KR840000500Y1 - An anchor - Google Patents

Abstract

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Description

Landfill anchor

1 is a side view of the first sphere body of the present invention.

2 is a plan view of a part of the first embodiment of the present invention.

3 is a side view of another part of the first embodiment of the present invention.

4 is a plan view of the part shown in FIG.

5 and 6 are plan and front views of another part of the embodiment shown in FIG.

FIG. 7 is a partially cut away elevational view of the assembled form of the parts shown in FIGS.

8 is a cross-sectional view taken along line VII-VII of FIG. 7.

9 is a view in the direction of arrow VII of FIG.

10 and 11 are schematic illustration of each step of the landfill process.

12 and 13 are side and plan views of the piling rig with anchors in place prior to reclamation.

14 is a side view of a second sphere shape of the present invention.

The present invention relates to a buried anchor used to anchor a structure, and more particularly to a buried anchor used to anchor an offshore platform to the bottom of a seabed. The invention also relates to a method of embedding such anchors.

The greatest difficulty in designing landfillable anchors and landfill processes is that such anchors and processes must be provided for many different types of soils. As a result, some processes and anchors can be applied to only one or only a few selected soils, although they are completely satisfactory in themselves.

Different types of soil need different faults, and if not, there is a disadvantage in that the price is expensive because at least separate equipment and stocks must be applied to the soil under different conditions. It is therefore considered desirable to develop anchors and processes that apply little or no difference to all types of soils.

More severe restrictions apply to the installation process for anchoring and reclamation processes that can be buried in the sea. Therefore, it is desirable that the anchor can be fixed by the work on the sea surface except for the cutting work of temporary temporary ships, which can be done by the first submersible or small submersible. Secondly, the necessary equipment should be either currently in use or at least developing rapidly.

It would be desirable to be able to provide anchors of different capacities over a relatively wide range by changing only some or all of the variables for the shape of the anchor at a constant rate.

As used herein, the term land refers to the outer layers of the earth's crust, including dry land soil and sand or other seabeds in the ocean.

The present invention provides a method of embedding a buried anchor in the ground, which has a support rod and a thrust member mounted thereon so that the anchor is placed on the ground surface and then anchored to the ground by the thruster. The thruster is subject to a considerable amount of resistance to the lateral movement of the anchor when it is landfilled by pushing the anchor into the ground.

The present invention also provides a method of embedding a buried anchor in the ground, wherein the anchor is equipped with a thruster that is capable of moving along at least a portion of its length, thereby placing the anchor on the surface of the ground. Later, when the thruster is buried through the stages that push the anchor into the ground until it is buried, it is subject to considerable magnitude of resistance to the lateral movement of the anchor.

In the method described in the preceding paragraph, the thruster can be pushed into the ground before, after, or along the way of pushing the rod into the ground.

The present invention provides a method of embedding a buried anchor in the ground, which has a vessel or longitudinal passage between both ends of the thrust device, or a hollow shaft or tubular support rod, and an anchor in the ground. The method consists of placing the anchor almost vertically on the surface of the ta, and then pushing the anchor into the ground until the thrust device is driven into the ground. I'm in, and when the thrust device is stuck in place, it pulls the material out of the aisle or tube.

The present invention also provides a method of embedding a buried anchor in the ground, which includes a thrust device, a vessel or longitudinal passage between the two ends, or a hollow shaft or tubular support rod, and an anchor in the ground. It consists of a buried device, a fixed device of several components having a closed or folded state and an open or expanded state, and devices installed to hold the components in a folded state. Position the support rods almost vertically, push the anchor into the ground until the thruster is driven to the ground, and move the components described above in the folded state, which is partially removed by removing the binder from the vessel, passage or tube. It is made by giving.

According to the present invention, the buried anchor is composed of a thrust device that is mounted on the support rod and is applied a considerable amount of resistance to the lateral movement of the anchor when buried.

In the embodiment of the present invention, the thrust device can move along at least a portion of the support rod length.

The buried anchor provided according to the present invention has a support rod, a thrust device that exerts a considerable amount of resistance to the lateral movement when the anchor is in position, a device for fixing the anchor in the ground, and the fixing device is a support rod. It is fixed at one end or adjacent to the rod, which resists upward movement when the anchor is in position, and the thrust device is mounted on the support rod so that it can move relatively along at least a portion of the rod length.

