 23)

Such device legs are conventionally arranged in a plurality of pieces of the same shape on the bottom surface of the telephones to allow a secure, gentle placement of the device on a wide variety of placement surfaces. The bottom surface of the device is kept at a corresponding distance above the placement surface by means of the axial height of the device leg.

The known device legs are formed as separate parts and are fastened individually, in each case to the horizontal areas of the horizontal surface of the device or the corresponding triangle, quadrilateral or polygon. The horizontal surface of the part of the device legs to be arranged between the bottom surface and the placement surface of the device may enclose a cylindrical or angular plan view. The purpose of the elastic shape of the device legs is to dampen the transmission of vibrations and vibrations between the placement surface and the device and to compensate for the unevenness of the placement surface by means of suitable material selection and design.

For this reason, it is known to make the device legs, for example, of rubber, plastic, felt, chamois leather or at least to provide a corresponding standing surface. When choosing a material, in addition to elastic properties, it is important to avoid mechanical or ceramic effects on the placement surface and permanent changes or abrasions in the form of damage to the device itself, in close contact or abrasion with the device legs, and to achieve a high coefficient of friction in Parik placement. future materials.

The friction number is the material constant determined for the arbitrary pairing of materials in different surface qualities. In this case, the coefficient of friction at rest friction and the coefficient of friction at sliding friction are distinguished from each other. The value of rest friction is usually slightly higher than the value of sliding friction.

In a known device leg corresponding to the preamble, which has hitherto been considered to be optimal in terms of its properties, a flat surface is formed from its two spaced apart interfaces at right angles to the axis for fixed support and connection, with the bottom surface of the device or against the bottom surface for support against the placement surface of the device. The legs can be attached to the device in a known manner, e.g. by gluing or by means of pins shaped on the device legs and corresponding to the openings in the bottom surface of the device, which can be connected to them in a secure manner.

The curved standing surface of the device foot can adapt in contact with the placement surface in its central region with a film-like wall to the shape of the placement surface by the elastic deformation of the device so as to form the tight surface contact required to provide high frictional resistance.

The high frictional resistance between the device foot and the mounting surface is important to achieve a sliding position of the device. The occurrence of sliding movement of the device with respect to the insertion surface due to mechanical forces acting parallel to the device should be made in this way so that e.g. manual operation of the rotary number switch 3 74849 mounted on the device or stretching of the elastic headphone cord in the device with unilateral traction

The achievable frictional resistance depends on the surface compression in the contact area between the standing times and the placement surface and the coefficient of friction. In this case, the weight or mass of the device is also a measure of the effect of the frictional resistance, and as such is included in the term "surface compression". The reduction and weight loss required in the manufacture of telephones now adversely affects the frictional resistance achievable with conventional device legs in that a strong tendency for lateral sliding relative to the placement surface has been repeatedly observed in such lighter devices. This is due to the lower frictional resistance, which with a lower weight of the telephone results from the poorer utilization of the constant coefficient of friction due to the reduction of the surface compression factor.

The object of the invention is therefore to improve the stability of the telephone with respect to sliding movement with respect to the insertion surface by means of a structural change of the known device-foot model without affecting the friction rate over the actual frictional resistance between the device legs and the insertion surface.

According to the invention, this object is solved by passing through the curved interface of the device leg a substantially circumferentially symmetrically circumferential groove which surrounds a cylindrical cavity coaxially enclosed in the body, or a film-like wall covering it.

By means of a groove in the curved support surface of this device leg, an external constraint is formed for the corresponding axial depth in an approximately hollow cylindrical part, the thickness of the cylindrical wall of this part being limited between the groove and the cavity.

4,74849

The solution according to the invention is based on the finding that the energy which causes an undesired sliding of the telephone does not, in most cases, e.g. when using a rotary number switch, act uniformly, but in the form of impulses of different intensities. In this case, the pulsating mechanical force only has to overcome the resting frictional resistance for a short time in order to move the device from its position with respect to the positioning surface. Due to the lower coefficient of friction, lower forces, or even weaker pulses, are sufficient to maintain the motion due to the lower coefficient of friction.

The design of the device leg according to the invention enables the elastic parallel displaceability of the standing surface of the device leg at right angles to its axis with respect to its area arranged for attachment to the device. For this purpose, this part of the wall on the side of its new hollow cylindrical region is stressed by bending. Due to the bending work carried out on the wall of the cylinder liner, part of the energy causing the unwanted sliding of the telephone on its mounting surface is consumed.

