BR102018002516B1 - SYSTEM, METHOD FOR SAFELY COUPLING TUBULAR ELEMENTS AND VERTICAL RATCHET ANTI-ROTATION DEVICE - Google Patents

Abstract

SYSTEM, METHOD FOR SAFELY COUPLING TUBULAR ELEMENTS AND VERTICAL RATCHET ANTI-ROTATION DEVICE. In one embodiment, a vertical ratchet anti-rotation device (130) includes a ratchet mechanism (220) pivotally coupled to a proximal end of a first tubular member (120) in a first recessed area (140) located on a shoulder of the first tubular element (120). A distal end of the ratchet mechanism (220) includes a first plurality of angled teeth (230, 330, 430) and a spring (240, 340a, 340b, 445) that allows the ratchet mechanism (220) to rotate in a direction vertical position within the first recessed area (140). The anti-rotation device may also include a toothed insert (210) mechanically coupled to a second tubular element (110) in a second recessed area (150) located in a shoulder of the second tubular element (110). The toothed insert (210) may include a second plurality of angled teeth (235, 335) positioned to engage with the first plurality of angled teeth (230, 330, 430) of the ratchet mechanism (220). The spring (240, 340a, 340b, 445) is compressible during coupling of the tubular elements (110, 120) to allow the ratchet mechanism (220) to move vertically over the second plurality of angled teeth (235, 335).

Description

Technical Field

[001] The present disclosure relates generally to connector assemblies and more particularly to a vertical ratchet anti-rotation device.

State of the Art

[002] Offshore oil and gas drilling operations typically include the composition of strings of tubing or casing elements, often of relatively large diameter. The rope of tubular elements can be routed to the ground or submerged in water. In some situations, the string of tubular elements can be used as conduits through which a well can be started. The joint between the elements of such tubular strings must provide both structural strength and fluid pressure integrity. Such characteristics of a joint can be provided, for example, by welding. However, because welding is a time-consuming operation, and drilling rig rates are high, particularly overseas, mechanical connectors are generally preferred. Typical mechanical connectors available include threaded type connectors in which the tubular elements are mutually rotated to thread a pin and housing connector assembly, break lock connectors, and snap lock connectors.

[003] In threaded mechanical connector assemblies, an externally threaded end, known as a pin, mates with an internally threaded section, known as a housing. The pin and housing in a threaded connector assembly are designed to be engaged with each other and rotated to a specific torque value to connect the ends. After the connection is made, anti-rotation devices can be installed to secure the pin and housing together at a desired compounding torque. Anti-rotation devices are designed to ensure that the threaded portions of the connector assembly are not tightened beyond the desired compounding torque or loosened from each other in response to forces applied to the pipe or casing elements on the string.

[004] Existing anti-rotation devices generally feature a mechanical switch that can be selectively positioned in a recess between the pin and housing of the connector assembly to prevent rotation of the pin and housing, relative to each other, in a particular direction. , once the compounding torque is reached. Unfortunately, these wrenches usually don't spring into action to engage with the connector assembly until the connection is slightly loosened. That is, the switches are usually initially positioned in the recesses of the connector assembly and then the pin and housing are rotated slightly relative to each other to energize the switch. As a result, the connection can be secured with a torque different from the initial desired compounding torque.

[005] Additionally, some existing anti-rotation switches are designed to interact very closely with the connector assembly to fill a recess therein. As such, these keys can be difficult to position into the corresponding recess and must often be hammered into engagement with the connector assembly using a large amount of force. This hammering process takes an undesirable amount of time and energy to ensure that the keys are housed in their respective recesses in the connector assembly. Often, the force applied causes the key to "bite" into the housing connector, resulting in damage to the connector.

Summary of the Invention

[006] In one embodiment, a vertical ratchet anti-rotation device includes a ratchet mechanism pivotally coupled at a proximal end to a first tubular element in a first recessed area located on a projection of the first tubular element. A distal end of the ratchet mechanism includes a first plurality of angled teeth and a spring that allows the ratchet mechanism to rotate in a vertical direction within the first recessed area. The vertical ratcheting mechanism may also include a toothed insert mechanically coupled to a second tubular member in a second recessed area located on a shoulder of the second tubular member. The toothed insert may include a second plurality of angled teeth positioned to engage the first plurality of angled teeth of the ratchet mechanism. The spring of the ratchet mechanism is compressible during coupling of the first and second tubular members to allow the ratchet mechanism to move vertically over the second plurality of angled teeth of the toothed insert. The spring is expandable during decoupling of the first and second tubular members to engage the first plurality of angled teeth of the ratchet mechanism with the second plurality of angled teeth of the toothed insert.

[007] In an exemplary embodiment, a method for securely coupling tubular elements includes preparing a first tubular element and a second tubular element to receive a pivoting, vertically coupled anti-rotation device. Preparation of the first tubular member and the second tubular member may include forming a first recessed area within a shoulder of the first tubular member and forming a second recessed area within a shoulder of the second tubular member. The method may then include mounting the pivoting, vertically coupled anti-rotation device. The assembly of the vertical, pivoting ratchet anti-rotation device may include arranging a ratchet mechanism to the first tubular member within the first recessed area, wherein the ratchet mechanism is pivotally coupled at an end proximal to the first tubular member. A distal end of the ratchet mechanism may include a first plurality of angled teeth and a spring that allows the ratchet mechanism to rotate in a vertical direction within the first recessed area. Assembly of the vertical, pivoting ratchet anti-rotation device may also include arranging a toothed insert to the second tubular member within the second recessed area, wherein the toothed insert has a second plurality of angled teeth positioned to engage the first plurality of teeth. angles of the ratchet mechanism. The method may further include coupling the first tubular element and the second tubular element to a compounding torque, wherein during coupling of the first and second tubular elements, the spring is compressible to allow the ratchet mechanism to move vertically about the second plurality of angled teeth of the toothed insertion.

[008] Technical advantages of certain embodiments may include minimizing damage caused to the load projection of the tubular elements during installation and removal of the vertical ratchet anti-rotation device. Another advantage provided by certain embodiments includes obtaining high resistance to rotation by locating the vertical ratchet anti-rotation device on the load shoulder of the tubular members. Another advantage provided by certain embodiments allows automatic locking of the vertical ratchet anti-rotation device when the first and second tubular elements are coupled to their composition torque. Yet another advantage provided by certain embodiments includes having the anti-rotation device pre-installed in the connectors before shipping the tubular elements, thereby alleviating the need to drill or tap a hole in the tubular elements before installing the anti-rotation mechanism in place.

[009] Other technical advantages will be readily apparent to one skilled in the art from FIGURES 1-5, descriptions and claims. Furthermore, although specific advantages have been enumerated above, various embodiments may include all, some, or none of the enumerated advantages.

