RU221735U1 - Hydraulic Key Safety Door Locking Device - Google Patents

Abstract

The utility model relates to the oil and gas industry, namely to the technical equipment of hydraulic tongs used for screwing and unscrewing tubing pipes. The hydraulic tong safety door locking device contains a safety door and a lever mounted on the hydraulic tong body. One arm of the lever contacts the cam of the safety door when it is closed, and the second end of the lever is connected to the rotating element mounted on the housing. The rotary element is equipped with a groove, made with the possibility of placement and movement in it when the safety door is closed, the lower part of the control lever associated with the hydraulic distributor of the key, and with the possibility of blocking the rotation of the rotary element when the lower part of the control lever moves in the groove. When the safety door is open, the groove of the rotating element is offset from the bottom of the control lever to block the movement of the control lever. The technical result consists in increasing reliability through the use of a simple system of levers and a locking mechanism by reliably locking both the control lever when the safety door is open, and the locking of the safety door when the control lever is in the operating position. 9 salary f-ly, 12 ill.

Description

The utility model relates to the oil and gas industry, namely to the technical equipment of hydraulic tongs used for screwing and unscrewing tubing pipes.

The hydraulic wrench Oil Country 45000-100, manufactured by Oil Country Manufacturing, is known from the prior art. Inc (HYDRAULIC TUBING TONG 45000-100 OPERATION AND SERVICE MANUAL, 2010 https://pdfslide.net/documents/oil-country-45000.html?page=1), containing a housing equipped with a window for entering pipes with a a rotary clamping device, a control device, a hydraulic motor mounted on the housing, connected through a system of levers to the control device, wherein the rotating clamping device is a reversible rotor connected by a gear reducer to the axis of the hydraulic motors, with jaws fixed on the inner surface, equipped with dies. The window for the pipe to pass through the body during operation of the key is blocked by a shutter. The locking of the damper (safety door) in the hydraulic key is ensured by a slider associated with the damper, blocking the path of movement of the control (control lever).

The disadvantage of the design is the possibility of turning on the hydraulic key when the damper is not completely closed due to the presence of a large idle speed of the slider, as well as the appearance of backlashes due to wear of the contact surfaces of the parts: the slider, the tail part (bottom plate) of the control lever and others.

A three-speed hydraulic tong is also known from the prior art (RU 38020, IPC E21B19/16, B25B13/00, published May 20, 2004), containing a housing equipped with a window for entering pipes with a rotary clamping device located in it, a control device, and a hydraulic motor mounted on the housing , connected through a system of levers with a control device and a means of protection from emergency situations, an additional hydraulic motor sitting on the same shaft with the first hydraulic motor, while the rotating clamping device is a reversible rotor connected by a gear reducer to the axis of the hydraulic motors, with a large and small one fixed on the inner surface jaws equipped with dies, the means of protection against emergency situations includes a hydraulic system protection unit and a control unit protection unit. The window for the pipe to pass through the body during operation of the key is blocked by a shutter. The damper is equipped with a locking device containing a locking lever, which fits into a groove on the tail part of the control lever when the damper is open and thereby locks it.

The disadvantage of the design is the possibility of opening the damper when the key is running, that is, the design of the key does not provide a mechanism for locking the damper specifically. In addition, during long-term operation of the key, the efficiency of the locking device is significantly reduced as a result of the appearance of backlashes associated with wear of the contact surfaces of parts: the locking lever, the tail part of the control lever and others.

The movement of the locking lever when the damper is open is ensured and supported by spring force. However, during operation, the spring may be subject to contamination, icing, and mechanical damage, as a result of which the spring force may not be enough to move the lever, which leads to a decrease in the reliability of the unit and its safety.

There is a known latch mechanism for hydraulic keys (RU112933, IPC E21B 19/16, published on January 27, 2012), which includes a damper mounted on the body, a lever, and the lever is made of two arms and mounted on the key body, with one arm in contact with the damper through a cam connected to the valve, and the other arm of the lever has the ability to interact with the hydraulic motor thrust unit, while an elastic element is installed on the lever.

This solution was adopted as the closest analogue (prototype).

The disadvantage of the design is the possibility of damage, even destruction, of the latch mechanism either with a pipe or with tools such as a hammer or sledgehammer when carrying out hoisting operations due to elements of the latch mechanism protruding above the surface of the key.

Known solutions provide a locking system for only the right control lever; however, if there are two hydraulic motors in the hydraulic tong, it is necessary to lock the left control lever when the safety door is open.

