RU190592U1 - Clamp Collet End - Google Patents

Abstract

The utility model relates to the manufacture of prestressed reinforced concrete structures and is used for terminating rod tensioned reinforcement. The purpose of the utility model is to provide reusability of the collet end clamp at high loads. is solved by the fact that in the known design of the clamping collet end, which includes Pus and placed in it a sleeve with a conical inner surface and a collet with an internal notch and a conical-cylindrical outer surface consisting of two or more longitudinal petals and having a groove with an annular spring located in the outer cylindrical surface, the clip body is cylindrical with a flat end face on one side, a sleeve with a conical inner surface is installed in the housing bore with an interference fit, and the hardness of the conical surface of the sleeve is higher than the hardness of the mating conical surface collets.

Description

The invention relates to the manufacture of prestressed reinforced concrete structures and is used for end termination of rod pre-stressed reinforcement.

Terminal collet clamps are widely used not only in construction, but also in other areas of technology, for example, in electrical engineering for connecting electrical wires. Thus, a terminal clamp for collet type wires is known, consisting of a clamp body, a sleeve and a collet with notches on the inner surface. Catalog of the company Arthur Flury AG https://www.aflury.ch/de/startseite/.

The disadvantage of this clamp is the lack of reliability of fixing the collet fastening on the wire at the time of installation, which can lead to the possibility of the wire slipping out of the clamp.

Known connecting collet clamp (RU 181969 - published 30.07.2018 Byul. No. 22), comprising a cylindrical body with threaded ends and two conical collets, each of which has a wide base facing the corresponding end of the cylindrical body, two couplings having a wide initial section with cylindrical internal thread for connection with the corresponding threaded end of the cylindrical clamp body, which passes into the final section with a conical cavity, which is intended to be installed in it appropriately The cone collet is made according to the shape of its outer surface, and on the outer surfaces of the couplings and on the central part of the surface of the cylindrical body there are faces for wrenches, each of the couplings in the final section in front of the cone-shaped cavity is provided with a thermoplastic sealing ring.

The disadvantage of this utility model is the complexity of the design and the limited application - exclusively for connecting the ends of the wires.

Known butt collet clamp (RU 92388 - published 20.03.2010 Byul. No. 8), comprising a clamp body, two nuts and two collets, while the clamp body in the middle part is equipped with a hexagonal stop with cut cylindrical ends for fastening nuts on it, each collet made of segments fixed at its end. In addition, the collet has three grooves that divide it into three segments, with one groove made over the entire length of the collet with a gap of at least 2.5 mm, and the other two grooves are cut to the bottom of the collet and have a width of at least 2 mm, and the outer longitudinal the slope of the collet surface in length is 6–12 ° with respect to the longitudinal axis.

The disadvantage of this design is that the clamping force is determined by the force of fastening the nut on the device body, which does not always provide a high strength connection.

The closest in technical essence to the claimed utility model is a collet end clamp, comprising a housing and a sleeve with a conical inner surface and a collet with an internal notch and a conical-cylindrical outer surface, consisting of two or more longitudinal lobes and having an outer cylindrical surface groove with ring spring located in it. (RU 164073 - published 08/20/2016 Bull. No. 23 prototype). The body is made with a U-shaped cylindrical surface on the side of the inlet, and the end of the sleeve with a conical inner surface is made from the side of the hole of smaller diameter, cylindrical with a radius of curvature, respectively, the internal surface of the body.

The disadvantage of this design is that it is not designed for reusable use under high loads, since under the action of high loads there is a significant deformation of the sleeve with a conical inner surface, which violates the accuracy of matching this conical surface with the conical surface of the collet, and reduces the clamping force, when used repeatedly, leads to rapid wear of the mating conical surfaces and increased friction between them, which further reduces the force of the end clamp.

The task of the utility model is to provide reusable clamping of the collet end at high loads.

The technical result of the utility model is to increase the clamping rigidity and reduce the wear of the conical interface.

The problem is solved by the fact that in the known design of the clamping collet end, which includes the case and placed in it a sleeve with a conical inner surface and a collet with an internal notch and a conical-cylindrical outer surface consisting of two or more longitudinal lobes and having a groove on the outer cylindrical surface with an annular spring located in it, the clamp body is cylindrical with a flat end on one side, a sleeve with a conical inner surface is installed in a flange stii housing with an interference fit, and the tapered sleeve surface hardness higher than the hardness of the mating tapered surface of the collet.