Appropriate sizing of the thickness of the cylindrical wall of the new, hollow cylindrical region can then ensure that the driving forces acting on the device, which substantially exceed the rest friction resistance for a short time, cannot cause the standing surface of the device to slide relative to the placement surface.

According to a preferred further development of the invention, a plurality of groove-cutting, radial strips in the form of walls terminating in a curved interface can be arranged in the paths of the substantially rotationally symmetrical groove on the curved interface of the device foot.

Such strips provide a suitable stiffening of the new hollow cylindrical region with respect to the surrounding part of the device leg. Such strips can be used to delay the premature, rectangular tilting of the standing surface of the foot in the desired parallel displacement with respect to its attachment area with an impact-like decrease in the frictional resistance. According to another further development, a small axial opening can be provided in the membrane-like part of the curved interface of the device foot, which provides a cavity in the initial load of the device foot with a initially flat curved standing surface and a substantially flat placement surface. The purpose of this connection is to prevent the formation of microclimates that may be harmful to the mounting surface between the device leg and the mounting surface in a rather long, unchanging resting position of the device.

The device foot according to the invention is, of course, not limited in its usefulness to telephones, but can be used almost universally and in many cases of use it is possible to make optimal use of its special features.

The invention will be explained in more detail by means of an exemplary embodiment shown in the following figures.

In the drawings: Fig. 1 shows the device foot in a half-cut side view, Fig. 2 shows the device foot of Fig. 1 in an elastically deformed working position, and Fig. 3 shows the device foot of Fig. 1 in a 90 ° folded view from below.

The device leg shown has substantially two parallel interfaces extending at right angles to the axis, the first being formed as a substantially flat support surface 1 and provided for connection to the telephone base surface 2, the second being formed as a curved standing surface 3 for partial support and frictional resistance 4 the device is set.

6 74849

The foot is surrounded parallel to its axis 15 by a cylindrical interface 14. A substantially cylindrical cavity 5 passes coaxially through its body and is covered by a membrane-like wall 6 facing the curved surface 3. An axially small, outwardly conically expanding hole 7 passes through this membrane-like wall. forms a connection between the cylindrical cavity 5 and the outside of the device leg in its rest position on the curved standing surface 3.

On the side provided for attachment to the device, a cylindrical abutment 8 of smaller diameter extends axially over said flat interface of the device leg from a flat interface 1. Also passing through this stop is a coaxial cylindrical cavity 5 in the device leg, the stop is provided with a thickening 9 running around the outer edge and is connected to a hole in the base plate 10 of the telephone.

Passing through the curved standing surface 3 of the device foot is a groove 11 recessed towards its body, extending substantially rotationally symmetrically, which surrounds a cylindrical cavity 5 or, respectively, a membrane-like wall 6 enclosing the body.

Thus, an approximately hollow cylindrical region with a small axial depth is formed. The thickness dimension of the cylindrical wall 12 is determined by the distance between the groove and the cavity. The cylindrical shell may be subjected to bending at right angles to the axis (arrow "p") as shown in Figure 2. Due to the work required for bending, some of the energy that could cause the phone to move on the placement surface is consumed. In this way, the value of the energy required to overcome the frictional resistance really increases.

In order to improve the shape stability of the device leg, especially in the new, hollow cylindrical region, the passage of the rotationally symmetrical groove 11 is interrupted by three radially separating walls 13 evenly distributed around its circumference, forming in the same plane the groove 11 covering strips.

Claims (5)

74849 A device leg for telephones, which leg is in the form of an elastic, one-piece body defined substantially by two parallel, spaced apart support surfaces vertically permeated by a unitary axis, the first extending in a plane, the second being convexly curved at least in the vicinity of the axis, and at least one sheath surface extending axially between the horizontal edges of both support surfaces, in which the cylindrical cavity extends coaxially open on the side of the flat support surface over its entire cross-sectional surface but on the curved surface on the other side covered by a film a recessed, substantially rotationally symmetrically circumferential groove (11) surrounding the cylindrical cavity (5) enclosed in the body or the membrane-like wall covering it coaxially. Device foot according to Claim 1, characterized in that a plurality of radial walls (13) pass through the substantially rotationally symmetrical groove (11) in the curved interface (3) of the device foot. Device foot according to Claim 2, characterized in that an axial opening (7) with a relatively small diameter is arranged in the membrane-like part (6) of the curved interface (3) of the device foot. Device foot according to claim 1, characterized in that the external horizontal plane shape is formed by a coaxially oriented, cylindrical interface. Device foot according to Claim 1, characterized in that the flat support surface (1) of the foot body is provided coaxially with the cylindrical cavity (5).