FR3093340A1 - IMPROVED DECINTER - Google Patents

Abstract

IMPROVED DECINTER The decentering device comprises four elements (1a, 1b) which each define two internal sliding faces (3) with a protruding zone and a groove configured to cooperate with the protruding zone of an adjacent element (1b, 1a ). The opposite external faces (2) of the tilting device are parallel two by two. A rod (4) is used which passes through the first two elements (1a) mounted opposite. The rod (4) defines the maximum distance between the first two elements (1a) which will define the distance and therefore the height between the two second elements (1b) which slide relative to the first two elements. The four elements (1a, 1b) of the tilting device are formed from a polymer material. Figure for the abstract: f igure 1

Description

IMPROVED DEBENDER

The invention relates to a decentring device that can be used in engineering structures and constructions.

In the public works trades, it is common to replace hydraulic lifting tools, which are expensive and bulky, with unbend tools also called unbends. The decentring tools make it possible, for example, to remove the hangers that were used to build a vault or an arch once the structure is finalized.

The unbending tools are configured to support a heavy load, typically several tons. The unbending tools can modulate their height in order to adapt to the configuration of the work. To remove the unbend tool, simply reduce its height to remove the stress exerted by the mass that was supported.

Debenders are commonly used in very tight and often difficult to reach places because it is difficult to use other tools. It is common to find benders in the foundations, the spacers of bridge piers or in the abutment of a bridge that will support the weight of the deck.

However, even if the debender has many advantages compared to hydraulic tools, it must be recognized that a debender has a mass greater than thirty kilograms and that it is difficult for a companion to move and install such a tool. in a cramped and difficult to access area.

It appears that the installation of the debender is a difficult operation and which can lead to accidents or musculoskeletal disorders.

Object of the invention

The object of the invention is a decentring device which is easier to use than the devices of the prior art.

• une paire de premiers éléments montés en vis-à-vis, la paire de premiers éléments étant agencée pour présenter des faces externes parallèles, chaque premier élément présentant deux faces de glissement,
• une paire de second éléments montés en vis-à-vis, la paire de seconds éléments glissant par rapport à la paire de premiers éléments, la paire de seconds éléments étant agencée pour présenter des faces externes parallèles, chaque second élément présentant deux faces de glissement qui glisse sur une face de glissement d’un premier élément,
• un système de blocage configurés pour définir l’écartement maximal entre les faces externes de la paire de premiers éléments, le système de blocage passant au travers d’orifices ménagés dans la paire de premiers éléments.

There is a tendency to solve the aforementioned drawbacks by means of a retention device for a plurality of ice screws comprising:

• a pair of first elements mounted facing each other, the pair of first elements being arranged to have parallel outer faces, each first element having two sliding faces,
• a pair of second elements mounted facing each other, the pair of second elements sliding relative to the pair of first elements, the pair of second elements being arranged to have parallel outer faces, each second element having two sliding faces which slides on a sliding face of a first element,
• a blocking system configured to define the maximum spacing between the outer faces of the pair of first elements, the blocking system passing through orifices provided in the pair of first elements.

The shifting device is remarkable in that the pair of first elements and the pair of second elements are made of polymer material. Each sliding face of a first element has an engaging element selected from a groove and/or a projection which cooperates with an engaging element chosen from a projection and/or a groove of a sliding face of a second element . The pair of first elements and the pair of second elements are made of polymer material which has a Young's modulus greater than 2000 MPa and an elastic compressive strength greater than or equal to 60 MPa.

In one development, each sliding face has at least two cooperating elements selected from a groove and/or a protrusion.

In a particular embodiment, each sliding face has at least one groove and one projection.

Advantageously, the two cooperation elements are arranged on either side of the through hole receiving the locking system.

Preferably, the first elements are identical to the second elements.

It is advantageous to provide that the first and second elements are made of cast polyamide PA6.

