RU2111692C1 - Clamping device - Google Patents

Abstract

FIELD: equipment for continuous controlling of length and for retaining tightening members, such as strap, tape or belt so that loop is formed. SUBSTANCE: clamping device has frame with support and plank with projections. Plank is movable relative to support. Length of inner surface of at least one plank projection exceeds typical size of section, such as diameter of rounded portion of at least one edge of support and plank projection. EFFECT: simplified construction, wider operational capabilities and enhanced reliability in operation. 6 dwg

Description

 The invention relates to the provision of vital human needs, for example, the production of haberdashery, and in particular to clamping devices for continuously adjusting the length and holding the tension element such as slings, belts, belts, etc. The invention can be used in the manufacture of accessories, buckles, fasteners, clamping devices, goods for sports and recreation.

 Known clamping devices, consisting of a fixed frame and strap, freely moving in the plane of the frame, remaining parallel to one of its sides (support), having the ability to press against it [1]. The belt in such a clamping device is first bent around the bar at an angle of 3π / 2, and then around the support at an angle of π / 2 in the opposite direction.

 Complicated variants of such a clamping device [2-5] are also known, containing, in addition to protrusions extending on the bar and the support, increasing the friction force of the belt against the elements of the clamping device under load, one or another spring-loaded device additionally pressing the bar pressed against the support ( both under load and in the absence of load).

 The closest technical solution, selected as a prototype, is a clamping device [6] (without the above spring-loaded device), consisting of a frame with a support and a strap that can freely slide along the guides of the frame, while remaining parallel to the support.

 The projections facing each other are made on the frame support and the plank, and the distance between the projections of the plank is greater than the width of the protrusion of the frame support. The belt is enveloped around the outer surface of the plank, threaded between the plank and the support, envelopes the support and exits in the direction opposite to the entrance. The strap is bent around the strap by an angle slightly less than 2π, the support - by almost π.

 The holding force of the belt in the clamping device is the sum of the friction force in the place of compression of the belt between the support and the angle of the protrusion of the strap and the friction force when bending around the edges of the support and strap.

 When tightening the belt by the free end, a force is created that slightly pushes the bar away from the support and allows the belt to be pulled between them. The force of friction of the belt when tightening is the sum of the friction when bending around the radii of curvature of the bar and the support.

 The main disadvantages of the known design are the following: low reliability of the device due to the possibility of the belt slipping through the clamping device when the load is weakened or removed; the adaptability of the clamping device to the belts in fact with one specific thickness, or thickness in a narrow range of values.

 The aim of the invention is to increase the reliability of the clamping device and expanding the operational capabilities of the clamping device.

 This goal is achieved by spatial separation of the sharp edges of the strap and support covered by a large angle in the holding position by the belt so that the spatially extended inner area of the strap in which the shoulder-wrapped edge of the support is located only in the holding position is highlighted.

 The proposed clamping device for tensioning and holding the belt comprises a support, one way or another connected to the remaining parts of the frame, and a strap containing a base and two long protrusions. The bar can move freely towards and away from the support.

 The inner surfaces of the protrusions of the plank either diagonally tapered, or are surfaces of complex shape. The outer surface of the plank has large radii of curvature.

 In contrast to the prototype, the length of at least one of the protrusions of the strip exceeds the characteristic size of the cross section, for example, the rounding diameters of the edges of this protrusion, strap and support. The divergence angle from the support of the inner surface of the protrusions of the strap is made as close as possible to 0 (at least less than π / 2).

 In addition, the length of the inner surface of the protrusions is such that it allows wedge-shaped clamping by the inner walls of these protrusions of the cylinder with a radius that coincides with the radius of curvature of the edge of the support, which exceeds it several times.

 The distance between the inner surfaces of the protrusions is significantly different in the base region and other areas, if in the base region it can be made arbitrarily small (it does not really exceed the diameter of the rounding of the support edge), then due to the length of the protrusions, despite a small angle of divergence, at some the distance from the support this distance exceeds several times the diameter of the rounding of the edge of the support.

 Thus, the technical solution meets the criterion of "novelty."

 A comparison of the proposed solution with other technical solutions shows that the protrusions on the plan, their wedge-shaped inner surface, sufficiently sharp edges, significant bend angles of the surface are known (although the clamping properties of the wedge-shaped walls in the known solutions [2-6] were not used under load, since the clamping the belt in them occurs by the angle of the protrusion of the strap, and not by jamming the frame support wrapped in the belt with the walls of the protrusions).

 The main thing in this case seems to be that both the use of individually extended protrusions on the bar, and together with the above signs, is new, and in addition, the use of these signs in this combination leads to the manifestation of a new property of the clamping device, namely, the formation and use permanent deformation of the clamping element (belt) for which the clamping device is intended.

 This allows us to conclude that the technical solution meets the criterion of "significant differences".

