DE2534474C3 - Rope clamp for fixing ropes - Google Patents

Description

The invention is based on a cable clamp as specified in the preamble of claim 1 and through the US-PS 32 65 032 known Art.

In the rope clamp disclosed in US Pat. No. 3,265,032, each stool is approximately part of one To look at the truncated cone. Its jacket surface facing the gap is part of a truncated cone surface. the Combs of the toothing arranged thereon run along the generating surface area, that is to say accordingly like the tooth backs of a straight bevel gear. The tooth backs of the cusp surface then find their direct and straight line extension in the gap, based on the foremost tooth back on the stool, which is transferred in a straight line to the 3rd tooth of the base body. Just like one Bevel gear also takes the face width and the width of the grooves present between the teeth against the Cone tip down. All teeth are on the lower section of the base body and the continuation paragraph on the stool perpendicular to the base plate, when each tooth is in the direction of the top of the base plate and viewed perpendicularly to its tooth. Then namely the flat kink to the cusp surface no longer visible as a result of the projection. In addition, there is the imaginary central axis of the truncated cone eccentric to the axis of rotation of the base body, namely at a point where the elongated Hit the back of the tooth. It is supposed to be through the essentially vertical teeth against the base

to achieve minimal friction of the sheet when pressing in vertically. The straight down teeth running on the truncated cone must necessarily move away from each other to the base, so that when the sheet is laid, there is also a horizontal friction factor in addition to vertical friction, which makes it even more difficult to insert.

In the prior art, as little friction as possible would be an advantage, because the sheet surface slides when pushed in vertically, i.e. H. without pulling back, between the two Tooth back of the cam surfaces down and presses the cams exactly perpendicular to the longitudinal axis of the sheet apart. The pressure forces on both sides are converted into two forces by the axes of rotation of the jaws decomposed, one of which is directed as precisely the reaction force opposite to the compressive force, while the other generates a torque to unscrew the jaws. This torque could be the However, the jaws only yield if there is no friction between the back of the tooth and the sheet surface template. Since it is assumed that the sheet does not pull in the opening direction of the jaws, and there the back of the tooth in contact with the sheet as a result of the pivoting away of the jaw must perform a movement in the pivoting direction, there is a relative movement between the sheet surface and the back of the tooth. This relative movement can only take place with the generation of strong friction, or the sheet must carry out the relative movement.

However, if the sheet is only to be pushed in vertically, the frictional forces act counteracts this relative movement of the back of the tooth, so that the jaws are prevented from spreading apart will. It is clear that the jaws with a certain pulling movement also in the case of the sheet clamp according to the US-PS are brought apart and there is strong friction between the sheet surface and the The back of the tooth occurs and this results in rapid damage to the sheet and wear and tear on the teeth are. This disadvantage is also not eliminated by the fact that the tooth backs on the cusp surface to one another different angles. It essentially depends on the fact that it is in contact with the sheet coming tooth backs, and those are few, pretty much straight down to the teeth im Guide the gap yourself.

The object of the invention is to provide rope clamps of the type specified in the preamble of claim 1 Kind to improve that while maintaining the possibility of opening the jaws without Application of tensile forces in the sheet is above all achieved that with this opening movement The smallest possible frictional forces occur between the sheet and the toothing in the inclined surface and thus a

f> 5 the least possible wear on the contact surfaces occurs and thus, above all, the sheet is spared from wear and tear.

To solve this problem are in the invention

provided in the characterizing part of claim 1 specified design features, still in the Dependent claims 2 and 3 claimed advantageous and beneficial developments for the task solution are.

Although it has become known through US-PS 26 27 834 and 37 65 061 rope clamps of a similar type, in which helical teeth are provided on the clamping jaws, but in a different type and in different ways Effect, so that completely different technical conditions prevail in the respective state of the art, such as in the invention.

In the subject of the application, the inclined surface that carries the toothing is similar to a truncated cone jacket section view that has a curvature corresponding to the curvature of the clamping surfaces Toothing is then in the manner of a helical toothing with an inclined surface generated by the cone different direction attached, but essentially the same width over the entire extent Teeth. These teeth are then transferred into the vertical teeth with a spatial kink. Spatially because the transition surface is at an angle to the gap surface and also a kink in the The course of the back of the tooth is present when the back of the tooth is viewed precisely from the front in the direction of the base surface will. The sheet finds two tooth backs on the sloping surfaces when it is pushed down vertically, which intersect through the points of contact with respect to a plane directed perpendicularly to the base surface The sheet and the back of the tooth are inclined at an angle. In this sheet clamp according to the invention is a prerequisite that the surface of the sheet with the respective tooth back touched at the beginning of the Interlocking indentation phase. When pressing down, these toothing points move along the inclined ones Tooth backs in the direction of indentation vertically downwards, but they slide along the inclined tooth backs along and force the jaws to rotate, which is a consequence of the tangential force around the Is the axis of rotation of the jaws. It takes place between the contact points of the sheet surface, which essentially stand still and the tooth back only a relative movement along the tooth back instead. There is no horizontal relative movement with large frictional forces, which forces the Jaws are no longer necessary; instead, there is a clear, form-fitting movement deflection for the purpose of Swiveling the jaws apart.