The disadvantage of the known solutions is the unreliability of the safety door locking device and, as a consequence, the possibility of driving the rotor when the safety door is open.

The objective of this utility model is to expand the arsenal of hydraulic tong safety door locking devices with increased reliability.

The technical result is the creation of a hydraulic key safety door locking device, characterized by high reliability due to the use of a simple system of levers and a locking mechanism, as well as protection of the locking device from mechanical damage during operation of the hydraulic key.

The solution to the stated technical problem in a device for locking the safety door of a hydraulic key, containing a safety door, a lever, mounted on the body of the hydraulic key,

is achieved by

one arm of the lever is in contact with the cam of the safety door when it is closed, and the second end of the lever is connected to a rotating element mounted on the housing, while the rotating element is equipped with a groove made with the possibility of placement and movement in it when the safety door is closed, the lower part of the control lever, connected with a hydraulic key distributor, and with the ability to block the rotation of the rotary element when the lower part of the control lever moves in the groove, while when the safety door is open, the groove of the rotary element is offset relative to the lower part of the control lever, ensuring that the movement of the control lever is blocked.

In addition, in particular cases of implementation of this utility model, the achievement of the stated technical result is ensured by the following.

The rotating element is mounted on the housing axis with the possibility of rotation relative to the axis.

The groove in the rotary element is made in a protrusion formed on the upper surface of the rotary element.

The protrusion of the rotating element has the shape of a hollow cylinder.

At the base of the lower part of the control lever there is a protrusion that fits with a gap into the central hole of the cylindrical protrusion of the rotary element.

The side projections of the lower part of the control lever prevent rotation of the rotary element when the control lever is in the operating position.

The rotating element is protected from mechanical damage by a protective structure.

The protective structure is detachably attached to the body.

The protective structure consists of a base, side brackets and a protective guard surrounding the control lever handle.

When the safety door is open, the swing arm is secured against displacement by an elastic element.

The proposed design allows for reliable locking of both the control lever (left control lever) when the safety door is open, and the locking of the safety door when the control lever is in the operating position.

A safety door in contact with a lever, which in turn is connected to a rotating element having a groove to accommodate the lower part of the control lever, forms a simple system of levers, which increases the reliability of the locking device in various weather conditions.

The locking mechanism is formed by a lever and a rotating element with a groove associated with it. The angle of placement of the groove of the rotary element coincides with the path of movement (rotation or movement) of the lower part of the control lever and does not interfere with control - when the safety door is closed, or the groove of the rotary element does not coincide with the path of movement (rotation) of the control lever (the groove is rotated relative to the bottom of the control lever at a certain angle) and interferes with control, i.e. The control lever blocks rotation when the safety door is open.

The use of a locking mechanism and the proposed lever system allows the safety door and control lever to be locked mechanically in both directions, which reduces the likelihood of jamming and, accordingly, increases the reliability of the design.

When the safety door is open, the control lever is securely locked, preventing involuntary rotation of the rotor, for example, when changing jaws or a brake band.

When the hydraulic tong is operating, the control lever blocks the possibility of inadvertent opening of the safety door by blocking the displacement of the rotary element with the lower part of the control lever while the tong is operating.

When the safety door is opened, the lever is secured from displacement in a certain position using an elastic element, for example, a pawl with a spring. Fixing the lever is necessary, since the safety door locking device does not have a permanent mechanical connection with the door, and therefore, if a break occurs in the chain of mechanical contacts, it is necessary to rigidly fix the lever from arbitrary rotation, and, consequently, the entire mechanism in a certain position, so that when closing the safety door restore contact between the door and the swing arm strictly in the same position of the lever.

The presence of a protective structure allows you to protect the junction of the rotary element with the lower part of the control lever from mechanical damage, for example, a pipe or a tool, which increases the reliability of the inventive device.

This useful model is explained below by a specific example of its implementation, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the stated technical result.

The essence of the proposed hydraulic key safety door locking device is presented in the drawings:

fig. 1 – hydraulic key safety door locking device (general top view);

fig. 2 – placement of the safety door locking device on the hydraulic key;

fig. 3 – rotary element (general view);

fig. 4 – lever (general view);

fig. 5 – control lever (general view);

fig. 6 – position of the lower part of the control lever in the rotary element with the safety door closed (neutral position of the control lever) – side view;

fig. 7 – position of the lower part of the control lever in the rotary element with the safety door closed (neutral position of the control lever) – top view;

fig. 8 – position of the lower part of the control lever in the rotary element with the safety door closed (position when the control lever is turned, the safety door is locked) – side view;

fig. 9 – position of the lower part of the control lever in the rotary element with the safety door closed (position when the control lever is turned, the safety door is locked) – top view;

fig. 10 - position of the lower part of the control lever in the rotary element with the safety door open (the control lever is locked vertically) - side view;

fig. 11 - position of the lower part of the control lever in the rotary element with the safety door open (the control lever is locked vertically) - top view;

fig. 12 – protective structure (general view).