In an advantageous embodiment, the external surfaces of the pair of second elements are covered by a film of metallic material.

Advantageously, at least one spring is arranged between the pair of second elements to define a minimum spacing between the second elements.

Brief description of the drawings

• Fig 1 : la figure 1 représente, de manière schématique, en perspective, une configuration d’un dispositif de décintrement ;

• Fig 2 : la figure 2 représente, de manière schématique, en perspective, un des premiers ou seconds éléments formant un dispositif de décintrement.

Other advantages and characteristics will emerge more clearly from the following description of particular embodiments and implementations of the invention given by way of non-limiting examples and represented in the appended drawings, in which:

• Fig 1: Figure 1 shows, schematically, in perspective, a configuration of a decentring device;

• Fig 2: Figure 2 shows, schematically, in perspective, one of the first or second elements forming a decentring device.

As illustrated in Figure 1, the unbending device comprises a first pair of elements 1a which cooperates with a second pair of elements 1b. The two first elements 1a and the two second elements 1b each have an outer face 2 and at least two sliding faces 3. An embodiment of a first element or of a second element is illustrated in figure 2.

A first element 1a is in contact with two second elements 1b and a second element 1b is in contact with two first elements 1a. The second elements 1b slide on the first element 1a by means of their sliding faces 3 and the first elements 1a slide on the second element 1b by means of their sliding face 3.

The first elements 1a and the second elements 1b are arranged so that the external faces of the two second elements 1b are parallel and advantageously that the external faces 2 of the two first elements 1a are parallel.

The sliding of the first elements 1a relative to the second elements 1b makes it possible to modulate the height of the decentring device, that is to say the spacing between the two opposite external faces 2.

The decentring device has a blocking system which is configured to define the maximum spacing between the two external faces 2 of the first elements 1a. The modulation of the distance between the first two elements 1a will also modulate the distance between the two second elements 1b which will modulate the height of the decentring device.

Advantageously, the locking system comprises a rod 4 which is inserted to pass through the first elements 1a. In the illustrated embodiment, the rod 4 passes through an orifice 5 opening into the outer face 2 of the first two elements 1a which face each other.

The rod 5 can be a threaded rod which cooperates with two nuts 6 so as to define the maximum spacing authorized between the first two elements 1a.

In order to avoid a lateral shift of the pair of second elements 1b when the debending device is powered up, it is particularly advantageous to provide that each of the sliding faces 3 comprises a cooperation element in the form of a zone projecting 7a or a groove 7b. Comparative tests were carried out between unbending devices equipped with cooperation elements and devices without these elements. It emerged that, under load, the unclamping device devoid of the cooperation elements 7a, 7b sees its elements 1a and 1b shift laterally relative to each other, which results in a reduction in the mechanical performance of the unclamping device.

The projecting zone 7a of a sliding face 3 is configured to cooperate with the groove 7b of the sliding face 3 of the adjacent element with which it is in contact. The protruding zone 7a will slide inside the groove 7b so as to allow modulation of the height and length of the shifting device while preventing a lateral offset between the first and second elements 7a and 7b.

In a particular embodiment, each sliding face 3 has two cooperating elements which allows better lateral mechanical strength of the shifting device. It is particularly advantageous to provide that the two cooperating elements are arranged on either side of the orifice 5 arranged for the introduction of the rod 4 of the fastening system. In other words, the grooves 7b define cutting planes passing through the sliding faces 3, the external face 2 and perpendicular to the external face 2, it is advantageous for the through hole 5 to be located between the cutting planes .

By way of example, a sliding face 3 can have two grooves 7b and the associated sliding face 3 can have two projecting elements 7a which will move inside the grooves 7b. It is possible to provide that the first elements 1a have on each of their sliding face 3 grooves 7b or projecting zones 7a. The sliding faces 3 of the second elements 1b then have the complementary device, that is to say a projecting zone 7a or a groove 7b.

