RU195279U1 - REMOVABLE DRIVING ANCHOR - Google Patents

Abstract

The utility model relates to bottom anchors and can be used to hold floating objects. A recoverable driving anchor includes a spindle, three or more lower double ribs with lower inner plates, a cable tie for an anchor cable, three or more upper double ribs with upper inner plates, a lifting bracket for an exhaust cable, a composite rod fixed to the spindle using a remote disconnect device. It is new that the retrievable driven anchor is equipped with a spindle having a length longer than distance from the bottom of the lower double ribs to the top of the upper double ribs. The anchor is equipped with a lifting bracket, a composite rod and a remote disconnect device. A lifting bracket is attached to the spindle above the upper double ribs with the possibility of rotation across the axis of the spindle; the lifting bracket in the upper position does not touch the spindle. The composite rod includes several sections connected by ends with a collapsible connection, there is a through cavity inside the composite rod, the length of the composite rod is greater than the depth of the water at the anchor installation site. The remote disconnect device includes a detachment mechanism and flexible rods driving it, the length of the flexible rods is greater than the length of the composite rod. The remote disconnect device is attached to the upper end of the spindle using a disconnect mechanism. The composite rod is connected to the remote disconnect device so that it and the spindle are aligned, flexible rods are extended through the entire cavity of the composite rod. An anchor is installed and removed from the surface of the water without performing work underwater. 6 ill.

Description

The utility model relates to bottom anchors and can be used to hold floating objects.

Known anchor, immersed by indentation, for example, using a suction pipe, including a lower plate, an upper plate, pivotally attached to the top of the lower plate, a double spindle, rigidly attached to the lower plate, and mounting parts of the anchor flexible rod [1].

The disadvantage of this anchor is that for its immersion it is necessary to use a suction pipe having a thick wall to absorb pressure, and a diameter corresponding to the width of the armature, and therefore having a large mass, and high-pressure vacuum equipment. In addition, it is necessary to accurately position the spindles of this anchor in the direction of further application of the load.

Known anchor, immersed using impact equipment, including a vertical corrugated plate and a horizontal plate spindle articulated with a vertical corrugated plate [2].

The disadvantages of this anchor include the need to use an underwater loader and the need for accurate positioning of the spindle of this anchor in the direction of further application of the load.

The closest to the claimed technical solution is the anchor, immersed by the method of vertical discharge [3], including a spindle, three lower double ribs with lower inner plates, a clamp for the anchor cable, three upper double ribs with upper inner plates, the fastening part of the exhaust cable.

The disadvantage of this anchor is the impossibility of immersing it in the soil to the required depth with a shallow water depth and in the presence of strong bottom soils.

The task the utility model is aimed at is providing the ability to immerse the anchor at any water depths and bottom soils, except rocky, with the work of immersing it above the water, as well as the possibility of applying a horizontal load to the anchor in any direction.

This problem is solved due to the fact that the anchor including the spindle has three lower double ribs with lower inner plates, an anchor cable clamp, three upper double ribs with upper inner plates, the spindle length is greater than the distance from the bottom of the lower double ribs to the top of the upper double ribs, the anchor is equipped with a lifting bracket, a composite shaft and a remote disconnect device, the lifting bracket is attached to the spindle above the upper double ribs with the possibility of rotation across the axis of the spindle, lifting bracket in the upper position it does not touch the spindle, the composite rod includes several sections connected by ends with a collapsible connection, there is a through cavity inside the composite rod, the length of the composite rod is greater than the depth of the water at the anchor installation site, the remote disconnect device includes a disconnect mechanism and flexible rods that actuate it , the length of the flexible rods is greater than the length of the composite rod, the remote disconnect device is attached to the upper end of the spindle using the disconnect mechanism, rod is attached to the remote device detachably so that it is coaxial with the spindle and flexible rods are stretched across the cavity of the composite rod.

The essence of the utility model is illustrated by drawings, where in FIG. 1 shows an anchor, front view; in FIG. 2 shows an anchor with spaced parts; in FIG. 3 shows a remote disconnect device, a sectional view in isometric view; in FIG. 4 shows a round pipe, isometric view; in FIG. 5 shows a jumper, isometric view; in FIG. 6 depicts an anchor in operating position with a detached composite rod.