To ensure the safety of the operating personnel, a safety door 2 is provided in the body 1 of the hydraulic tong. When the hydraulic tong is operating, that is, when the rotor with jaws and rams rotates during make-up or screwing of tubing pipes, the safety door 2 is installed through the axis of rotation 3 on 1 key housing must be in the closed position.

The closing and opening of the safety door 2, which blocks the entrance to the hole 4 of the housing 1 for entering the pump and compressor pipes, is directly related to the rotation locking elements of the control lever 5 of the hydraulic tong.

When replacing jaws and carrying out other work on servicing the hydraulic tong with the safety door 2 open, the control lever 5 must be blocked from accidental movement (rotation) and, as a consequence, from accidental activation of rotation of the working mechanism of the tong.

The safety door locking device contains a rotary type lock, including a rotary element 6, which in a particular embodiment is a rounded element. The rotating element 6 is equipped with a hole 7, through which it is mounted on the axis of rotation of the housing 1 with the possibility of rotation.

On the upper side of the rotating element 6 there is a protrusion 8 with a groove 9 of constant depth. According to one embodiment, the rotary element 6 contains a hollow cylindrical protrusion 8 placed around the hole 7, in which the axis of rotation of the housing 1 is installed. The hollow cylindrical protrusion 8 has a groove 9 in the form of a groove passing through the opposite walls of the cylindrical protrusion 8. Groove 9 in one of the embodiments it may not have a constant depth.

The rotary element 6 is mechanically connected to the lever 10. In a particular embodiment, for the movable connection of the rotary element 6 and the lever 10, a through groove 11 is made on the lever 10, in which a protrusion (or axis) 12 is installed with the ability to perform reciprocating movement, rigidly attached to rotary element 6.

Lever 10 is installed on the body 1 with the ability to rotate at a certain angle when closing and opening the safety door 2.

The safety door 2 on the side facing the key body 1 is equipped with a wedge-shaped cam 13 that interacts with the lever 10 when closing the safety door 2.

The safety door 2 is equipped with a protrusion (stop) 14, made, for example, in the form of a handle (handle) for opening and closing the door 2. The protrusion 14 interacts with the lever 10 when opening the door 2.

When the safety door 2 is opened, the lever 10, pushed by the protrusion 14 of the door 2, is rotated and secured against displacement in a certain position using an elastic element 15, for example, a pawl with a spring, located on the key body 1.

When closing the safety door 2 with the wedge-shaped cam 13, the lever 10 is unlocked, and then the lever 10 is rotated until the safety door 2 is finally closed. When the safety door 2 is opened, the lever 10 is rotated until the door 2 opens, and then fixed by the elastic element 15 (pawl with a spring) from further rotation.

When the safety door 2 is closed, one arm of the lever 10 is placed on the key body 1, and the second is on the safety door 2 in contact with the wedge-shaped cam 13.

The rotating element 6 is protected from mechanical damage by a protective structure 16, removably secured to the body 1 by means of bolts. The protective structure 16 in a particular embodiment consists of a base 17, side brackets 18 and a protective fence 19 covering the handle of the control lever 5.

Inside the protective structure 16 between two brackets 18 on the axis there is a control lever 5 with the ability to make rotary (rocking) movements, while the lower part 20 of the control lever 5 is mechanically connected through the fork axis, the rod fork, the distributor rod (not shown in the drawings) hydraulic distributor.

The control lever 5 is installed in a protective structure 16 with the possibility of placing its lower part (tail part) 20 inside the groove 9 of the rotary element 6 and with the possibility of rotating it in the groove 9 with the safety door 2 closed.

The lower part 20 of the control lever 5 is preferably made in the form of a triangular plate with beveled lower corners forming side projections 21, and with a protrusion 22 on the base, which in one embodiment has a rectangular cross-section with beveled ribs.

The protrusion 22 on the lower part of the control lever 5 fits with a gap into the central hole of the cylindrical protrusion 8 of the rotary element 6.

The control lever 5 has the ability to move forward (away from itself) and backward (toward itself), including, through the associated hydraulic distributor, the working rotation of the hydraulic tong rotor.

