ES2674899B1 - REINFORCED BOARD - Google Patents

Description

DESCRIPTION

Reinforced board.

OBJECT OF THE INVENTION

The present descriptive report defines a reinforced joint intended for the serial connection of pipes, preferably for pipe pipes, and therefore the invention is intended for the civil engineering sector and more specifically for the assembly work of hydraulic pipes.

By means of the use of this reinforced joint it is achieved that the junction zone between the pipes is perfectly sealed, for which, prior to the connection of a pipe in the adjoining, the joint is introduced in a simple and manual way in a slot of one of the pipes, and the correct sealing is achieved because said joint has a flexibility similar to the plastic joints which allows its installation manually, as well as obtaining a joint that has a high internal resistance only within reach of metal joints.

BACKGROUND

The joints for the connection of pipes are elements commonly known by the general public. They are generally referred to as seals, and are components that serve to ensure the tightness of the joint between two pipes. These joints have their reason for existence in the irregularity of the faces of the pipes, which means that by means of a joint can be corrected the possible failures that could exist in the manufacture of said pipes, just as in certain pipes there is a difference of diameter that allows the coupling of one pipe with the next. Therefore, these elements save money in the machining of the joining surfaces because it does not make it necessary to be completely exact the coupling between two pipes since said joints correct said possible failures and ensure the tightness of the hydraulic pipeline, as well as allowing the development of typologies of pipes that allow the direct coupling in series between them, being able to ensure the tightness in said joint zone.

Depending on the type of union of the pipes, different types of joints arise, which have been subject to evolution and improvements over time. In particular, the present invention is directed to pipes encochado, ie tubes that have at one end a slight widening with a groove to accommodate joints that make that when introducing the next pipe, the union between the two pipes is watertight.

These pipes can be made of different materials, such as plastic, metal or cement, just as the uses can be diverse, such as drinking water transport, irrigation, recycled water or sanitation. In this sense, it is worth highlighting the two usual methods of installation of joints for this type of conduction, which is the automatic method with special tools and the manual method. Basically the automatic method with special tools is a method used with joints or steel rings, known in the industrial field as a "rieber" system, in which the pipe is heated, and with the help of special tools the gasket is inserted inside of the tube and this adheres to the annular shape of the joint. On the other hand, the manual method is the conventional one for joints or plastic rings, and it consists of bending joint by exerting a manual force in such a way that the joint can be introduced inside the tube, and once it is inside it is no longer necessary. exert that force and the board returns to its annular configuration and fits inside the slot.

It is important to say that while the metallic or steel joints are elements that have not suffered hardly any variation with respect to their annular and flat configuration, the plastic joints have been subject to different improvements. There has been evolution in the joints between pipes, such as the one defined in the register US4842305, or the one defined in the register ES2411468, in which a clamp for improved pipe is detailed, although this type of external connection is not optimal for the typology of tubes encopados. However, there has also been a noticeable evolution in the internal boards, in which you can start from the boards conventional plastic and elastic, as for example the one defined in the registration ES1001991, in which an annular seal of plastic material is observed which is introduced in the slot provided in the tube, in such a way that when the next pipe is introduced, the joint contracts and the tightness of the joint area is secured; and in which registers with more sophisticated designs and forms have been developed, among which we can highlight, for example, the seal of the register EP0211428 in which an elastic joint is defined with two widening of variable shapes at its ends that double contain to possible leaks; the joint defined in register ES233242 defining a joint for pipes with a plurality of teeth or projections, which, as in the previous case, allow a good sealing of the joint zone between two pipes; the registration US201300001821 in which a joint with perimetral recesses is defined on one of its faces in such a way as to allow a vacuum or suction effect to be generated against the face of the other pipe and to ensure sealing; US7328493 which defines a joint with different areas, such as for example one with a plurality of teeth and with differentiated ends, intended for joining metal pipes, with which said joining area is also secured; or the registration US7845686 that defines a combined system of pipes with special grooves that require a joint with specific shapes for said connections, in which the joints are plastic and can have a zone with particular teeth or spreads in different areas. In all existing records, as can be seen, joints of a plastic and / or elastic nature are defined, which have a flexibility that allows them to be manually entered, as well as the adequacy of their position or form so that the introduction of the next pipe is possible and the tightness of the joint area is ensured.