The fastening means may take the form of a cracked fastening device secured at points spaced apart along the length of the support rod. One of such split anchors may be at the end of the support rod. In this way, the anchor's resistance to uplift, i.e., to lift the anchor from the buried position, is increased.

A cracked fastening device may take the form of moving a part in the device to a position where the device causes the maximum resistance to bulging force. Such parts can be variably moved to such a position or can be connected to a common actuator that can simultaneously move all the parts to that position.

The present invention also provides a method of embedding an anchor in the ground, the anchor having a thrust device mounted on the support rod to move relative to at least a portion of the support rod length, which places the support rod almost vertically The thrust device is partially driven into the ground, and the thrust device is pushed into the ground until the thrust device comes to the opposite end of the support rod, and then the thrust device is pushed into the ground.

The present invention also provides a method of embedding an anchor in the ground with a thrust device mounted on a support rod so that it can move relatively at least along a portion of the support rod length. It is to be pushed into the ground until it is partially or completely in place, and the locking device is pushed into the ground until the thrust device is at the opposite end of the support rod, and then the thrust device is completed if necessary.

The present invention also provides a buried anchor consisting of a thrust device, a support rod and a device for fixing the device in the ground, wherein the fixing device consists of two or more plate-like structures, which are pivotally coupled to the support rods and the plates are parallel FIG. 1 is movable between a folded state and a second or expanded state extending laterally with respect to the axis of the support rod, and a device is provided for holding the plates in the folded state.

The thruster resists upward movement when the anchor is in place.

The present invention also provides a method of embedding the anchor consisting of the aforementioned plates, which pushes the anchor into the ground until the thrust device is driven into the ground, releases the retaining device and then unfolds the plates in the folded state. have.

The present invention also provides a method of embedding a buried anchor in the ground, which consists of a thrust device, a support rod, and a device for anchoring the anchor to the ground, which form an almost vertically extending hole and The anchor is to be inserted.

The present invention also provides a method of embedding a buried anchor having any two or more of the aforementioned methods.

The present invention also provides a buried anchor having any two or more of the above mentioned anchors.

The present invention also provides a method for embedding a buried anchor having at least two of the aforementioned anchors.

The advantage of placing the union in a container or passageway before pushing it in is that there is no need to make a separate line to fill the container or passageway or tube after installation.

The advantage of using the binder to release the retainer and move the devices from the folded state to the expanded state is that the binder is needed anyway to retain the retaining device in at least most applications. The advantage of having a thruster that can be moved at least along a portion of the rod's length guides the rod into the ground when the thruster is partially embedded in the ground.

All anchors manufactured by the present invention and anchors used in all methods by the present invention include support rods in the form of containers or longitudinal passages or hollow shafts or tubes between both ends. The support rod is in the form of a solid rod. In such a case, the support rod has one or more longitudinal grooves externally in the longitudinal direction through which the devices constituting the fixing device can be released and move.

All buried anchors manufactured by the present invention and anchors used in all methods according to the present invention hold the fixing device and its components in a folded state consisting of a plurality of components having a closed or folded state and an open or expanded state. Equipped with a device. The device consists of one or more explosive bolts that hold the components in a closed or folded state until they need to be moved to an open position. Then, when an explosive charge is initiated, the components are moved open by an explosion or released by another device. The explosive material of the bolt is exploded either by remote control or by a trigger device mechanically actuated by a suitable device actuated by a control signal, for example a raccoon signal or an ultrasonic signal. Alternatively, after the component is released, the anchoring movement continues further, and the component may be formed to move open.

Except for having a thrust device mounted on the support rod so as to be able to move at least relatively along a portion of the support rod length, all the buried anchors and methods of embedding made by the present invention are located at the end of the support rod away from the fixing device. It is also possible to use a fixing device consisting of a fixed thrust device.

In all of the methods according to the present invention the binder can be pulled out as a container, passageway or tube for release of the retainer. Otherwise the retainer may be released by explosive filling or cutting. Explosive charging can be initiated by a signal transmitted from a location far from the anchor. The signal is a radio signal or an ultrasonic signal.

In all the methods according to the present invention, the binder can be used to cause the overall movement of the components. Otherwise the retainer can be released before the pushing is complete and the components can be moved into the expanded state by the binder after the components have been partially expanded and thus completed by the pushing action.

Retention devices may be installed to keep components open or expanded. The retaining device may allow the components to be automatically locked when in the above state.