Brief Description of the Drawings

[0010] For a more complete understanding of the current disclosure and its features and advantages, reference is now made to the following description, together with the accompanying drawings, in which:

[0011] FIGURE 1 illustrates a front view of a connector assembly comprising a female tubular member and a male tubular member having a vertical ratchet anti-rotation device, in accordance with an embodiment of the present disclosure;

[0012] FIGURE 2A illustrates a vertical, pivoting ratchet anti-rotation device in the open position, according to an embodiment of the present disclosure;

[0013] FIGURE 2B illustrates the vertical, pivoting ratchet anti-rotation device in the engaged position, according to an embodiment of the present disclosure;

[0014] FIGURE 3A illustrates a vertical ratchet anti-rotation device with multiple springs in the open position, according to an embodiment of the present disclosure;

[0015] FIGURE 3B illustrates the multi-spring vertical ratchet anti-rotation device in the engaged position, according to an embodiment of the present disclosure;

[0016] FIGURE 4A illustrates an angularly rotatable anti-rotation device in the open position, in accordance with an embodiment of the present disclosure;

[0017] FIGURE 4B illustrates the angularly rotatable anti-rotation device in the engaged position, in accordance with an embodiment of the present disclosure; It is

[0018] FIGURE 5 illustrates a method for securely coupling tubular elements using a vertical ratchet anti-rotation device, in accordance with an embodiment of the present disclosure. Detailed Description of Figures

[0019] Certain embodiments in accordance with the present disclosure are directed to an improved vertical or angular ratchet anti-rotation device designed to prevent rotation of a first tubular element of a connector assembly relative to a second tubular element of the connector assembly . A vertical anti-rotation device includes several features that facilitate easier, faster and more accurate clamping of tubular elements to prevent rotation of the threaded tubular elements of the connector. For example, the vertical ratchet anti-rotation device may include features that prevent disengagement of the threaded tubular elements once the desired torque is applied to the threaded tubular elements.

[0020] As explained in greater detail below, in certain embodiments, a vertical, pivoting ratchet anti-rotation device that can prevent the tubular elements from decoupling once they are brought to a compounding torque. The vertical, pivoting ratchet anti-rotation device may comprise a ratchet mechanism (e.g., a pawl) that engages a toothed insert (e.g., a rack). The ratchet mechanism and toothed insert can be aligned within the shoulders of the tubular elements. The proximal end of the ratchet mechanism can be pivotally coupled to the male tubular member using a threaded screw. The distal end of the ratchet mechanism includes a plurality of angled teeth and a spring. The toothed insert can be mechanically coupled to the female tubular member. As compounding torque is applied to the tubular elements, the ratchet mechanism can pass over the toothed insert in the female tubular element. By traversing the leading edge of the ratchet mechanism teeth, the ratchet mechanism can roll in and out of the toothed insert. The ratchet mechanism spring can compress as the ratchet mechanism slides over the toothed insert and expand to force the distal end of the ratchet mechanism - and thus the angled teeth of the ratchet mechanism - into the toothed insert. In some embodiments, a locking screw may be installed in the ratchet mechanism to provide a mechanical locking feature. Once engaged, the teeth of the ratchet mechanism and toothed insert can prevent the tubular elements from disengaging.

[0021] In some embodiments, the vertical ratchet anti-rotation device is implemented using a multiple-spring vertical ratchet anti-rotation device. The multi-spring vertical ratchet anti-rotation device may include an upper ratchet device coupled to the male tubular member using one or more springs and a lower ratchet device coupled to the female tubular member using one or more springs. The upper ratchet device may have a plurality of angled teeth facing the lower ratchet device and the lower ratchet device may have a plurality of angled teeth facing the upper ratchet device. As the tubular elements are brought to their compounding torque, the springs of the upper and lower ratchet devices can compress allowing the teeth of the ratchet mechanisms to slide past each other. The springs of the upper and lower ratchet devices can compress as the ratchet mechanisms move past each other and expand to force the upper and lower ratchet devices - and thus the teeth of the ratchet mechanism - one into the other. Once engaged, the teeth of the upper and lower ratchet devices can prevent the tubular elements from disengaging. FIGURES 1-5 provide additional details of a vertical ratchet anti-rotation device in accordance with certain embodiments.

[0022] FIGURE 1 illustrates a front view of a connector assembly 100 comprising a female tubular member 110 and a male tubular member 120 having a vertical ratchet anti-rotation device 130 (the female tubular member 110 and the male tubular member 120 may be referred to together as "tubular elements 110 and 120"). In the illustrated embodiment, the load shoulder of the male tubular member 120 has a male tubular recessed area 140. Similarly, the load shoulder of the female tubular member 110 has a female tubular recessed area 150 (the male tubular recessed area 140 and the female tubular recessed area 150 may be collectively referred to as "recessed areas 140 and 150"). As shown in greater detail in FIGURES 2 and 3, components of the vertical ratchet anti-rotation device 130 may be located with recessed areas 140 and 150.

[0023] The female tubular element 110 may have internal threads, while the male tubular element 120 may have external threads. In certain applications, the female tubular member 110 may be referred to as the "housing" and the male tubular member 120 may be referred to as the "pin." The case and pin are designed to be coupled together. These tubular elements may include, for example, lengths of a large diameter wire rod or casing.

[0024] In some embodiments, the pin is formed on the first tubular component and the housing is formed on the second tubular component, such that the connector assembly 100 is integral to the tubular components being connected. In other embodiments, the pin and housing may be separate components that are connected to their respective tubular components as desired to facilitate connection. However, the present disclosure is not limited to any specific pin and housing configuration with respect to the female tubular member 110 and the male tubular member 120 being connected.

[0025] When coupling the female tubular element 110 with the male tubular element 120, it is desirable to rotate the tubular elements 110 and 120 relative to each other until the tubular elements 110 and 120 reach a desired compounding torque. As the tubular elements 110 and 120 reach this compounding torque, one or more vertical ratchet anti-rotation devices 130 may automatically engage to prevent the tubular elements 110 and 120 from rotating out of their designated compounding torque.

[0026] As illustrated in FIGURE 1, the vertical ratchet anti-rotation device 130 may be aligned within the recessed areas 140 and 150. In some embodiments, the recessed areas 140 and 150 are tangent to the sides of the female tubular member 110 and the tubular member male 120. The vertical ratchet anti-rotation device 130 can ensure that a secure connection is formed around the entire boundary between the female tubular member 110 and the male tubular member 120. Although FIGURE 1 is illustrated as a single vertical anti-rotation device 130 , any number of vertical ratchet anti-rotation devices 130 may be used in the connector assembly 100. For example, vertical ratchet anti-rotation devices may be installed around the connector assembly 100 at certain intervals (e.g., every 45, 90, or 180 degrees).