However, to facilitate mounting of the unbending device in cramped areas, it is particularly advantageous to provide that the four elements of the unbending device are identical and each have a groove 7b and a projecting area 7a. In this way, the companion who installs the decentring device can assemble the elements as they go along without worrying about a possible order of assembly in the different elements.

It is then advantageous that each element also has a through hole 5 for the installation of the rod 4 of the locking system.

A configuration of the shifting device with cooperation elements mounted on each of the sliding faces 3 allows a better absorption of the forces without increasing the volume occupied.

In addition to a good recovery of the forces, it is particularly advantageous to provide that the unbending device has a reduced mass in comparison with the devices of the prior art.

It is advantageous to provide that the pairs of elements 1a and 1b of the unbending device are made of polymer material and in particular of a polymer material which has a Young's modulus greater than 2000 MPa and whose elastic resistance in compression is greater than or equal to 60MPa. Advantageously, the material used to form the pairs of elements 1a and 1b is a polymer material obtained by casting.

The polymer material used is advantageously a material chosen from polyamides, polyethylene terephthalate (or polyethylene terephthalate or PETP), polycarbonates, polyvinyl chloride, polyamide 6.

Against all expectations, it appeared that a decentring device, the pairs of elements 1a and 1b of which are made of polymer material such as those defined above, can support a recovery of force on a load whose mass is greater than 30 tons. even more than 50 tons.

With such polymer materials, it is possible to form a decentring device which supports a mass greater than or equal to 20 tons, which allows its use in a very large number of construction sites. A dismantling device provided with four square-based elements each having a side length of 150 mm and 70 mm in height has a mass equal to 11 kilograms, while the steel dismantling device has a mass greater than 30 kilograms. The gain obtained on the total mass of the unbend device allows better use by the companion who can work more easily with a lighter product.

As indicated above, the unbend device has a locking system which has a rod 4 passing through the first two elements 1a in order to define the maximum spacing of the latter. When the unbending device is under load, part of the stress applied to the pair of second elements 1b is taken up by the rod 4. The use of elements made of polymer material makes it possible to obtain different coefficients of friction in comparison with what is obtained for a metallic unbending device which modifies the behavior of the unbending device.

It appeared that the use of four elements 1a and 1b made of polymer material associated with cooperation means 7a and 7b seems to induce greater stress on the rod 4 compared to the configurations of the prior art. It is therefore preferable to use a rod 4 whose elastic limit is at least equal to 90% of the load supported by the shifting device or at least equal to 80% of the load supported. It is also advantageous to provide that the rod 4 has a breaking limit equal to the load supported by the unbending device. The rod is advantageously produced by means of a ribbed prestressing bar. The prestressing bar is defined in particular by force value representing the elastic limit (typically in kiloNewton, kN) and by a breaking force value also presented in kN. These values of forces at the elastic limit and at rupture can be translated into an equivalent mass according to the relationship value of the stress (in Newtons) = mass of the supported load (in kg) * g vector acceleration (approximately 9.81m /s ² ).

In a particular embodiment, the external faces 2 of the second elements 1b intended to support the load and to rest on the ground are covered by a film of metallic material. Preferably, the thickness of the film of metallic material is less than 1 cm . It is advantageous to provide that the thickness of the film of metallic material is greater than 0.3 mm .

The use of films of metallic material 8 makes it possible to protect the external faces 2 of the second elements 1b when the decentring device is in contact with surfaces having flatness imperfections. This makes it possible to prevent the external surface 2 made of polymer material from being punched during stressing, which would lead to accelerated degradation of the second elements 1b.

Since the metal film 8 does not participate in the definition of the metal performance of the decentring device, it is advantageous to use an inexpensive metal material, the installation of which makes it possible to avoid the punching of the second elements 1b made of polymer material. The metallic material is advantageously made of aluminum or an aluminum alloy because this makes it possible to protect the external surfaces of the decentring device without weighing it down too much. It is also possible to use plates made of iron or an alloy containing iron, for example steel, even if this option makes the unbend device heavier without providing any mechanical gain. Other metallic materials are possible.