In all methods according to the present invention, a reinforcing agent, ie a spirally wound reinforcing material, is disposed in the container, passage or tube, and is released by the binder. The reinforcement serves to reinforce the bulbs formed around the fasteners.

In all the methods of the present invention, for example, before the completion of the pushing operation, the holding device is released and pushed by an explosive filling or cutting device except that the binder is used to move at least partially into the expanded state in the folded state. By completing the operation the components are moved out of the folded state. This method is particularly advantageous when the components consist of the aforementioned plates.

In all methods according to the present invention explosive filling is used to partially move the above-mentioned components in the folded state.

In all methods of the present invention, explosive filling is used to move the components entirely, except for the use of binders and pushes to move the components.

In all methods according to the present invention, the binding material passes under a hollow shaft or passageway after the fixing device is installed, except that the support rod is pre-filled with the binder.

All methods of the present invention, including the step of embedding an anchor in the ground, may be replaced or supplemented by forming a hole extending substantially perpendicular to the ground and inserting the anchor in the hole instead of such a step. If the hole is made deep enough, no push is necessary, but if the length of the hole is shorter than the length of the rod, then an anchor is inserted into the hole and then pushed to fully install the fixing device. For example, when the fixing device is installed in a rocky area, it is necessary to form the hole in advance. If necessary, the bottom of the hole can be widened.

The retaining device may consist of a locking bolt that can be sheared by cutting when it needs to be released. Such locking bolts can be used when the components of the fastening device are in the form of hooks or plates (shrink-coupled to the supporting rods).

Otherwise the components may form a hollow tubular chamber, which components are brittlely linked together by a weak line. In this case, the molar retainer consists of a brittle connection which can be destroyed by the pressure of the binder or by the explosion of explosive substances in the chamber.

Whenever any of the methods according to the present invention is applied to the ocean, the landfill operation is preferably performed by an underwater hammer. The anchor can thus be almost entirely buried by surface work. Furthermore, for marine applications it is desirable to attach the anchor cable to the device prior to pushing it so that the anchoring device is ready for use as soon as it is properly installed. Anchor cables can be attached by universal joints or other devices that allow the cable to move as needed. In some cases, however, the anchor is laid and the anchor cable connected. The binder may be mortar, concrete and epoxy resin. It may also contain materials that slow down the rate at which the binder solidifies when placed in a passage or tube.

In all methods and anchors according to the present invention, one or more fastening devices may be arranged along the length of the support rods.

The thrust device is generally cylindrical and preferably open at its ends. Other forms, such as truncated cones or cones, may be used, but cylindrical thrusters provide better displacement / load characteristics. To facilitate fabrication, for example, the top view may be regarded as a substantially approximate cylinder with a polygon, such as a hexagon, with an open end and thrust made from a plate. The shape of the thrust device can be determined by the anticipated direction of load to be supported when the anchor is embedded, along with the shape of the other components of the buried anchor. The interior of the thruster is divided into compartments by partition walls extending radially from the centerline of the thruster. The partition wall also serves as a reinforcement.

It is advantageous to install cutting edges to help drive thrust to the ground. It is particularly advantageous if the thrust device is an open lattice or compartmental structure. Such a structure provides a better strength / weight ratio.

The lattice and compartments are installed to allow soil to pass through the landfill, making it easier to bury them. The size of the lattice or compartment is reasonable so that the soil can be filled in and maintained inside the thruster.

If the thruster is mounted on the support rod to move relative to at least part of the rod length, if the thruster is mounted on the support rod near the anchorage, the thruster can be released to the support rod near the anchorage. It is desirable to be. The thrust device can be brittlely connected to the support rod, the connection can be destroyed by explosive charging, or can be destroyed by explosive charging, for example, or by other release devices such as explosive bolts. .

The method of using such a thrust device includes another step of releasing the thrust device from the support rod. The thruster is released when it is partially embedded in the ground. In this case, it is desirable to connect the thrust device to the support rod brittlely so that it can be released from the support rod by the first push of the fixing device to break the weak connection. Otherwise, the thruster is completely buried by pushing the support rods and retainers, and then the thrusters are released from the support rods to complete the pushing of the support rods and fixation devices.

If necessary, the anchor may be completely buried in the ground and then the thruster may be connected back to the support rod. Connections may be made by wedge-shaped surfaces or locking devices that operate on their own or require remote control, or by explosive fillings that deform the thrust device or portions thereof to wind the components onto the support rods.