 In FIG. 1 shows a clamping device, complete; in FIG. 2 and 3 - clamping device in the tightening and holding position, respectively; in FIG. 4 - the phenomenon of formation of permanent deformation of the belt in the clamping device and its use; in FIG. 5 and 6 are the results of a study of the dependence of the formation of residual belt deformation on the design parameters of the clamping device.

 One of the simplest implementations of the described clamping device is shown in FIG. 1. It consists of a V-shaped strip 1 (for example, bent from a rectangular sheet) and a support 2 connected to the guides 3 of the frame 4, for example, bent from a round bar.

 The bar consists of protrusions 5 and 6, connected by a base 7, so that the distance between them in the area of the base is less than the size (cross-section diameter) of the support. At its base 7, holes 8 are drilled under the guides 3 of a frame of such a radius that the strip can both freely move along the guides and rotate around the longitudinal axis of the base 7 and "lie" on the guide frames with the inner surfaces of the protrusions 5 and 6. The edges of the protrusion 6 of the strap 1 and frame supports 2 are designated as 9 and 10, respectively.

 Under load, the belt bends around the outer surface of the strap 1 (at an angle close to π, covers the edge 9 of one of the protrusions (6) - covered (at an angle close to π, and then bends around the edge 10 of the support 2 (at an angle close to π) .

 In the tightening position (Fig. 2), the frame 11 slides along the outer surface of the strip 1, along the edge 9 and does not go into the inner region of the strip, along the edge 10 of the support 2. In this position, the edges 9 and 10 are practically aligned.

In the load holding position (Fig. 3) of the belt 11 with a force of F _{0, the} edge 10 of the support 2 wrapped by the belt enters the inner region of the bar 1. The edges 9 and 10 are separated by a distance of the order of the difference between the length of the protrusion 6 and the thickness of the belt. The belt is sandwiched between the inner walls of the protrusions of the strap 5 and 6 and the supporting 2 forces F ₁ and F ₂ , which depend on the applied load F ₀ and the angle of the solution α of the inner surface of the protrusions of the strap.

If we neglect the small angle ν between the guides of the frame and the direction of the applied load and consider the small friction force, then the reaction force of the support (guides 3 frames) in the holes 8 - N is approximately equal to F ₀ , thus, it can be estimated
N = F ₀ , F ₁ = F ₀ / sinα, F ₂ = F ₀ (1 + ctgα). (1)
It is seen that the force of the V-belt clamping of the belt can be made significantly higher than F ₀ by reducing the angle α. For example, for α = π / 6; F ₁ + F ₂ ≈ 4.7.
Let us now consider the technical effect of the formation of a belt memory in a clamping device, such as FIG. 1.

 After unloading the clamping device of the type of FIG. 1, the belt 11 remains deformed (Fig. 4), similar to its position under load around the strip 1 with the protrusions 5 and 6, and some force is required to straighten it. Such residual deformation is a phenomenon depending, in particular, on the thickness, material of the belt, the structure and density of its weaving, the period of time under load and the magnitude of the load.

All used woven belts almost do not resist bending around a large radius and a small angle. Under such conditions, the belt can be considered as having no thickness and properties associated with it. This is due to the fact that the fibers in the belt are relatively loosely coupled, an insignificant (less than the size of the fibers) fiber displacement relative to each other in the thickness of the belt requires almost no energy and can be considered frictionless. This is what happens when the belt bends around a large (compared to the thickness of the belt) radius. The difference between the lengths α of the outer and inner layers of the belt of thickness τ enveloping the angle α with radius r
α = α • τ, (2)
those. per unit length of the curved zone of the belt, this difference is
α / (r • α) = τ / r. (3)
Thus, for large turning radii, r ≫ τ, and the relative displacement of the belt fibers is small, if the diameter is comparable to or less than the thickness of the belt, the displacement of the fibers is large and the force of permanent deformation is noticeable.

 Therefore, the described clamping device is advisable to use with belts with a thickness less than or comparable to the characteristic size of the cross section, for example, the rounding diameter of at least one of the edges of the support and the protrusions of the strap. If, in addition, it is required to limit the tightening force so that the thickness of the belt is not significantly greater than these measurements (diameters), then as a result we will find that the thickness of the belt coincides in order of magnitude with the characteristic cross-sectional size (rounding diameter) of at least one of the support edges and protrusions of the strap, and less than the length of the inner surface of the protrusions, and the diameters of the rounding of the outer surface of the strap, and in addition, the belt-wrapped edge of the support has the ability to enter between the protrusions of the strap.