The retrievable driving anchor includes a spindle 1, three or more lower double ribs 2 with lower inner plates 3, a clamp 4 for anchor cable, three or more upper double ribs 5 with upper inner plates 6, rigging bracket 7 for the exhaust cable, composite rod, fixed to the spindle using the remote disconnect device 8.

Spindle 1 is a round pipe and has a tip 9 at its lower end. At the top of the spindle 1 has a pair of coaxial holes 10, their axis is perpendicular to the axis of the spindle 1.

The lower double rib 2 includes a rectangular strip 11 and a pair of lower trapezoidal plates 12, in which one of the sides is vertical, the length of this side is equal to the length of the strip 11. Each lower trapezoidal plate 12 has an opening 13 near the small base and an opening 14 near the corner of the large base and sloping side. Each lower trapezoidal plate 12 with a vertical lateral side is rigidly attached to the edge of the strip 11 perpendicular to its plane and in one direction from it. The corresponding holes 13 and 14 of the lower double rib 2 are aligned. The distance between the pair of lower trapezoidal plates 12 in the light is greater than the thickness of the lower inner plate 3.

The lower double ribs 2 are rigidly connected by a rectangular strip 11 to the spindle 1 along it at an equal angular distance between them. The small bases of the lower trapezoidal plates 12 are located near the tip 9 at the same distance from it.

Each lower inner plate 3 is located between a pair of lower trapezoidal plates 12. The lower inner plate 3 has a triangle shape. The angle near the tip 9 and the angle farthest from spindle 1 are rounded. In the corner near the tip 9 there is a hole 15 through which the lower inner plate 3 is pivotally connected to a pair of lower trapezoidal plates 12 through coaxial holes 13. Near the side located near the large bases of the lower trapezoidal plates 12, there is a group of three holes 16. Each of them is at an equal distance from hole 15. This distance is equal to the distance between holes 13 and 14. Through one of the holes of group 16, the lower inner plate 3 is fixed between a pair of lower trapezoidal plates 12 through coaxial e hole 14. When fixing through the distal opening of the spindle 1, the group 16, the lower inner plate 3 does not protrude beyond the lower side of trapezoidal plate 12. All three of the lower internal plate 3 are fixed through the same hole of the corresponding group of holes 16.

The upper double rib 5 includes a rectangular strip 17 and a pair of upper trapezoidal plates 18, in which one of the sides is vertical, the length of this side is equal to the length of the strip 17. The length of the strip 17 of the upper double rib 5 is greater than the length of the strip 11 of the lower double rib 2. Each upper the trapezoidal plate 18 has an opening 19 near the small base and an opening 20 near the corner of the large base and the inclined side. Each upper trapezoidal plate 18 with a vertical lateral side is rigidly attached to the edge of the strip 17 perpendicular to its plane and in one direction from it. The corresponding holes 19 and 20 of the upper double rib 5 are aligned. The distance between the pair of upper trapezoidal plates 18 in the light is greater than the thickness of the upper inner plate 6.

The upper double ribs 5 are rigidly fixed by a rectangular strip 17 to the spindle 1 along it at an equal angular distance between them. The small bases of the upper trapezoidal plates 18 are at the same distance from the large bases of the lower double ribs 2, which is greater than the width of the clamp 4 for the anchor cable.

Each upper inner plate 6 is located between a pair of upper trapezoidal plates 18. The upper inner plate 6 has the shape of a trapezoid, one of its sides is vertical. Near the angle of the inclined side and the large base there is a hole 21 through which the upper inner plate 6 is pivotally connected to the upper trapezoidal plates 18 through the holes 19. Near the vertical side there is a group of three holes 22. Each hole from the group 22 is equally spaced from holes 21. This distance is equal to the distance between holes 19 and 20. Through one of the holes of group 22, the upper inner plate 6 is fixed between the upper trapezoidal plates 18 through coaxial holes 20. When fixing through the hole 22 of the group 22 farthest from the spindle 1, the small base of the upper inner plate 6 is parallel to the axis of the spindle 1. All three upper internal plates 6 are fixed through the same corresponding hole from the group of holes 22.