When the fixing device consists of two plates, it is held only by bolts which can be released by explosion or cutting. The plates can be kept expanded by forcing the binder into the space beneath the plates. Otherwise, it is advisable to install a linkage to connect the plates together so that the plates remain expanded by the combination. The combination may be self-locking to hold the plates.

The present invention also provides a support structure for supporting the anchor during the push, the support structure being a tower for supporting and guiding the support rods, the tower being fixed to the base to position the tower on the ground.

Such hypotheses are particularly good for the ocean. If the base is properly positioned on the bottom of the sea floor, it can be pushed quickly compared to normal piling as it can be precisely pushed, is not affected by currents in the water, and there is no need to keep the supporting vessel exactly in one place. Because it can and continue in bad weather.

Although the tower may have an external wife body, it is better if the tower is in the form of a hollow shaft to support and guide the support rods.

The support structure can be used in any of the fixing device and the process according to the present invention.

The support has an anchor or method of using the anchor having a thrust device mounted on the support rod so as to be able to move at least relatively along a part of the support rod length and secured so that the thrust device can be released to the support rod near the fixing device. Particularly useful. In this case, the anchor may be placed on the structure together with the thrust device disposed below the base and the support rod supported by the tower. When the structure is lowered onto the ground, its weight (along with the weight of the anchor) can be used to block thrust in the ground until the base itself is supported on the ground. By pushing in the structure, the base can be placed in a suitable location on the ground. It can then be buried by pushing the anchor into the ground and the thrust device is partially or completely blocked in the ground before being released from the support rod.

The support structure is installed so that an underwater hammer can be used, and a guide for the hammer is preferably installed on the tower. It is advisable to install a buoyancy chamber to assist in the recovery of the supporting structure, which may be attached to or be part of the base and can be filled with water for lowering and pushing and supporting from the bottom of the sea floor after the push is completed. Air can be injected to lift the structure.

Referring to the anchor and support structure and the embedding method produced by the present invention with reference to the accompanying drawings in detail by the embodiment as follows.

1 to 9, the first embodiment of the present invention consists of a buried anchor, indicated by (1). The anchor has a hollow shaft or tubular support rod 2, and as shown in Fig. 1, the anchoring device 3 is fixed in the folded state. It is the thrust device 5 that can be moved relative to the support rod 2. The thrust device 5 consists of a cylindrical bottom 6 and an inner rib 7 which is a hollow hollow tube 8 through which the support rod 2 passes, as shown in FIG. Stretched from The tube 8 extends only partially into the cylinder and the lower edge of the rib 7 is thus inclined as shown. The staggered side of the rib 7 extends upward from the bottom 6 and supports the upper part of the tube 8, and a flange collar 9 is fixed to the upper end of the tube. The upper end of the other rib 7 is flush with the upper end of the bottom 6.

The rib 7 therefore divides the interior of the main gear into a series of compartments and gives some degree of rigidity to the cylindrical structure. The lower edge of the rib 7 and the lower edge of the bottom 6 can be sharpened or fitted with edges that allow the device to move easily in the ground during landfilling. The fastening device 3 consists of two anchor branches 10 and 11 with flat surfaces 12 and 13 (FIG. 9) in the shape of spades (FIG. 7), each of which has a flat surface. There are ribs 14 located in the recesses formed by the two parallel, and the lower ends are inclinedly cut and the lower ends are connected by a wedge-shaped transverse wall 16 as can be seen in FIGS. 3 and 4. There is a rib 15. As can be seen in FIGS. 3 and 4, the ribs 14 and 15 extend slightly further beyond the upper edges of the surfaces 12, 13.

There are three ribs 14 which are spaced laterally in parallel, and two outer ribs are provided with teeth 17 on the arched surface of the upper portion thereof. At its lower end, the rib 14 is connected by a mandrel 18.

As indicated by the lower edges 19 and 20 of each surface 12, 13, the ends are pointed and slanted and meet the lower edge. The two anchor branches are respectively pivotally coupled to the hinge block 22 by bolts 23 and 24 (FIGS. 5 and 6), the bolts being the top of the ribs 14 and 15, respectively. Through the corresponding holes 27 and 28 of the four mounting arms 29 extending from the base 30 of the block 22 and through the holes 25 and 26 at Do it. Hinge block 22 is fixed to the lower end of the support bar (2).