Advantageously, the films of metallic material 8 are fixed to the second elements 1b, for example by connectors 9 which pass through the films of metallic material 8 and which are inserted into orifices defined in the external faces of the second elements 1b.

In a preferred embodiment, the second elements 1b are separated from each other by one or more springs 10 which are configured to define a minimum spacing between the two second elements 1b. Advantageously, the second elements are separated by two springs 10 which are preferably identical. The rod 4 of the locking system passes between the two springs 10.

The use of springs 10 makes it possible to install the two second elements 1b one above the other during assembly of the decentring device. This configuration makes it possible to install the two second elements 1b in a secure manner without the risk of pinching the companion's fingers. Once the two second elements have been installed, the two first elements can be brought together by means of the rod 4 so as to separate the second elements and thus manually adjust the height of the decentring device.

It is particularly advantageous to form blind holes 11 in the internal faces of the second elements 1b in order to block the movement of the springs laterally with respect to the elements 1b. The springs are non-adjoining coil springs. The springs are configured to allow manual height adjustment.

The use of a polymer material makes it possible to form first and second elements that are lighter than those of the prior art. The change in behavior linked to the better sliding of the elements on each other makes the use of cooperation elements particularly interesting in order to obtain high mechanical performance.

The rod 4, as well as the nuts are advantageously made of steel in order to withstand the mechanical stresses undergone by the shifting device. It can be the same for the springs and the metal film 8. However, it is also possible to use other materials and possibly composite materials, for example composite materials reinforced with glass fibers for any of the aforementioned metallic elements. Advantageously, the metallic material used has an elastic limit resistance value greater than 355 MPa.

Claims (8)

Displacement device comprising:
- a pair of first elements (1a) mounted facing each other, the pair of first elements (1a) being arranged to have parallel outer faces (2), each first element (1a) having two sliding faces (3 );
- a pair of second elements (1b) mounted facing each other, the pair of second elements (1b) sliding relative to the pair of first elements (1a), the pair of second elements (1b) being arranged to present parallel external faces (2), each second element (1b) having two sliding faces (3) which slide on a sliding face (3) of a first element (1a);
- a blocking system configured to define the maximum spacing between the outer faces (2) of the pair of first elements (1a), the blocking system passing through orifices (5) made in the pair of first elements ( 1a),
shifting device in which the pair of first elements (1a) and the pair of second elements (1b) are made of polymeric material, in which each sliding face (3) of a first element (1a) has a cooperating element chosen from a groove (7b) and/or a projection (7a) which cooperates with a cooperating element chosen from a projection (7a and/or a groove (7b) of a sliding face (3) of a second element (1b) and in which the pair of first elements (1a) and the pair of second elements (1b) are made of a polymer material which has a Young's modulus greater than 2000MPa and an elastic compressive strength greater than or equal to 60MPa. Unbending device according to Claim 1, characterized in that each sliding face (3) has at least two cooperation elements chosen from among a groove (7b) and/or a projection (7a). Unbending device according to Claim 2, in which each sliding face (3) has at least one groove (7b) and one projection (7a). Unbend device according to one of Claims 2 and 3, in which the two cooperation elements are arranged on either side of the through hole (5) receiving the locking system. Retention device according to one of the preceding claims, characterized in that the first elements (1a) are identical to the second elements (1b). Retention device according to one of the preceding claims, characterized in that the first and second elements (1a, 1b) are made of cast polyamide PA6. Retention device according to the preceding claim, characterized in that the external surfaces (2) of the pair of second elements (1b) are covered by a film of metallic material (8). Retention device according to one of the preceding claims, characterized in that at least one spring (10) is arranged between the pair of second elements (1b) to define a minimum spacing between the second elements (1b).