However, none of the joints defined above has a high resistivity, and both in the case of being able to undergo unexpected stresses, that the joint is not perfect and the introduction of the next pipe can damage the joint, that the alignment between pipes not correct, that the manual coupling in the slotted tube is not good due to a defect in the plastic material or in the grooving itself, or to a bad coupling between the The tubes can cause the joint to move, break, or be deformed so that the joint is susceptible to non-tightness, and that is why it is common to see in the assembly of pipes that when pressure tests are made, leaks in diverse joints due to these problems derived from low resistance.

For this reason, there is a need to develop a joint for pipe pipes that is defined below, which enjoys a similar flexibility of plastic joints which allows its installation manually, and also enjoys a high resistance only within reach of steel joints which makes it resistant to unsupported actions by joints of plastic material. Taking into account the existing background and the solution described below, it can be pointed out that the present invention solves the problems existing in the joining of pipe lines and introduces an optimized sealing solution for the connection of pipes, in addition to its easy installation reduces the costs of both investment and manufacturing.

DESCRIPTION OF THE INVENTION

The gasket defined herein is a reinforced gasket for the connection and coupling of coiled pipes with which a perfect sealing of the joining zone between said pipes is achieved due to the combination of the previously defined characteristics of flexibility and high strength Bearing in mind this essential aspect, this joint is a single piece with a flexible ring shape of a plastic or synthetic nature, such as rubber or rubber, which is internally reinforced by a rigid ring which gives it resistance and rigidity during operation. This rigid ring is preferably of a metallic nature, like steel, and may also be of high rigidity plastic. By combining both materials in a single piece, the joint is flexible enough to be manually positioned in the groove of the hooked tube, just as it is rigid enough to give the joint the qualities of rigid steel joints.

In the definition of the board it is not only important to define the structure, which as it has just been exposed is a single piece composed of two differentiated elements, a flexible body that has a reinforcement incorporated in its core, but it is also important to define the shape necessary to ensure the correct seal of the joint between the tubes.

The reinforced joint is a single piece with ring configuration that is installed in the contour of the groove of the end of the tube. This joint has a particular and necessary section, defined essentially in a flexible body with rounded contours and an internal reinforcement of high resistance.

The body with rounded contours has a configuration that is coupled to the groove of the coiled tube. This implies that in its upper part there are two converging faces with a rounded connection, said flexible body being of synthetic nature in total contact with the groove located in the internal face of the tube that is encased. In its lower part a horizontal and split base is defined in which a flange with a triangular configuration protrudes at an intermediate point. When the joint is in rest position, the flange projects from the horizontal of the base, while when the joint is working, that is to say, the connection between both pipes is made, the flange deforms towards its upper part in such a way that the base of the flange is placed horizontally giving continuity to the horizontal base of the main body. In this way, when the joint is working, the base of the joint is horizontal in its entirety and is in total and direct contact with the outer face of the pipe that has just been introduced. This deformation is possible because as mentioned, the base is split, that is, it has a horizontal part but the other part of the base is open, so that there is an open area that allows the area of the flange to be be occupied when deformation occurs.

At this point it is important to say that the deformation of the joint and the perfect fit or coupling with the walls of the tubes is due to the fact that the body material is flexible and synthetic in nature. But to solve the problems derived from an excess of flexibility, in the present meeting there is the second element basic in its structure, which is the internal reinforcement, with which the problems indicated in the background section are solved.