[0027] In certain embodiments, recessed areas 140 and 150 may be milled into the load shoulders of the female tubular element 110 and the male tubular element 120 once the tubular elements 110 and 120 are coupled to the desired compounding torque. In some embodiments, the recessed areas 140 and 150 may be milled out of place and/or included in the design of the female tubular member 110 and the male tubular member 120. FIGURES 2 and 3 provide a more detailed view of the vertical ratchet anti-rotation device 130, according to certain modalities.

[0028] FIGURE 2A illustrates a vertical, pivoting ratchet anti-rotation device 205 in an open position. In the illustrated embodiment, the vertical, pivoting ratchet anti-rotation device 205 comprises a toothed insert 210 within the female tubular recessed area 150 and the ratchet mechanism 220 located within the male tubular recessed area 140.

[0029] The toothed insert 210 represents any suitable insert capable of engaging the ratchet mechanism 220 to prevent decoupling of the female tubular member 110 and the male tubular connector 120. The toothed insert 210 may be made of any suitable material (e.g., metal, metal alloy, plastic, composite material, etc.). Additionally, the toothed insert 210 may be scalable based on the size and application of the tubular elements 110 and 120. For example, the larger diameter tubular elements 110 and 120 may require a wider toothed insert 210, while the larger diameter tubular elements 110 and 120 may require a wider toothed insert 210, while the toothed insert 210 of smaller diameter 110 and 120 may allow a smaller toothed insertion 210.

[0030] The toothed insert 210 may comprise a plurality of insertion teeth 235 facing upward toward the ratchet mechanism 220. The toothed insert 210 may have any suitable number of insertion teeth 235. In the illustrated embodiment, the plurality of teeth The toothed insert 210 may also utilize any suitable pattern for the plurality of insertion teeth 235 for the purpose of distributing the force created when the female tubular member 110 and the male tubular member 120 tend to decouple.

[0031] In the illustrated embodiment, the toothed insert 210 is mechanically coupled to the female tubular recessed area 150 of the female tubular element 110 using threaded insertion screw 250. In some embodiments, the toothed insert 210 is installed tangent to the side of the element female tubular 110 within a female tubular recess area 150. In this way, the toothed insert 210 can be replaceable in the event that the toothed insert 210 is damaged. For example, if one or more insertion teeth 235 becomes damaged or breaks, the toothed insert 210 can be replaced by removing the threaded insertion screw 250 and installing a new toothed insert 210.

[0032] The ratchet mechanism 220 represents any suitable mechanism capable of rotating within the male tubular recessed area 140 to engage with the toothed insert 210. The male tubular recessed area 140 may be sized to leave a space between the ratchet mechanism 220 and the inner wall of the male tubular recessed area 140 to allow the ratchet mechanism 220 to move in a vertical direction as the female tubular member 110 and the male tubular member 120 are coupled. In the illustrated embodiment, the ratchet mechanism 220 comprises the ratchet teeth 230 and the spring 240. In the illustrated embodiment, the ratchet teeth 230 face downwardly toward the toothed insert 210, while the spring 240 is positioned to engage with the upper wall of the male tubular recess member 140. The ratchet mechanism 220 may be made of any suitable material (e.g., metal, metal alloy, plastic, composite material, etc.). Similar to the toothed insert 210, the ratchet mechanism 220 may be scalable based on the size and application of the tubular elements 110 and 120.

[0033] A proximal end of the ratchet mechanism 220 may be mechanically coupled to the male tubular recessed area 140 using threaded ratchet screw 260. In some embodiments, the toothed insert 210 is installed tangent to the side of the female tubular member 110 within of the female tubular recessed area 150. The threaded ratchet screw 260 may act as a pivot point for the ratchet mechanism 220, thereby allowing the ratchet mechanism 220 to rotate a sufficient distance to allow the ratchet teeth 230 to engage. move in and out of the insertion teeth 235 when the tubular elements 110 and 120 are being coupled. Accordingly, in some embodiments, the space between the wall of the male tubular recessed area 140 and the ratchet mechanism 220 may be determined by the length of the ratchet teeth 230 and the insertion teeth 235.

[0034] To facilitate the pivoting ratchet effect, in some embodiments, the ratchet mechanism 220 may have fewer ratchet teeth 230 than the insertion teeth 235 of the toothed insert 210. This may allow the ratchet mechanism 220 to rotate in around the threaded ratchet screw 260 and move in a vertical direction as the ratchet mechanism 220 moves over the toothed insert 210.

[0035] Spring 240 represents any suitable device operable to exert a force on the ratchet mechanism 220 for the purpose of directing the ratchet teeth 230 into the insertion teeth 235. In the illustrated embodiment, the spring 240 is mechanically coupled to a distal end of the ratchet mechanism 220. Although the spring 240 is illustrated as being coupled to the ratchet mechanism 220, in some embodiments, the spring 240 is coupled to the wall of the male tubular recessed area 140. The spring 240 may be any appropriate spring, which includes but is not limited to a compression spring and a torsion spring.

[0036] The free length (i.e., the uncompressed length) of the spring 240 may depend on a number of factors, including the size of the male tubular recessed area 140 and the ratchet mechanism 220. Additionally, the spring constant or The spring rate of the spring 240 may depend on factors such as the force required to keep the ratchet teeth 230 coupled with the insertion teeth 235 and overcome the decoupling forces created by the female tubular element 110 and the male tubular element 120.

[0037] In some embodiments, the vertical ratchet anti-rotation device may include a locking screw 270 coupled to the distal end of the ratchet mechanism 220. The locking screw 270 may comprise any suitable device operable to engage the ratchet mechanism 220 in a downwardly seated position with the toothed insert 210. In some embodiments, the locking screw 270 may be a socket button head screw. The locking screw 270 may be installed in the male tubular recessed area 140. In some embodiments, the locking screw 270 may be installed in a recessed area of the locking screw 275 separate from the male tubular recess member 140. In the illustrated embodiment, the locking screw 270 is within spring 240. In some embodiments, locking screw 270 may be located in other locations, external to spring 240.

[0038] As illustrated in Figure 2A, spring 240 will compress against the upper wall of the male tubular recess area 140 as the tubular elements 110 and 120 are brought to their composition torque. While the tubular members 110 and 120 are coupled, the ratchet teeth 230 of the ratchet mechanism 220 will slide over the insertion teeth 235 of the toothed insert 210, causing the spring 240 to compress against the wall of the male tubular recess area 140 By capturing the leading edge of the ratchet teeth 230 the vertical, pivoting ratchet anti-rotation device 205 can provide little resistance as the tubular elements 110 and 120 are brought to their compounding torque.