 The effect of the load is as follows. With a small (not very stretching belt) load, all the force is passed to the layer external from the enveloped edge, and the fibers of the inner layers only bend and wrinkle without shifting relative to each other. In this case, the thickness of a certain outer layer acts as the thickness of the belt with respect to τ / r, and the relative displacement of the fibers of the belt is small as r-r + τ. On the contrary, under a strongly stretched belt load, all layers of the belt take up force, the displacement of the fibers relative to each other significantly affects not only the entire bend zone, but also the surrounding belt zones, and the fibers remain in this form even after the load is removed, if the belt is not straightened by a pulling application strength (an illustration of this is the well-known method of straightening steel cables with a jerk - heavy load). Some wickerwork - slings, ropes, etc. - under a significant load, tend even to irreversibly thin, lengthen, and thus increase the density of weaving, hardness, and bending resistance.

 As experience shows, for the mutual displacement of the fibers takes some time. That is why, when the belt is pulled uniformly around the bend, the forces of residual deformation are hardly noticeable.

 Quantitative studies of the described effect for buckles of the type of FIG. 1, made of aluminum sheet 1105 AM and stainless steel 12X18H10T with a radius of 1 mm and nylon belts of various weaving and thickness. In FIG. 5 - 6 show the results for a belt Art.2S-289 with a thickness of 2 mm.

 The force F was measured, which is required for the belt to be pulled back through the clamping device after applying and removing a small load (5 kg, 100 s) and removing the bar from the support at a distance of 30 mm (the maximum length of the tabs of the bar was 15 mm).

In FIG. 5 shows the indicated force F depending on the angle between the protrusions α, and in FIG. 6 - depending on the length of the protrusion 1. F _c indicates the pulling force of the belt through the clamping device without first applying a load.

 It can be seen that in order for the indicated effect to be noticeable in the clamping device, in addition to the requirements that the rounding diameter of the edges should be of the order of or less than the thickness of the belt, and so that the angle of rotation of the belt at the edge exceeds π / 2, it is also necessary that the length of the protrusions exceeded the thickness of the belt. As indicated above, this is achieved if the thickness of the belt coincides in order of magnitude with the rounding diameter of at least one of the edges of the support and the protrusions of the strap.

 The latter requirement can be explained by the fact that when the forward and backward bending zones (around the edges of the strap and the support) of the belt are arranged sequentially, as in the clamping device under consideration, the fibers external to one zone are internal to the other and, when they are close and rarely weave the fiber, just shift from one zone to another, so the forces of permanent deformation are weakened. In order to prevent this from happening, the difference between the zone of the forward and reverse kink of the belt (or the edge of the bar and the supporting part of the frame for this design) in the holding position should be remotely.

 In addition (this also seems to be very important), the separation of these edges in the presence of forces of permanent deformation and a small angle at the top of the inner surface of the strip leads to some "jamming" of the belt inside the strip (even after the support part of the strip is removed from the inner region of the strip - Fig. 4 ) It can be seen that the smaller the angle α between the protrusions of the straps 5 and 6 and the greater their length, the better the belt “gets stuck”. Moreover, it turns out that if the load is again applied to the belt, then the zones of forward and reverse kinks exactly fall to the former places of the protrusions 5 and 6.

 Therefore, the described design of the clamping device allows the formation and efficient use of residual deformation of the belt. After removing the load and even after removing the edge of the supporting part of the frame from the inner region of the plank, it remains bent inside the buckle in approximately the same position as under the load, and it requires some force to straighten it, which makes it difficult to slip and indicates resistance to loosening and removing load.

 In addition, while the edge of the support is in the inner region of the bar, the clamping device can be considered to be in the holding position of the load, and in order to move from the holding position to the tightening position, the support and the film should be shifted by a distance of the order of the length of the ledge of the bar.

 Thus, the positive effect is: reliable retention of the belt in the clamping device by the wedging walls under load, the possibility of using a wide range of belts, increasing the "natural" reliability compared to the prototype against the random relative shift of the parts of the clamping device relative to each other in the absence of load, and also to weakening repeatedly, or relieving the load.

 This "natural" reliability, as shown by 5 years of experience using a clamping device, is enough for all those cases when the clamping device is not used as a means of insurance.

 In addition, the simplicity and manufacturability of the clamping device, low requirements for manufacturing tolerances of parts of the clamping device, since their connections can be manufactured with a gap, are a positive effect. In addition to lowering the requirements for the manufacture of a clamping device, this also means a low sensitivity of the functioning of the device to various kinds of conditions other than the calculated ones - distortions, lateral directions of effort, belt inhomogeneities, etc.

 Thus, experimental studies and calculations of the clamping device showed that, in comparison with a device of the same name (prototype), the inventive device provides: more reliable retention of the belt both under load and in its absence, as well as with repeated application / removal of the load; the expansion of the operational capabilities of the device due to the possibility of using a wide thickness range of belts. In addition, the claimed device is more technological.

Claims (1)

 A clamping device comprising a frame with a support and a bar with protrusions movable relative to the support, characterized in that the length of the inner surface of at least one of the protrusions of the bar exceeds a characteristic cross-sectional dimension, for example, the diameter of the rounding of at least one of the edges of the support and protrusions of the bar.

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