The internal reinforcement is an element that is located mainly in the part of the joint that is exposed to the blow or to the introduction of the pipe, and that previously we have commented that it has a horizontal base. This reinforcement is in any section a flat, plate-like element, which extends obliquely inside the flexible body from the area of the joint where the pipe is received to the opening area of the body, or the zone occupied by the deformation of the flange. In this way, the reinforcement forces the joint to remain in contact with the groove of the tube in its upper part and forces the horizontal base to remain horizontal without the friction of the inserted tube twisting the lower part of the flexible body, allows the flange to deform correctly in the open space enabled for that purpose in the body, and makes once the tube has been introduced, the base of the body including the flange is in direct and total contact with the outer face of the tube inserted. By means of this reinforcement, the correct mechanical behavior of the joint against the stresses produced in the introduction of a tube in the other is guaranteed, as well as allowing the joint to be strengthened against the own stresses and pressures produced by the fluid currents that run through said pipes, taking into account that the junction zone between two pipes is a weak point in a hydraulic pipeline.

To better illustrate the previously described, it should be mentioned that the flexible body can vary in its composition depending on the type of fluid, temperature of this fluid or the exposure of the joint to the elements. The fluid used in pipeline conduits is generally potable water and sanitation, and therefore preferred compositions of the flexible body of the gasket may be EDPM rubber, NBR rubber or silicone rubber. In all these cases, as already defined above, the body is itself a flexible annular element of a plastic or synthetic nature, such as rubber or rubber. On the other hand, the main feature of the reinforcement is its high strength, for which it is considered that the preferred composition of said ring is steel, which in order to acquire the characteristics of slight elasticity must be tempered and tempered, of the type conventional used in elements such as springs, although the reinforcement can also be other compounds with high strength such as fiberglass or carbon fiber. Also in this case, the reinforcement must be an annular element that even having a certain elasticity, is a resistant and rigid element so that its correct function in front of the efforts received by the assembly of the joint. The combination of the characteristics of the elements that form the joint means that the reinforced joint meets all the requirements necessary for a correct tightness in the union of pipe lines.

To complete the description that is being made and in order to help a better understanding of the characteristics of the invention, a set of drawings is included as an integral part of the same, in which, with an illustrative and non-limiting nature, lengths, contours or shapes The following has been represented:

Figure 1 is a free perspective representation of the reinforced joint object of the present invention.

Figure 2 is a representation of the connection of two coiled tubes.

Figure 3 is a representation of a section of both the reinforced joint and the tube encased with its groove, bearing in mind that the reinforced joint is housed in said groove.

Figure 4 is a representation of the section of the connection zone between two pipes, in which the board is in rest position waiting for the connection between said pipes.

Figure 5 is a representation of the section of the connection zone between two pipes in which the pipes are already connected and therefore the joint is working for the correct sealing of the joint.

Figure 6 is a representation of the necessary correlation between the dimensions of the groove of the crimped tube and the reinforced joint.

Figure 7 is a representation of the installation form of the joint.

Description of the drawings

Figure 1 represents the reinforced joint in perspective, and it can be seen how it is a single piece constituted by a body (1) with rounded contours that has a configuration that is coupled to the slot of the tube encoded, said body (1) a flexible element of synthetic nature, and also constituted by a high strength internal reinforcement (2). Furthermore, in the lower part of the body (1) there is a horizontal and split base from which a flange (3) with a triangular configuration and constituted by the same material as the body (1) protrudes at an intermediate point. The body has an open area (not referenced) intended for the necessary deformation of the flange (3) when the joining of the two pipes occurs. It can also be seen that the internal reinforcement (2) is an annular and flat element, like a plate, which is located mainly in the part of the joint that is exposed to the blow or to the introduction of the pipe, extending the reinforcement ( 2) obliquely inside the flexible body (1) up to the opening area of the body or the area occupied by the deformation of the flange. Taking into account the basic composition of the board, it can be said that the assembly is a single piece that is arranged in the shape of a ring, and that it is flexible due to the plastic nature of its body, and that it is reinforced by internal reinforcement rigid which gives resistance and rigidity during operation. By combining both materials in its structure, the joint is flexible so that it can be manually placed in the groove of the hooked tube, just as it is rigid to provide the joint with the qualities of steel joints.