When the safety door 2 is closed, the location of the groove 9 of the rotary element 6 coincides with the direction of rotation of the lower part 20 of the control lever 5. When the control lever 5 is rotated to the operating position, when the control lever 5 tilts forward or backward, the side projections of the lower plate 20 of the control lever 5 enter groove 9 of the rotary element 6, and the protrusion 22 on the base of the lower plate 20 of the control lever 5 is shifted along the groove 9 relative to the central hole 7 of the cylindrical protrusion 8. In this case, the side protrusions 21 of the lower plate 20 of the control lever 5 prevent rotation of the rotary element 6, thereby through the lever 5 blocking arbitrary opening of security door 2 while the key is operating.

After the end of the working cycle, control lever 5 is returned to the neutral (vertical) position, the rotation of the rotor stops and it becomes possible to open door 2.

When the safety door 2 is opened, the protrusion 14 on the door 2 pushes the lever 10, which, when turned, displaces the rotary element 6, turning it. In this case, the groove 9 of the rotating element 6 rotates relative to the axis and blocks the lower part 20 of the control lever 5, preventing arbitrary rotation of the control lever 5 forward or backward, which is especially important for safety reasons. When the safety door 2 is open, the rotary element 6 is rotated so that the groove 9 is oriented predominantly at an angle of 45° with respect to the lower part (plate) 20 of the control lever 5. The angle of placement (rotation) of the groove 9 relative to the lower part 20 of the control lever 5 can be to others. The protrusion 22 on the base of the lower plate 20 of the control lever 5 is located in the central hole 7 of the cylindrical protrusion 8, and due to the rotation of the rotary element 6, the groove 9 is displaced, which does not allow the protrusion 22 to move in the groove 9, while blocking the rotation of the control lever 5.

When closing the safety door 2, the lever 10 rotates due to the pushing action of the wedge-shaped cam 13, rotating the rotary element 6 to its original position, thus making it possible to rotate the control lever 5.

The claimed design of the safety door locking device is designed for use on hydraulic tongs with a control handle on the left side, type GKSh 1200,1500,1600 in the MT version (tandem motor). It is also possible to use the proposed device on other hydraulic tongs having a similar design.

The proposed hydraulic key safety door locking device has a simple design, is characterized by increased operational reliability, is technologically advanced in manufacturing, and can be produced in domestic industry using well-known equipment, materials and technologies.

The terms and phrases used in this description: “comprises”, “comprising”, “preferably”, “mainly”, “in particular”, “may” and variations thereof should not be interpreted as excluding the presence of other materials, parts, design elements, actions.

Claims (10)

1. A device for locking the safety door of a hydraulic key, comprising a safety door and a lever installed on the body of the hydraulic key, characterized in that one arm of the lever is in contact with the cam of the safety door when it is closed, and the second end of the lever is connected to a rotary element mounted on the body, when In this case, the rotary element is equipped with a groove, made with the possibility of placing and moving in it when the safety door is closed, the lower part of the control lever associated with the hydraulic distributor of the key, and with the possibility of blocking the rotation of the rotary element when the lower part of the control lever moves in the groove, while the door is open The safety groove of the rotating element is offset relative to the lower part of the control lever to ensure that the movement of the control lever is blocked. 2. The hydraulic key safety door locking device according to claim 1, characterized in that the rotary element is installed on the axis of the housing with the ability to rotate relative to the axis. 3. The hydraulic tong safety door locking device according to claim 1, characterized in that the groove in the rotary element is made in a protrusion formed on the upper surface of the rotary element. 4. The hydraulic key safety door locking device according to claim 3, characterized in that the protrusion of the rotary element has the shape of a hollow cylinder. 5. The hydraulic tong safety door locking device according to claim 1, characterized in that on the base of the lower part of the control lever there is a protrusion that fits with a gap into the central hole of the cylindrical protrusion of the rotary element. 6. The hydraulic tong safety door locking device according to claim 1, characterized in that on the lower part of the control lever there are side projections designed to prevent rotation of the rotary element when the control lever is in the operating position. 7. The hydraulic key safety door locking device according to claim 1, characterized in that the rotary element is protected from mechanical damage by a protective structure. 8. The hydraulic tong safety door locking device according to claim 7, characterized in that the protective structure is detachably attached to the housing. 9. The hydraulic tong safety door locking device according to claim 7, characterized in that the protective structure consists of a base, side brackets and a protective guard covering the handle of the control lever. 10. The hydraulic tong safety door locking device according to claim 1, characterized in that when the safety door is open, the rotary lever is secured against displacement by an elastic element.