[0039] FIGURE 2B illustrates the vertical, pivoting ratchet anti-rotation device 205 in an engaged position. As shown in the illustrated embodiment, once the ratchet teeth 230 slide over the insertion teeth 235, the spring 240 will expand to force the ratchet teeth 230 into the recesses of the insertion teeth 235. In the engaged position, the teeth ratchet 230 and insertion teeth 235 make contact to prevent the female tubular element 110 from decoupling from the male tubular element 120 while still allowing the tubular elements 110 and 120 to further rotate to a compounding torque.

[0040] In some embodiments, once the female tubular element 110 and the male tubular element 120 reach their compounding torque and the ratchet mechanism 220 engages with the toothed insert 210, the locking screw 270 can be installed in the male tubular recessed area 140. Locking screw 270 may retain ratchet mechanism 220 in the downward engaged position with toothed insert 210. In some embodiments, locking screw 270 acts to relieve tension on spring 240. Although FIGURE 2B show a single locking screw 270, any suitable number of locking screws may be used in the pivoting, vertical ratchet anti-rotation device 205.

[0041] In some embodiments, it may be necessary for the female tubular element 110 and the male tubular element 120 to be decoupled after they have been brought to their composition torque. To decouple the female tubular member 110 and the male tubular member 120, the threaded ratchet bolt 260 and the locking bolt 270 may be removed. Once the threaded ratchet screw 260 and the locking screw 270 are removed, the ratchet mechanism 220 can be removed from the male tubular recessed area 140 and the tubular elements 110 and 120 can be decoupled. In this way, removal/disengagement of the vertical, pivoting ratchet anti-rotation device 205 can occur with minimal damage to the tubular elements 110 and 120.

[0042] Modifications, additions or omissions may be made to the vertical, pivoting ratchet anti-rotation device without departing from the scope of the disclosure. In some embodiments, the toothed insert 210 and the ratchet mechanism 220 may be preinstalled in the female tubular member 110 and the male tubular member 120, respectively. Although the vertical, pivoting ratchet device is illustrated as using spring 240 to engage ratchet teeth 230 with insertion teeth 235, other mechanisms may be used to enable the ratchet mechanism. In other embodiments, the pin and housing sections of the connector assembly 100 may be reversed such that the housing acts as the male tubular member 120 and the pin acts as the female tubular member 110. Furthermore, although the insertion toothed insert 210 and the ratchet mechanism 220 are illustrated as being mounted within the recessed areas 140 and 150, in some embodiments, the toothed insert 210 and the ratcheting mechanism 220 may be mounted on the exterior of the female tubular member 110 and the male tubular member 120. Additionally, in some embodiments, the ratchet teeth 230 and the insertion teeth 235 may both have angled teeth with angled leading and trailing edges.

[0043] FIGURE 3A illustrates a vertical ratchet anti-rotation device with multiple springs 305 in an open position. The multi-spring vertical ratchet anti-rotation device 305 may comprise a lower ratchet device 310 within the female tubular recessed area 150 and an upper ratchet device 320 within the male tubular recessed area 140 (the lower ratchet device 310 and the upper ratchet 320 may be referred to together as "ratchet devices 310 and 320"). In contrast to the ratchet mechanism 220, which rotates around the threaded ratchet screw 260 at a proximal end, the entire length of the ratchet devices 310 and 320 can extend and compress vertically.

[0044] In the illustrated embodiment, the lower ratchet device 310 is mechanically coupled to the female tubular recessed area 150 using a plurality of lower springs 340b. In some embodiments, the lower ratchet device 310 is installed tangent to the side of the female tubular member 110. In this way, the lower ratchet device 310 may be replaceable in the event that the lower ratchet device 310 is damaged.

[0045] The lower ratchet device 310 may be comprised of a plurality of lower teeth 335 facing upward toward the upper ratchet device 320. The lower ratchet device 310 may have any suitable number of lower teeth 335. In the illustrated embodiment , the plurality of lower teeth 335 runs the entire length of the lower ratchet device 310. The lower ratchet device 310 may also utilize any suitable pattern for the plurality of lower teeth 335 to distribute the force created when the female tubular member 110 and the male tubular element 120 tends to disengage.

[0046] In the illustrated embodiment, the upper ratchet device 320 is mechanically coupled to the male tubular recessed area 140 using a plurality of upper springs 340a. In some embodiments, the upper ratchet device 320 is installed tangent to the side of the male tubular member 120 within the male tubular recessed area 140. In this manner, the upper ratchet device 320 may be replaceable in the case where the upper ratchet device 320 be damaged.

[0047] The upper ratchet device 320 may comprise a plurality of upper teeth 330 facing downward toward the lower ratchet device 310. The upper ratchet device 320 may have any suitable number of upper teeth 330. In the illustrated embodiment, the The plurality of upper teeth 330 runs the entire length of the upper ratchet device 320. The upper ratchet device 320 may also utilize any suitable pattern for the plurality of upper teeth 330 for the purpose of distributing the force created when the female tubular member 110 and the male tubular member 120 tend to disengage. In some embodiments, the upper teeth 330 and the lower teeth 335 may have corresponding tooth patterns.

[0048] Ratchet devices 310 and 320 may be made of any suitable material (e.g., metal, metal alloy, plastic, composite material, etc.). Furthermore, the ratchet devices 310 and 320 may be scalable based on the size and application of the tubular elements 110 and 120. For example, the larger diameter tubular elements 110 and 120 may require larger ratchet devices 310 and 320, while the smaller diameter tubular elements 110 and 120 may allow for smaller size ratchet devices 310 and 320.

[0049] The upper springs 340a and the lower springs 340b (together "springs 340") represent any suitable device operable to exert force on the lower ratchet device 310 and the upper ratchet device 320 for the purpose of driving the upper teeth 330 and the lower teeth 335 one inside the other. In the illustrated embodiment, the upper springs 340a are mechanically coupled to the upper ratchet device 320. Similarly, the lower springs 340b are mechanically coupled to the lower ratchet device 310. Although the illustrated embodiment shows three upper springs 340a and three lower springs 340b , any suitable number of springs may be used in the multi-spring vertical ratchet anti-rotation device 305. Furthermore, although the springs 340 are illustrated as being coupled to the lower ratchet device 310 and the upper ratchet device 320, in some embodiments, springs 340 are coupled to the male tubular recessed area wall 140. Springs 340 may be any suitable spring device, which includes but is not limited to a compression spring and a torsion spring.

[0050] The free length (i.e., the uncompressed length) of the springs 340 may depend on a number of factors, including the size of the male tubular recessed area 140 and the ratchet devices 310 and 320. In addition, the constant of spring or the spring rate of the springs 340 may depend on factors such as the force required to keep the upper teeth 330 engaged with the lower teeth 335 with the aim of overcoming the decoupling forces created by the female tubular member 110 and the male tubular member 120 .