Since the clamp body is cylindrical, and the sleeve with a conical inner surface is installed in the housing bore with tension, this increases the clamping rigidity, which reduces the deformation of the sleeve, improves the accuracy of the conical interface of the sleeve and collet, reduces contact stresses and reduces their wear. And since the hardness of the conical surface of the sleeve is higher than the hardness of the mating conical surface of the collet, with repeated use of the clamp, the conical surface of the sleeve will not be subject to strong wear and will retain its shape for a long time, which will not prevent the collet from sliding against the sleeve with its dimensional wear. All this provides the possibility of reusable clamping collet end at high loads.

The design of the clamp is illustrated in the figure, where in FIG. 1 shows a cross section of the device.

The figure uses the following notation:

1. Body, 2. Sleeve. 3. Grip. 4. Ring spring. 5. Twisted spring. 6. Cover.

The device consists of a housing 1 having a cylindrical shape of the outer and inner surfaces and a flat end, and the sleeves 2 located therein, the collet 3, the spring 5 and the lid 6. The sleeve 2 is installed in the opening of the housing 1 with an overload with an emphasis on its end. The sleeve 2 has a conical inner surface that mates with the outer conical surface of the collet 3. The collet 3 has a hole with a notch applied to it and a short portion of the outer cylindrical surface on which the groove is made. In the groove of the collet 3 is installed annular spring 4. The collet consists of two or more longitudinal petals, which are held together by an annular spring 4.

The sleeve 2 and the collet 3 are subjected to thermal hardening, but so that the hardness of the conical surface of the sleeve 2 is several units higher than the hardness of the outer conical surface of the collet 3.

From the open end of the housing 1, a cover 6 is fixed. Between the cover 6 and the collet 3, a twisted spring 5 is installed.

The operation of the device is as follows. The end of the fixed core reinforcement (not shown) is passed into the holes of the housing 1 and the sleeve 2 pressed into it. Then the collet 3 with the ring spring 4 is put on it. The collet segments are evenly positioned along the circumference of the rod end. The clamp body 1 with the sleeve 2 is pushed onto the collet 3. After that, the coiled spring 5 is installed in the housing 1, and the opening of the housing 1 is closed with the cover 6. When the core reinforcement is tensioned, the collet 3 sticks in the conical hole of the sleeve 2, the petals of the collet 3 contract and firmly hold the end rod reinforcement. The spring 5 prevents the reinforcement from slipping in the hole of the collet 3 at the time of clamping, and the cover 6 provides support for the coiled spring 5 and limits the ingress of dirt into the interior of the body 1.

After using the clamp for its intended purpose, it is disassembled. To do this, remove the cover 6 from the housing 1, remove the twisted spring 5 and push the reinforcement along the axis of the housing 1. The collet 3 comes out of the mating with the sleeve 2, it is removed, and the rod is removed from the housing. When re-using the clamp again perform the above steps.

Since the dimensions of the housing 1 are much larger than the dimensions of the sleeve 2, and consequently, its rigidity is higher, then when installing the sleeve 2 into the opening of the housing 1 with tension, the rigidity of this connection significantly increases. Therefore, even with a very high pressure on it from the side of the conical surface of the collet 3, the deformation of this connection is insignificant, and therefore, the angle of the sleeve cone changes slightly. This prevents the edge contact of the conical surface of the sleeve 2 with the conical surface of the collet 3, reduces the magnitude of the contact stresses and increases the reliability during clamp operation.

In order to reduce the wear of the working surfaces of the clamp, the materials of the sleeve 2 and the collet 3 are subjected to thermal hardening. But with repeated use of the clip, wear of the hole of the collet 3 and the surfaces of the conical interface of the collet 3 and the sleeve 2 is still unavoidable. The specified wear is compensated by the fact that the collet 3 is displaced along the axis of the sleeve 2, thereby maintaining the strength of the clamp. But if under the action of high and repeated load plastic deformation occurs or the conical surface of sleeve 2 will wear out, the unevenness formed on it will prevent the collet 3 from moving along the axis of sleeve 2 and the clamping force of the collet will decrease. Therefore, the hardness of the conical surface of the sleeve 2 should be at least a few units higher than the hardness of the conical surface of the collet 3. Then when the collet 3 is worn, the conical surface of the sleeve 2 will retain its shape and will not prevent the collet 3 from moving along its axis and compensating for its wear. In addition, too high hardness of the collet can lead to the brittle destruction of its internal cuts and its premature failure.

Example. It is necessary to create a clamp end collet for tense rod reinforcement with a diameter of 5 mm used in the manufacture of prestressed concrete structures. Rebar tension force 35 kN.