Figure 2 represents the series connection of two pipes (4 and 4 "), in such a way that it can be seen that each pipe has a slightly enlarged area where one slot is located (5 and 5). ") in which the reinforced gasket object of the present invention is located. The connection is simply by inserting the smooth end of an encoded pipe (4 ") into the slightly widened part and disposing the groove (5) of the previous pipe (4) in which previously the gasket object of the present invention has been manually introduced. invention.

In Figure 3 it can be clearly seen how the reinforced joint, formed by its flexible body (1) with a flange (3) and an internal reinforcement (2), is a single piece with a ring shape that is manually inserted inside of the coiled tube (4) and is located in the groove (5), in such a way that in resting position the upper part of the reinforced joint adheres to the internal walls of said groove (5) while waiting for the introduction of the next tube crimped.

Figure 4 is a representation that proceeds with the above explanations and illustrates the section of the connection zone between two encoded pipes (4 and 4 "), and represents the moment prior to the connection between said pipes and therefore represents the joint reinforced in resting position while waiting for the connection between the tubes.In this figure it can be seen how the body (1) has the rounded contours and has a configuration that is coupled to the groove (5) of the tube (4) This implies that in its upper part there are two converging faces (11 and 12) with a rounded connection, said flexible body (1) therefore remaining in full contact with the groove (5) located on the inner side of the tube. In its lower part a horizontal base (14) is defined and from which a flange (3) with a triangular configuration protrudes at an intermediate point.In this rest position it is noticed that the base of the body (1) is open d e such that there is an open area (13) destined to be occupied by the flange (3) upon deformation by the introduction of the crimped tube. This figure also shows how the internal reinforcement (2) is located mainly in the part of the joint that is exposed to the blow or the introduction of the pipe (4 "), the reinforcement (2) extending obliquely inside the body (1) flexible up to the opening zone of the body or the zone occupied by the deformation of the flange (3).

Figure 5, as a continuation of the previous figure, represents the moment of connection between both pipes (4 and 4 "). In this figure it is highlighted how the flange (3) has deformed and has occupied the open area (13) of the flexible body (1) At this time the joint is working and ensuring tightness, ie the flange (3) is deformed towards its top in such a way that part of the flange is placed horizontally giving continuity to the base horizontal (14) of the main body.Thus, the board is on its upper part attached to the face of the slot (5) of the tube (4) by its converging faces (11 and 12), and attached to the external face of the next tube (4 ") by the horizontal extension of both the horizontal base (14) and At this point it can be seen how the internal reinforcement (2) ensures the correct mechanical behavior of the joint against the efforts produced in the introduction of a tube in the other, as well as reinforcing the joint in front of the own tensions and pressures produced by the currents of the fluids that run through said pipes, taking into account that the zone of union between two pipes is a weak point in a pipeline.

Figure 6 shows the necessary correlation between the dimensions of the slot (5) of the tube (4) and the reinforced joint. In particular, the angles of the convergent faces (11 and 12) can be seen with respect to the horizontal base (14) and its correlation with the angles of the internal faces of the slot (5) with respect to the horizontal of the tube (4). It can be seen that there is an angle and that is the angle of the converging face of the body (1) that makes the front stop with the face of the groove (5) of the tube (4) when the second tube is inserted into the joint , this angle being and preferably in a range between 30 ° and 60 °. On the other hand

there is an angle P which is the angle of the converging face of the front body (1) of which is engaged on the face of the groove (5) of the tube (4) in the part where the next tube is inserted, being this angle P preferably in a range between 30 ° and 60 °. Although both angles coincide in the range, it is emphasized that they do not have to be the same. Finally, it can be observed how the internal reinforcement (2) extends obliquely inside the flexible body (1) up to the opening area of the body or the area occupied by the deformation of the flange (3) generating an angle Q that can be Consider how the bisector of the angle generated between the converging face of the front body (1) that fits is engaged on the face of the slot (5) of the tube (4) in the part where the next tube and the tube is inserted. horizontal base, therefore it can be said that approximately Q = P / 2.