Between the lower 2 and upper 5 double ribs is a collar 4 for the anchor cable, which can freely rotate around spindle 1.

The lifting bracket 7 is attached to the spindle 1 above the upper double ribs 5 and below the pair of coaxial holes 10 with the possibility of rotation across the axis of the spindle 1. In the vertical position, it does not touch the spindle 1.

Remote disconnect device 8 includes a round pipe 23, two pins with coil springs 24 and flexible rods 25, as well as a jumper (the designation is not shown in the figure).

The lower part of the round pipe 23 has an outer diameter smaller than the inner diameter of the spindle 1, and the upper part is larger than the internal diameter of the spindle 1. At the bottom of the round pipe 23 there is a pair of coaxial holes 26, their axis is perpendicular to the axis of the round pipe 23. The distance from the axis of the pair of coaxial holes 26 to the lower edge of the upper part of the round pipe 23 is equal to the distance from the axis of the pair of coaxial holes 10 to the upper edge of the spindle 1.

Each pin (the designation is not shown in the figure) includes a rod 27, the diameter of which is less than the diameter of the hole 26, and a round plate 28 at the end of the rod 27, the diameter of which is larger than the diameter of the hole 26. The round plate 28 has a side (designation not shown in the figure) according to its a circle directed in the opposite direction from the rod 27. The inner diameter of the rim is greater than the outer diameter of the coil spring 24, its height is less than its length in a compressed state. The pin is inserted by the rod 27 into the hole 26 from the inside of the round pipe 23 and abuts against it with a round plate 28.

The jumper includes two rods 29 located coaxially and a spring stop (the designation is not shown in the figure) between them, rigidly attached to them. The spring stop includes a round plate 30, two truncated cones 31, an axial hole 32, an upper hole 33 and a lower hole 34. The diameter of the round plate 30 is larger than the outer diameter of the coil spring 24, its axis is perpendicular to the axes of the rods 29. The truncated cones 31 abut the base to the round plate 30 from two sides coaxially. The diameter of the base of each truncated cone 31 is less than the inner diameter of the cylindrical spring 24, its height is less than its length in a compressed state. The axial hole 32 passes along the axis of the circular plate 30 and the cones 31, its diameter is larger than the diameter of the flexible rod 25. The upper 33 and lower 34 holes are vertical and coaxial, their axis passes through the center of the circular plate 30. The diameter of the lower hole 34 is larger than the diameter of the upper hole 33. The upper hole 33 extends from the top of the round plate 30 to the axial hole 32. The lower hole 34 extends from the bottom of the round plate 30 to the axial hole 32. The interface between the axial 32 and the upper 33 of the holes is rounded. The jumper is fixed in the pipe so that the rods 29 are perpendicular to the axis of the pipe 23, the axial hole 32 is aligned with the pins and a pair of coaxial holes 26.

Springs 24 are located horizontally. Each spring 24 with one end abuts against the round plate 28 of the pin, with the other end against the spring stop.

Flexible rod 25 has a diameter two or more times smaller than the diameter of the upper hole 33 and less than the diameter of the axial hole 32 of the spring stop. The length of the flexible rod 25 is greater than the length of the composite rod 27.

A flexible rod 25 is attached at one end to the center of the circular plate 28. The other end passes through the axial hole 32 and exits through the upper hole 33 of the spring stop.

The composite rod consists of sections 35, each of which includes a round pipe. They are rigidly connected by the ends by means of a collapsible connection, the connection elements do not completely overlap the pipe cavity, allowing flexible rods 25 to be drawn through them.

Before installing the anchor, it must be assembled.

The opening angle of the lower inner plates 3 and the upper inner plates 6 is selected depending on the characteristics of the soil. The opening angle of the lower inner plates 3 is regulated by connecting them to the lower trapezoidal plates 12 through the corresponding hole of a group of three holes 16. The opening angle of the upper inner plates 6 is regulated similarly.