[0051] As illustrated in Figure 3A, springs 340 will compress as the multi-spring vertical ratchet anti-rotation device 305 moves to an open position when the upper teeth 330 slide over the lower teeth 335. As the tubular elements 110 and 120 are brought to their composition torque, the upper teeth 330 of the upper ratchet device 320 and the lower teeth 335 of the lower ratchet device 310 slide past each other. As the upper teeth 330 slide over the lower teeth 335, the upper springs 340a and the lower springs 340b may compress against the wall of the male tubular recessed area 140 and the female tubular recessed area 150, respectively. By capturing the leading edge of the upper teeth 330 and/or the lower teeth 335, the female tubular member 110 and the male tubular member 120 can be torqued to the desired level with minimal resistance created by the multi-spring vertical ratchet anti-rotation device. 305.

[0052] FIGURE 3B illustrates the multi-spring vertical ratchet anti-rotation device 305 in the engaged position. As shown in the illustrated embodiment, once the upper teeth 330 slide over the lower teeth 335, the springs 340 will expand to force the upper teeth 330 and the lower teeth 335 against each other. In the engaged position, the upper teeth 330 and the lower teeth 335 make contact to prevent the female tubular member 110 from decoupling from the male tubular member 120, while still allowing the tubular members 110 and 120 to further engage with a compounding torque.

[0053] In some embodiments, once the female tubular member 110 and the male tubular member 120 reach their compounding torque and the upper ratchet device 320 is engaged with the lower ratchet device 310, a plurality of locking screws upper 350a and lower locking screws 350b can be installed in the male tubular recessed area 140 and the female tubular recessed area 150, respectively. The upper locking screws 350a may retain the upper ratchet device 320 in the downward position, while the lower locking screws 350b may retain the lower ratchet device 310 in the upward position, thereby ensuring that the ratchet devices 310 and 320 remain in position. an engaged position. In some embodiments, upper locking screws 350a and lower locking screws 350b act to relieve tension in springs 340. Although FIGURE 2B shows two upper locking screws 350a and two lower locking screws 350b, any suitable number of screws locking device 350 can be used in the multi-spring vertical ratchet anti-rotation device 305.

[0054] In some embodiments, it may be necessary for the female tubular element 110 and the male tubular element 120 to be decoupled after they have been brought to their composition torque. To decouple the female tubular member 110 and the male tubular member 120 in this manner, removal/disengagement of the pivoting multi-spring vertical ratchet anti-rotation device 305 can occur with little damage to the tubular members 110 and 120.

[0055] Modifications, additions or omissions may be made to the multiple spring vertical ratchet anti-rotation device without departing from the scope of the disclosure. For example, in some embodiments, the multi-spring vertical ratchet anti-rotation device 305 may comprise an upper ratchet device 320 with toothed insert 210 instead of the lower ratchet device 310.

[0056] FIGURE 4A illustrates an angularly pivoting anti-rotation device 405 in the open position. The angularly pivoting anti-rotation device 405 may include a toothed insert 210 within the female tubular recessed area 150 and angular pivot mechanism 420 within the angled male tubular recessed area 440. The angular pivot mechanism 420 may engage, rotate, or translate in one direction. angular inside the recessed area angular male tubular 440.

[0057] Similar to the vertical ratchet anti-rotation device 205, in the illustrated embodiment, the toothed insert 210 can be mechanically coupled to the female tubular recessed area 150 of the female tubular member 110 using a threaded insertion screw 250. In this manner , the same toothed insert 210 may be used with different ratchet mechanisms and anti-rotation configurations, such as the ratchet mechanism 220, the upper ratchet device 320, and/or the angle pivot mechanism 420. While the illustrated embodiment shows the toothed insert 210 having the same shape and tooth profile as the toothed insert 210 of FIGURES 2A and 2B, in some embodiments, a different tooth design or profile may be used instead.

[0058] Angular pivot mechanism 420 represents any suitable mechanism capable of angularly pivoting, sliding, or engaging within the angled male tubular recessed area 440 for the purpose of mating with the toothed insert 210. The angled male tubular recessed area 440 may be sized to leave a space between the angled pivot mechanism 420 and the inner wall of the angled male tubular recessed area 440 for the purpose of allowing the angled ratchet mechanism 420 to move in an angular direction when the female tubular element 110 and the tubular element male 120 are coupled.

[0059] In the illustrated embodiment, the angled pivot mechanism 420 is composed of angled ratchet teeth 430 and an angled spring 445. The angled ratchet teeth 430 face downward toward the toothed insert 210, while the angled spring 445 is positioned to mate with the upper angled wall of the angled male tubular recessed area 440. The angled pivot mechanism 420 may be made of any suitable material (e.g., metal, metal alloy, plastic, composite material, etc.). Similar to the ratchet mechanism 220, the angle pivot mechanism 420 may be scalable based on the size and application of the tubular elements 110 and 120.

[0060] As also shown in the illustrated embodiment, the angular articulation mechanism may have a recessed cavity 420A. In some embodiments, a retaining screw 410 holds the angled pivot mechanism 420 within the angled male tubular recessed area 440 using the recessed cavity 420A. The retaining screw 410 may be installed in the countersunk cavity 420A to prevent radial movement of the angle pivot mechanism 420. In this way, the recessed cavity 420A and the retaining screw 410 may function to alleviate or prevent radial loading of the pivot mechanism. angle 420. Retaining screw 410 may be made of any suitable material and may be of any suitable size. In some embodiments, the retaining bolt 410 may be similar to the threaded ratchet bolt 260 in size, shape, and/or material.

[0061] To facilitate the hinged ratchet effect, in some embodiments, the angled pivot mechanism 420 may have fewer angled ratchet teeth 430 than the insertion teeth 235 of the toothed insert 210. This may allow the angled ratchet mechanism 420 moves in an angular direction as the angled ratchet mechanism 420 moves over the toothed insert 210.

[0062] The angle spring 445 represents any suitable device operable to exert force on the angle pivot mechanism 420 for the purpose of driving the angle ratchet teeth 430 into the insertion teeth 235. In the illustrated embodiment, the angle spring 445 is mechanically coupled to the angled pivot mechanism 420. Although the angled spring 445 is illustrated as being coupled to the angled pivot mechanism 420, in some embodiments, the angled spring 445 is coupled to the angled wall of the angled male tubular recessed area 440. The spring angle 445 may be any suitable spring device, which includes but is not limited to a compression spring and a torsion spring.

[0063] The free length (i.e., the uncompressed length) of the angle spring 445 may depend on a number of factors, including the size of the angle male tubular recessed area 440 and the angle pivot mechanism 420. Additionally, the constant The spring rate or spring rate of the angle spring 445 may depend on factors such as the force required to keep the angle ratchet teeth 430 coupled with the insertion teeth 235 and overcome the decoupling forces created by the female tubular member 110 and the tubular member male 120.