После некоторого износа цанга сместится в осевом направлении и длина сопряжения может уменьшится до

что соответствует площади контакта S_min=540 кв. мм.We manufacture a clamp body 1 with an outer diameter D = 10.5 mm., An internal diameter d = 16.5 mm., And a height h _k = 40 mm. A flange with a 6 mm hole for fittings is made at one end of the body, and an internal thread is made to fix the lid 6 at the other end. In the hole of the body 1 with tension, we install sleeve 2 with a height of t _ν = 22.5 mm with a tapered bore α = 12 °. At the end of the sleeve 2, a hole of the same diameter as the hole in the flange of the housing 1 is made. The material of the sleeve 2 is Art. ShH-15, hardened to hardness HRC 62. To reduce the friction force, the surface roughness of the tapered bore of the sleeve 2 is not higher than R a 0.32, which provides a coefficient of friction with the collet surface not higher than ƒ = 0.1. The maximum length of the conical mating sleeve and collet is equal to

After some wear, the collet will shift in the axial direction and the mating length may be reduced to

which corresponds to the contact area S _min = 540 square meters. mm

We manufacture the collet 3 in the form of two halves connected by an annular spring 4. The material of the collet is st. 20X, cemented to a depth of 1 mm and hardened to a hardness of HRC 56. The collet height is 22 mm. Internal notches collet provide a friction coefficient of not less than менее _c = 0.25.

The thickness of the ring spring 4 is taken equal to 0.8 mm. The outer diameter of the twisted spring is 13 mm, the diameter of the coils - 0.8 mm, height - 30 mm. The cover 6 is made of polyamide and serves to guide the twisted spring 5 and to protect against external contamination.

Since the required tension force of the reinforcement is 35 kN, the required clamping force of the collet is equal to Q = 35 / ƒ _c = 140 kN.

Maximum contact stresses of the sleeve and collet of the wound:

For non-hardened steel, this stress is dangerous, as it can cause plastic deformation and increased wear of the material. For thermally hardened steel, this stress is quite acceptable, as hardened to hardness HRC 62 st. ShH 15 can withstand a contact stress of collapse up to 2000 MPa, and the material of the collet hardened to hardness HRC 56 can withstand contact stresses up to 1600 MPa. But this is only under the condition that the conic mating is performed fairly accurately and does not have distortions.

The magnitude of the deformation of the sleeve 2 in the weakest section - from the side of its larger internal diameter, we find by the formula:

where Е is the modulus of elasticity of steel, MPa (Е = 2.1⋅10 ⁵ MPa); r _n and r _ν are, respectively, the inner and outer radius of the section of the sleeve 2, mm.

In our case, r _ν = 6.5 mm, the outer radius, together with the body, is r _n = 10.25 mm. Then by the formula (2) we define u = 0.01 mm. This is not a desirable value, but is permissible, since compensation for this error can be made due to a small dimensional wear of the surface of the collet. If the sleeve 2 was not pressed into the housing 1, then its r _n = 8 mm, and its deformation would be u = 0.025 mm, i.e. 2.5 times higher. It was harder to compensate for the wear of the collet.

Normal clamp operation is possible if the conical surface of the sleeve 2 is not damaged. The clamping force of the collet should be wound:

where N is the thrust force, H; ϕ is the angle of friction between the conical surfaces of the sleeve and the collet (ϕ = arctgƒ), rad.

In our case, N = ƒ _c ⋅Q. After conversion, we define the normal condition of the clamp:

For the considered example, this condition is met, since

ƒ _c / tg (α / 2 + ϕ) = 1.2.

But if the conical surface of the sleeve 2 is damaged and the value ƒ increases to ƒ = 0.2, then

ƒ _c / tg (α / 2 + ϕ) = 0.85.

Therefore, in this case, condition (4) is not met.

Thus, a more significant hardening of the conical surface of the sleeve 2 in comparison with the collet provides a more reliable operation of the clamp.

The proposed end collet clamp allows you to increase its rigidity and reduce the wear of the conical mating, especially the conical surface of the sleeve, which allows for the reusable use of the clamp at high loads on the anchored product in the form of rod reinforcement.

Claims (1)

Clip collet end, comprising a housing and placed in it a sleeve with a conical inner surface and a collet with an internal notch and a conical-cylindrical outer surface consisting of two or more longitudinal petals and having on the outer cylindrical surface a groove with an annular spring located in it, characterized by that the clamp body is cylindrical with a flat end on one side, a sleeve with a conical inner surface is installed in the housing bore with an interference pressure, and the hardness is second surface of the sleeve above the hardness of the mating tapered surface of the collet.

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