Flexible rods 25 are pulled and the rods 27 of the pins are pulled inward without protruding from the outer contour of the lower part of the round pipe 23. The remote disconnect device 8 is inserted by the lower part of the round pipe 23 into the spindle 1 from above, the holes 10 and 26 are aligned, after which the rods 25 are released and the rods 27 pins go into holes 10.

The first section 35 of the composite rod is rigidly connected to the device 8 coaxially, the subsequent sections 35 of the composite rod are rigidly connected to each other in series with the simultaneous drawing of the flexible rods 25 through their cavity. The number of sections 35 of the composite rod depends on the depth of water at the location of the anchor.

An anchor cable is attached to the clamp 4, and an exhaust cable is attached to the rigging bracket 7. A float is attached to the end of each cable.

The assembled anchor is suspended on a floating pile driver vertically when the length of the anchor is less than the useful height of the mast of the copra or inclined when the length of the anchor is greater than the useful height of the mast of the copra. After that, the coper is towed to the anchor installation site.

At the installation site, the pile driver lowers the anchor to the bottom in a vertical position. An immersion device (hammer or vibration absorber) is installed on the upper part of the composite rod, which immerses the anchor in the ground for the length of the spindle.

The immersion device is removed. Next, two flexible rods 25 are pulled through the top of the composite rod, the springs 24 are compressed and the rods 27 of the pins exit the holes 10. The remote disconnect device 8 is removed from the spindle 1. The composite rod rises from the water.

A floating tool is attached to the anchor cable to hold it.

To extract the anchor, a floating pile driver with a lifting device approaches the exhaust cable and hooks it to the working body of the lifting device.

A floating pile driver becomes above the anchor, the lifting device pulls the exhaust cable up, the anchor leaves the ground and rises up until it leaves the water.

This technical solution can find application in building floating railway bridges. To date, when building floating railroad bridges, reinforced concrete suction anchors weighing up to 15 tons are used. The application of the claimed technical solution will reduce the weight of the anchor, carry out work on installing and removing the anchor above the water without involving divers, let vessels and floating equipment pass over the place of installation of the anchor, remove the anchor for reuse.

(56) Sources of information

1. Patent for invention US No. 9469960 "Method of and apparatus for installation of plate anchors", published 10/18/2016, IPC F02D 5/80; B63B 21/27.

2. Patent for invention US No. WO 99/46163 "Sea bed anchoring", published September 16, 1999, IPC B63B 21/22; 21/24.

3. Patent for the invention of US No. 7059263 B1 "Gravity installed anchor", published on 06/13/2006, IPC B63B 21/34.

Claims (1)

A removable driven anchor including a spindle, three or more lower double ribs rigidly attached to the lower part of the spindle, with a small plate inside each lower double rib, an anchor cable clamp located on the spindle above the lower double ribs with the possibility of rotation around the spindle, three or upper double ribs, rigidly attached to the spindle above the clamp, with the upper plate inside each upper double rib, the lower and upper plates can be connected by folding connection with the corresponding lower and upper double ribs in different positions so that the lower and upper plates protrude beyond the dimensions of the corresponding lower and upper double ribs, characterized in that the spindle has a length greater than the distance from the bottom of the lower double ribs to the top of the upper double ribs, the anchor is equipped with a lifting bracket, a composite rod and a remote disconnect device, the lifting bracket is attached to the spindle above the upper double ribs with the possibility of rotation across the axis of the spindle, the lifting bracket in the top position does not touch the spindle, the composite rod includes several sections connected by ends with a collapsible connection, there is a through cavity inside the composite rod, the length of the composite rod is greater than the depth of the water at the anchor installation location, the remote disconnect device includes a disconnect mechanism and flexible rods that actuate it, the length of the flexible rods is greater than the length of the composite rod, the remote disconnect device is connected to the upper end of the spindle using the detachment mechanism, composite attached to the rod of the device remote detachably so that it and the spindle is coaxial flexible rods are stretched through the cavity of the composite rod.

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