[0064] As illustrated in Figure 4A, the angled spring 445 will compress against the angled wall of the angled male tubular recess area 440 as the tubular elements 110 and 120 are brought to their compounding torque. While the tubular members 110 and 120 are coupled, the angled ratchet teeth 430 of the angled pivot mechanism 420 will slide over the insertion teeth 235 of the toothed insert 210 causing the angled spring 445 to compress against the wall of the recess area. angular male tubular 440. By capturing the leading edge of the angled ratchet teeth 430, the angularly pivoting anti-rotation device 405 can provide little resistance as the tubular elements 110 and 120 are brought to their compounding torque.

[0065] FIGURE 4B illustrates the angularly pivoting anti-rotation device 405, in an engaged position. As shown in the illustrated embodiment, once the angled ratchet teeth 430 slide over the insertion teeth 235, the angled spring 445 will expand to force the angled ratchet teeth 430 into the recesses of the insertion teeth 235. In engaged position, the angled ratchet teeth 430 and the insertion teeth 235 make contact to prevent the female tubular member 110 from disengaging from the male tubular member 120, while still allowing the tubular members 110 and 120 to rotate further for a compounding torque.

[0066] In some embodiments, it may be necessary for the female tubular element 110 and the male tubular element 120 to be decoupled after they have been brought to their composition torque. To decouple the female tubular member 110 and the male tubular member 120, the threaded ratchet screw 260 can be removed. Once the threaded ratchet screw 260 is removed, the angle pivot mechanism 420 can be removed from the angled male tubular recessed area 440 and the tubular elements 110 and 120 can be decoupled. In this way, removal/disengagement of the angularly pivoting anti-rotation device 405 can occur with minimal damage to the tubular elements 110 and 120.

[0067] Modifications, additions or omissions may be made to the angularly pivoting anti-rotation device 405, without departing from the scope of the disclosure. For example, although not illustrated, the angularly pivoting anti-rotation device 405 may include a locking screw similar to the locking screw 270 used to retain the ratchet mechanism 220 in the downwardly engaged position with the toothed insert 210.

[0068] Furthermore, in addition to or as an alternative to retaining screw 410, in some embodiments, a proximal end of the angled pivot mechanism 420 may be mechanically coupled to the angled male tubular recessed area 440 with the use of a threaded screw similar to the threaded ratchet screw 260. The threaded screw may act as a pivot or a sliding point for the angle pivot mechanism 420, thereby allowing the angle pivot mechanism 420 to rotate or slide to allow the angle ratchet teeth 430 to engage. move in and out of the insertion teeth 235 when the tubular elements 110 and 120 are being coupled. Accordingly, in some embodiments, the space between the angled wall of the angled male tubular recessed area 440 and the angled pivot mechanism 420 may be determined by the length of the angled ratchet teeth 430 and the insertion teeth 235. Furthermore, in some embodiments, the toothed insert 210 and the angular pivot mechanism 420 may be preinstalled in the female tubular element 110 and the male tubular element 120, respectively. Furthermore, in some embodiments, the angled ratchet teeth 430 and the insertion teeth 235 may have both angled teeth with inclined leading and trailing edges.

[0069] Although the angularly pivoting anti-rotation device 405 is illustrated as using an angular spring 445 to engage the angular ratchet teeth 430 with the insertion teeth 235 other mechanisms may be used to enable the pivoting mechanism. In other embodiments, the pin and housing sections of the connector assembly 100 may be reversed such that the housing acts as the male tubular member 120 and the pin acts as the female tubular member 110. Furthermore, although the insertion If the toothed insert 210 and the angled pivot mechanism 420 are illustrated as being mounted within the recessed areas 440 and 150, in some embodiments, the toothed insert 210 and the angled pivot mechanism 420 may be mounted on the exterior of the female tubular member 110 and the male tubular 120.

[0070] FIGURE 5 illustrates a method 500 for securely coupling tubular elements 110 and 120 with the use of a vertical ratchet anti-rotation device 130. In step 510, the female tubular element 110 and the male tubular element 120 are prepared for the components of the vertical ratchet anti-rotation device 130. Preparation of the tubular members 110 and 120 may include forming the male tubular recessed area 140 on the load shoulder of the male tubular member 120 and forming the female tubular recessed area 150 on the load shoulder of the load of the female tubular member 110. For example, in certain embodiments, the formation of the recessed areas 140 and 150 may be completed by milling the recessed areas 140 and 150.

[0071] In step 520, the vertical ratchet anti-rotation device 130 may be mounted to the tubular members 110 and 120. For example, to mount the vertical, pivoting ratchet anti-rotation device 205, the ratchet mechanism 220 may be disposed within the male tubular recessed area 140 and the toothed insert 210 may be disposed within the female tubular recessed area 150. In some embodiments, the ratchet mechanism 220 may be pivotally coupled at a proximal end to the male tubular member 120 with the use of a threaded ratchet screw 260, while the toothed insert 210 is mechanically coupled to the female tubular recessed area 150 using a threaded insert screw 250.

[0072] As another example, to mount the multi-spring vertical ratchet anti-rotation device 305, the upper ratchet device 320 may be disposed within the male tubular recessed area 140 and the lower ratchet device 310 may be disposed within the recessed area female tubular 150. In some embodiments, the upper ratchet device 320 is coupled to the male tubular recessed area 140 using upper springs 340a while the lower ratchet device 310 is coupled to the female tubular recessed area 150 using lower springs. 340b.

[0073] As another example, to mount angularly pivoting anti-rotation device 405, the angular pivot mechanism 420 may be disposed within the angled male tubular recessed area 440 and the toothed insert 210 may be disposed within the female tubular recessed area 150. In some embodiments, the angular pivot mechanism 420 may be pivotally coupled at a proximal end to the male tubular member 120 with the use of a threaded ratchet screw 260, while the toothed insert 210 is mechanically coupled to the female tubular recessed area 150 with the use of a 250 threaded insertion screw.

[0074] In step 530, the female tubular element 110 and the male tubular element 120 can be coupled to a desired compounding torque. The desired compounding torque of the tubular elements 110 and 120 may depend on a number of factors including the application of the tubular elements 110 and 120, the material used to create the tubular elements 110 and 120, and the design of the tubular elements 110 and 120.

[0075] As the tubular elements 110 and 120 are being coupled to the desired compounding torque, the vertical ratchet anti-rotation device may automatically engage to prevent the female tubular element 110 and the male tubular element 120 from disengaging.