The invention is explained in more detail using an exemplary embodiment in conjunction with the drawing explained. In the drawing shows

Fig. 1 is a perspective view of the rope clamp, and

2 shows a section of the clamping surface with a transition into the inclined toothing.

As shown in Fig. 1, this cable clamp consists of two clamping jaws 1, each on swivel axes 2 are pivotally attached to a foot and base plate 3.

The jaw 1 is a substantially triangular block-shaped body which is eccentric on the Pivot axis 2 is mounted and its surface farthest from the pivot axis 2 as The clamping surface 4 is formed. The clamping jaws 1 are mirror images of one another on the pivot axes 2 mounted, and the clamping surface 4 is designed arcuate in plan view that depending on the rotation of her effective distance from the other clamping surface 4

ίο increases or decreases the clamping jaw 1 is held in a rotary position by a spring, not shown and housed in its interior, that the clamping surfaces 4 are as close together as possible. The upper part of the clamping surface 4 is as Transition or inclined surface 5 shaped like a truncated cone jacket section and like the clamping surface 4 with a toothing 6 provided. The teeth 6 on the clamping surface 4 are parallel to the pivot axis 2 aligned and each have the same tooth width, seen in cross section of a sawtooth shape correspond in the direction of arrow 7. The toothing 6 on the inclined surface 5, which is one of the curvature of the Clamping surface 4 has corresponding curvature, is in the manner of a helical toothing with one of the Cone generating obliquely different direction attached, but with the essential about the entire extension of the same width teeth, which with a spatial kink 9 in the teeth 6 of the Clamping surface 4 are transferred. This spatial kink 9 is particularly good from FIG. 2 to recognize.

When the sheet, not shown, on the inclined surface 5 and thus on the toothing provided on it 6 is pressed on, there is great friction between the sheet surface and the tooth gaps,

J5 whereby the sheet is interlocked with the tooth back that is touched at the beginning of the indentation phase, the interlocking points when pushing down the sheet along the inclined tooth back according to the hike inclined plane 8 vertically downwards in the indentation direction, but the inclined tooth back slide along and force a rotary movement on the clamping jaws 1, which is a consequence of the tangential force around the axis of rotation 2 of the jaws 1. It takes place between the contact points of the sheet surface, which in the

i-> essentially stand still, and the tooth back exclusively a relative movement along the tooth back takes place, which is only possible because the Clamping jaws 1 around the horizontal component of this relative movement with large frictional forces does not occur, there is no need to force the clamping jaws apart, rather there is an unambiguous form-fitting Movement redirection for the purpose of pivoting the clamping jaws apart 1. This could be in correspondingly also be a pushing apart with sliding jaws. With 10 are in the drawing Denotes ends of the jaws 1 that are closest to one another. The opposite end on which the toothing ends, is denoted by 11 Finally, the upper edge between the inclined surface 5 and the horizontal

w) area has the reference number 12.

1 sheet of drawings

Claims (3)

Patent claims: 1. Rope clamp for fixing ropes, especially sheets in sailing boats, with two the rope between clamping jaws with toothed and, in a plan view, arched Clamping surfaces that have a tension-dependent clamping pressure on the rope, depending on the magnitude of the tension exercise on this and reduce their effective distance from one another depending on the direction of pull or enlarge, whereby from the top of each clamping jaw an inclined one, with a toothing provided surface leads to the clamping surface, characterized in that the inclined surface (5) The one curvature of the clamping surface is formed similar to a truncated cone jacket section (4) has a corresponding curvature, the toothing (6) on the inclined surface (5) in the manner of a Helical gearing attached with a diagonally deviating direction from the cone generating whose inclination upwards at an angle to the opening direction (arrow 7) of the clamping jaws (I) is directed and downwards with a spatial kink (9) in the teeth (6) of the clamping surface (4) are transferred, so that when the rope is pushed in, the greatest possible friction between the The surface of the rope and the gaps between the teeth are created, whereby the rope closes with the back of the tooth that is touched Beginning of the indentation phase, these interlocking points are interlocked when the rope is pushed down hike vertically downwards along the inclined tooth back in the direction of indentation, but the Slide along the inclined back of the tooth and force the jaws (I) to rotate Result of the tangential force around the axis of rotation (2) of the jaws (1). 2. rope clamp according to claim 1, characterized in that the inclination of the inclined surface (5) and the toothing (6) varies with the course of the clamping surface (4). 3. Rope clamp according to claim 1 and 2, characterized in that the toothing (6) on the Inclined surface (5) and the teeth (6) of the clamping surface (4) have a sawtooth shape in cross section.