Finally, in Figure 7 can be seen a representation of the installation of a joint, which as has been seen throughout the memory is a manual installation, in which the joint is exerted a manual force (F) at a point of its contour and a deformation (6) is generated at that point of the joint in such a way that the joint as a whole acquires a domed shape as a kidney. The gasket is then inserted into the groove of the crimped tube. Once that manual force (F) is no longer exerted and the gasket is in the groove, the gasket returns to its conventional circular shape and adheres and fixes completely to the walls of the groove, ensuring the sealing at said connection point between pipelines.

A preferred embodiment invention, taking into account the previous figures, can be defined as an annular joint constituted by a flexible rubber body (1) with a flange (3) in its lower part and an internal reinforcement (2) of steel, having an open area (13) intended for the deformation of the flange (3) by the insertion action of the next shrunk pipe, in which the gasket is inserted in a groove (5) of a pipe (4), in such a way that the joint has an angle Y of 60 °, an angle P of 45 ° and an angle Q of 22 °, with which a correct connection is obtained between the converging faces of the body (1) with the internal walls of the groove (5) and a strong connection against possible torsional forces or pressure of the fluid because once the next tube is inserted into the previous pipe, the body (1) and the deformation of the flange (3) generate a surface horizontal, and therefore the entire body contour (1) is in contact with the two pipes, the reinforcement (2) ensures, reinforces and stiffens the assembly, and therefore a total sealing is achieved.

Described sufficiently in what precedes the nature of the invention, taking into account that the terms that have been written in this specification should be taken in a broad and non-limiting sense, as well as the description of the way to put it into practice, and, demonstrating which constitutes a positive technical advance, that is why the registration is requested, being what constitutes the essence of the aforementioned invention, which is specified in the following claims.

Claims (4)

1. Reinforced gasket for the connection and coupling of pipes in a hydraulic line, in which the reinforced gasket is an annular element that is manually introduced into the groove (5) of the widened area of said pipes (4) , and in which the reinforced joint is characterized in that it is a single piece that is constituted by a body (1) of flexible material having rounded contours, in whose upper part it has two converging faces (11 and 12) topped with a rounded union, in which in its lower part a horizontal base (14) is defined, from which a flange (3) with a triangular configuration protrudes at an intermediate point, and in which at the base of said body (1) there is an open area (13) intended to be occupied by the flange (3) upon deformation by the insertion of the crimped tube; and wherein there is an internal reinforcement (2) of high strength that extends obliquely in the manner of a plate in the core of the body (1) flexible from the part of the joint that is exposed to the blow or to the introduction of the pipe to the open area (13) of the body. 2. Reinforced joint, according to the features of claim 1, characterized in that the angles that are generated between the converging faces (11 and 12) of the body (1) with respect to the horizontal base (14) of the body itself (1) ) are identical and correlated with the angles generated between the internal faces of the groove (5) with respect to the horizontal of the tube (4) so that the upper part of the body (1) remains in full contact with the internal faces of the slot (5). 3. Reinforced joint, according to the features of claim 2, wherein both generated angles are characterized because they are comprised in a range between 30 and 60 °. 4. Reinforced gasket, according to the features of claim 1, characterized in that when the connection of the pipes is produced the flange (3) is vertically deformed so that a horizontal surface is generated in contact with the outer face of the tube introduced which gives continuity to the horizontal base (14) of the body (1).