[0076] For example, spring 240 may compress as the vertical, pivoting ratchet anti-rotation device 205 moves to an open position when the ratchet teeth 230 slide over the insertion teeth 235. As the elements tubulars 110 and 120 are brought to their compounding torque, the ratchet teeth 230 of the ratchet mechanism 220 will slide over the insertion teeth 235 of the toothed insert 210. As the ratchet teeth 230 slide over the insertion teeth 235 , the spring 240 may compress against the wall of the male tubular recess area 140. Once the ratchet teeth 230 slide over the insertion teeth 235, the spring 240 will expand and force the ratchet teeth 230 into the recesses of the insertion teeth 235. In the engaged position, the ratchet teeth 230 and the insertion teeth 235 make contact to prevent the female tubular member 110 from disengaging from the male tubular member 120 while still allowing the tubular members 110 and 120 are further coupled with a compounding torque. Accordingly, the vertical, pivoting ratchet anti-rotation device 205 can automatically resist the decoupling of the tubular elements 110 and 120.

[0077] As another example, the upper springs 304a and the lower springs 340b will compress as the multi-spring vertical ratchet anti-rotation device 305 moves to an open position when the upper teeth 330 slide over the lower teeth 335. As the tubular elements 110 and 120 are brought to their compounding torque, the upper teeth 330 of the upper ratchet device 320 and the lower teeth 335 of the lower ratchet device 310 will slide past each other. As the upper teeth 330 slide over the lower teeth 335, the upper springs 340a and the lower springs 340b may compress against the wall of the male tubular recess area 140 and the female tubular recess area 150, respectively. Once the upper teeth 330 slide over the lower teeth 335, the springs 340 will expand and direct the upper teeth 330 and the lower teeth 335 against each other. In the engaged position, the upper teeth 330 and the lower teeth 335 make contact to prevent the female tubular member 110 from decoupling from the male tubular member 120, while still allowing the tubular members 110 and 120 to further engage with each other. a compounding torque. Accordingly, the multi-spring vertical ratchet anti-rotation device 305 can automatically resist the decoupling of the tubular elements 110 and 120.

[0078] As another example, the angle spring 445 may compress as the angularly pivoting anti-rotation device 405 moves to an open position when the angled ratchet teeth 430 slide over the insertion teeth 235. As the tubular elements 110 and 120 are brought to their compounding torque, the angled ratchet teeth 430 of the angled pivot mechanism 420 slide over the insertion teeth 235 of the toothed insert 210. As the angled ratchet teeth 430 slide over the teeth of insertion 235, the angle spring 445 may compress against the angled wall of the angled male tubular recess area 440. Once the angled ratchet teeth 430 slide over the insertion teeth 235, the angle spring 445 will expand and force the teeth of angled ratchet teeth 430 into the recesses of the insertion teeth 235. In the engaged position, the angled ratchet teeth 430 and the insertion teeth 235 contact to prevent the female tubular member 110 from disengaging from the male tubular member 120 at the same while still allowing the tubular elements 110 and 120 to further couple to a compounding torque. Accordingly, the angularly pivoting anti-rotation device 405 can automatically resist decoupling of the tubular elements 110 and 120.

[0079] Various embodiments can perform some, all or none of the steps described above. For example, in certain embodiments, the tubular elements may be prepared off-site so that the tubular elements do not need to be prepared on-site. Additionally, one or more steps may be repeated.

[0080] The scope of this disclosure encompasses all changes, substitutions, variations, alterations and modifications to the example embodiments described or illustrated herein that a person having ordinary skill in the art would understand. The scope of this disclosure is not limited to the example embodiments described or illustrated herein. Furthermore, although this disclosure describes and illustrates respective embodiments herein as including particular components, elements, functions, operations, or steps, any such embodiment may include any combination or permutation of any of the components, elements, functions, operations, or steps described. or illustrated anywhere in this document that a person of ordinary skill in the art would understand.

[0081] Furthermore, reference in the appended claims to an apparatus or system or to a component of an apparatus or system that is adapted to, arranged for, capable of, configured for, enabled for, operative for, or operable to perform a particular function encompasses whether or not that device, system, component is the same or that particular function activated, turned on or unlocked, as long as that device, system or component is adapted, organized, capable, configured, enabled, operable or operational.

[0082] Illustrative embodiments of the present description are described in detail in this document. For reasons of clarity, not all features of an actual implementation are described in this specification. Of course, it will be appreciated that in the development of any real modality, numerous implementation-specific decisions must be made to achieve the specific objectives of the developers, such as compliance with system-related and business-related constraints, which vary from one implementation to another. . Furthermore, it will be appreciated that such a development effort may be complex and time-consuming, but would nevertheless be a routine task for those of ordinary skill in the art with the benefit of the present disclosure. Furthermore, in no way should the following examples be read to limit or define the scope of the disclosure. Embodiments of the present disclosure are best understood by referring to FIGURES 1 to 4, in which like numbers are used to indicate corresponding and similar parts.

Claims (20)

1. System comprising: a first tubular element (120) having a first recessed area (140), the first recessed area (140) located on a first projection of the first tubular element (120); a second tubular member (110) having a second recessed area (150), the second recessed area (150) located on a second projection of the second tubular member (110); characterized by the fact that the system further comprises: a ratchet mechanism (220) pivotally coupled to the first tubular element (120) within the first recessed area (140) at a proximal end of the ratchet mechanism (220), wherein a distal end of the ratchet mechanism (220) comprises a first plurality of angled teeth (230) and a spring (240) that allows the ratchet mechanism (220) to pivot in a vertical direction within the first recessed area (140); a toothed insert (210) mechanically coupled to the second tubular member (110) within the second recessed area (150), wherein the toothed insert (210) comprises a second plurality of angled teeth (235) positioned to engage with the first plurality of angled teeth (230) of the ratchet mechanism (220); wherein during coupling of the first and second tubular elements (110, 120), the spring (240) is compressible to allow the ratchet mechanism (220) to move vertically over the second plurality of angled teeth (235) of the toothed insert (210); and wherein the spring (240) is expandable to engage the first plurality of angled teeth (230) of the ratchet mechanism (220) with the second plurality of angled teeth (235) of the toothed insert (210), and wherein the decoupling of the first and second tubular elements (110, 120) is prevented by engagement of the first plurality of angled teeth (230) of the ratchet mechanism (220) with the second plurality of angled teeth (235) of the toothed insert (210). 2. System according to claim 1, characterized by the fact that it further comprises a locking screw (270) mechanically coupled to the distal end of the ratchet mechanism (220), wherein when the first and second tubular elements (110, 120 ) are coupled, the locking screw (270) is installable by maintaining the first plurality of angled teeth (230) of the ratchet mechanism (220) with the second plurality of angled teeth (235) of the toothed insert (210). 3. System according to claim 1, characterized by the fact that the ratchet mechanism (220) is pivotally coupled to the first tubular element (120) using a threaded screw (260) so that the ratchet mechanism (260) ratchet (220) is removable after removing the threaded screw (260). 4. System according to claim 1, characterized by the fact that it further comprises a threaded hole within the first recessed area (140), wherein the threaded hole is configured to receive a threaded screw (260) with the aim of preventing the first plurality of angled teeth (230) of the ratchet mechanism (220) disengage vertically from the second plurality of angled teeth (235) of the toothed insert (210). 5. System according to claim 1, characterized by the fact that the ratchet mechanism (220) is pivotally coupled to the first tubular element (120) using a threaded screw (260) so that, when the first plurality of angled teeth (230) of the ratchet mechanism (220) are engaged with the second plurality of angled teeth (235) of the toothed insert (210), the ratchet mechanism (220) is removable upon removal of the threaded screw ( 260). 6. System according to claim 1, characterized by the fact that the first tubular element (120) is a male pin connector and the second tubular element (110) is a female housing connector. 7. System according to claim 1, characterized by the fact that the first and second plurality of angled teeth (230, 235) comprise an angled leading edge and a flat trailing edge. 8. Method for securely coupling tubular elements (110, 120), the method comprising: preparing (510) a first tubular element (120) and a second tubular element (110) to receive a vertical, pivoting ratchet anti-rotation device ( 130), wherein preparing the first tubular element (120) and the second tubular element (110) comprises: forming a first recessed area (140) within a projection of the first tubular element (120); and forming a second recessed area (150) within a projection of the second tubular member (110); assembling (520) the vertical, pivoting ratchet anti-rotation device (130), characterized in that assembling the vertical, pivoting ratchet anti-rotation device (130) comprises: arranging a ratchet mechanism (220) on the first tubular element ( 120) within the first recessed area (140), wherein the ratchet mechanism (220) is pivotally coupled at a proximal end to the first tubular member (120), a distal end of the ratchet mechanism (220) being comprised of a first plurality of angled teeth (230) and a spring (240) that allows the ratchet mechanism (220) to rotate in a vertical direction within the first recessed area (140); arranging a toothed insert (210) in the second tubular element (110) within the second recessed area (150), wherein the toothed insert (210) is composed of a second plurality of angled teeth (235) positioned to engage with the first plurality of angled teeth (230) of the ratchet mechanism (220); and coupling (530) the first tubular element (120) and the second tubular element (110), wherein during coupling of the first and second tubular elements (110, 120), the spring (240) is compressible to allow the mechanism of ratchet (220) moves vertically over the second plurality of angled teeth (235) of the toothed insert (210). 9. Method according to claim 8, characterized by the fact that it further comprises: installing a locking screw (270) at the distal end of the ratchet mechanism (220) when the first and second tubular elements (110, 120) are coupled , wherein the locking screw (270) retains the first plurality of angled teeth (230) of the ratchet mechanism (220) with the second plurality of angled teeth (235) of the toothed insert (210). 10. Method according to claim 8, characterized by the fact that the ratchet mechanism (220) is pivotally coupled to the first tubular element (120) using a threaded screw (260) in such a way that the mechanism ratchet (220) is removable after removing the threaded screw (260). 11. Method according to claim 8, characterized by the fact that it further comprises: inserting a threaded screw (260) into the first recessed area (140) of the first tubular element (120), the threaded screw (260) configured to prevent the first plurality of angled teeth (230) of the ratchet mechanism (220) disengage vertically from the second plurality of angled teeth (235) of the toothed insert (210). 12. Method according to claim 8, characterized by the fact that the ratchet mechanism (220) is pivotally coupled to the first tubular element (120) using a threaded screw (260) so that, when the first plurality of angled teeth (230) of the ratchet mechanism (220) are engaged with the second plurality of angled teeth (235) of the toothed insert (210), the ratchet mechanism (220) is removable upon removal of the threaded screw ( 260). 13. Method according to claim 8, characterized in that the first tubular element (120) is a male pin connector and the second tubular element (110) is a female box connector. 14. The method of claim 8, wherein the first and second pluralities of angled teeth (230, 235) comprise an angled leading edge and a flat trailing edge. 15. Method according to claim 8, characterized in that the decoupling of the first and second tubular elements (110, 120) is prevented by the spring (240) being expandable to engage the first plurality of angled teeth (230) of the mechanism of ratchet (220) with the second plurality of angled teeth (235) of the toothed insert (210). 16. Vertical, pivoting ratchet anti-rotation device (130), characterized in that it comprises: a ratchet mechanism (220) pivotally coupled to a proximal end of a first tubular element (120) within a first recessed area ( 140) located on a first projection of the first tubular member (120), a distal end of the ratchet mechanism (220) being comprised of a first plurality of angled teeth (230) and a spring (240) that allows the ratchet mechanism to (220) can rotate in a vertical direction within the first recessed area (140); a toothed insert (210) mechanically coupled to a second tubular element (110) in a second recessed area (150) located on a second projection of the second tubular element (110), the toothed insert (210) being composed of a second plurality of angled teeth (235) positioned to engage with the first plurality of angled teeth (230) of the ratchet mechanism (220); wherein during coupling of the first and second tubular elements (110, 120), the spring (240) is compressible to allow the ratchet mechanism (220) to move vertically over the second plurality of angled teeth (235) of the toothed insert (210); and wherein the spring (240) is expandable to engage the first plurality of angled teeth (230) of the ratchet mechanism (220) with the second plurality of angled teeth (235) of the toothed insert (210), wherein the decoupling of the first and second tubular elements (110, 120) is prevented by engagement of the first plurality of angled teeth (230) of the ratchet mechanism (220) with the second plurality of angled teeth (235) of the toothed insert (210). 17. Anti-rotation device (130) according to claim 16, characterized by the fact that it further comprises a locking screw (270) mechanically coupled to the distal end of the ratchet mechanism (220), wherein when the first and second tubular elements (110, 120) are coupled, the locking screw (270) is installable by retaining the first plurality of angled teeth (230) of the ratchet mechanism (220) with the second plurality of angled teeth (235) of the toothed insert (210). ). 18. Anti-rotation device (130) according to claim 16, characterized by the fact that the ratchet mechanism (220) is pivotally coupled to the first threaded tubular element (120) using a threaded screw (260) of so that when the first plurality of angled teeth (230) of the ratchet mechanism (220) are engaged with the second plurality of angled teeth (235) of the toothed insert (210), the ratchet mechanism (220) is removable after removing the threaded screw (260). 19. Anti-rotation device (130) according to claim 16, characterized by the fact that it further comprises a threaded hole within the first recessed area (140), wherein the threaded hole is configured to receive a threaded screw (260) with the The objective is to prevent the first plurality of angled teeth (230) of the ratchet mechanism (220) from disengaging vertically from the second plurality of angled teeth (235) of the toothed insert (210). 20. Anti-rotation device (130) according to claim 16, characterized in that the first and second pluralities of angled teeth (230, 235) comprise an angled leading edge and a flat trailing edge.