The lock bar 31 extends downward from the base 20 of the hinge block 22 and also in the center between the anchor branches 10 and 11, and a plate 31a is welded to the lower end thereof so that the cross section 32 is formed. The lower end of the link 33 is pivotally coupled on the plate and the other end of the link is pivotally coupled to the mandrel 18. The lock bar 31 passes through a hole 34 in the base 30 of the hinge block 22 and is relative to the pair of cooperating wedges 36 fixed to the base 30 together with the lock bar 31. It passes through a pair of wedges 35 which can be moved (Figs. 7 and 8).

The spine assembly has a parallel plate 37, the upper end of which is connected to the outer arm of the arms 29 of the hinge block, the lower end of which is connected to the cross plate 38, and the lower part of the plate 37 is enlarged. This facilitates the attachment of the plate 38. Anchor branch transverse wall 16 is perforated in 39 to accommodate conventional explosive bolts (not shown) designed to withstand predetermined tension loads and to be cut cleanly at shear notches located on the shaft of the bolt. .

The supporting rods 2 are made of steel of strength 50, and the lower end thereof is completely welded to the base 30 of the anchor block, and the anchor block itself is cast by annealing mild steel. The thrust device 5 and the rib 7 can be made of a mild steel sheet. Anchor branches 10 (11) are also cast and annealed in mild steel, and so are hinge blocks 22. Link 33 is made of high tensile steel, such as anchor locks, ring bolts or other suitable fastening means (not shown). To the upper end of the support rod (2) or to the thrust device, to secure the anchoring cable or chain to the anchor.

As described above, the thrust device 5 can be moved relative to the support rod 2, and is located in a position adjacent to the anchor branch to serve as a template for guiding the support rod in the initial stage of embedding the anchor in the ground. can do. If necessary, the thrust device may be temporarily fixed to the support rod in the position just described and its fixation may be broken during the internal movement of the support rod.

Figure 10 shows only a schematic view of the anchor being located at the bottom of the sea before the start of landfilling. In the position shown in FIG. 10 before the device is buried in the seabed, the anchor is hoisted with the thrust device 5 to the side of the barge 39. The upper end of the support rod 2 is connected to the drive shaft 41 of the underwater hammer 42. The whole system is then sent down to the sea floor.

By the weight of the device, the thrust device 5 is pushed into the top layer of the seafloor material. In order to facilitate the entry of the thrust device 5, the lower edge 43 may be sharply formed. The device is now in the position shown in FIG. A hammer 42 is used to drive the support rod 2 into the ground, and the thrust device 5 serves as a guide for the support rod 2 while the support rod is moving down. If the thrust device 5 is attached to the support rod 2, the initial drive of the support rod breaks the connection so that the support rod 2 freely penetrates into the thrust device 5.

Pushing continues until the flange 4 on the support rod 2 engages with the thruster 5. The support rods 2 and thrust device 5 are then pushed to their final position below the bottom of the seabed. The thrust device 5 may be pushed down below the surface of the sea floor, but may remain at or above the floor, depending on the material of the sea floor. The thrust device 5 on the bottom of the sea floor can be firmly mounted on the gate because its shape is an open compartment.

The explosive bolts that hold the anchor branches 10 and 11 together explode just before the anchor reaches its final position, causing the anchor branch to open by moving the anchor further to that position. The opening of one anchor branch is simultaneously performed with the other anchor branch because the gear branch 17 (FIG. 3) on the rib 14 moves and engages, and then the anchor branch moves together. After the anchor branch is completely opened, the anchor branch is locked by the anchor lock, and the link 33 is in a straight line shape.

If necessary, the thrust device 5 may be partially embedded in the sea floor before the push of the support rod is marketed. The thruster may also be pushed into the final bottom position of the seabed before the support rods begin pushing. This method may be adopted if the mechanism for embedding the anchor is not strong enough to simultaneously drive the thruster and support rods.

Sometimes when a load is applied only on one side of the anchor, i.e. when the load is applied only laterally and rarely upwards, or when the load is only applied upwards to the anchor and tends to be pulled up from the bottom of the anchor It should be noted that there may be situations in which this load must be tolerated. In such a case, there may be no fixing device, and the anchor may basically consist of a supporting rod equipped with a thrust device.

The shape of the thrust device is determined by the factors described above, and for example, a thrust device 5 of the type shown in FIG. 1 may be used. The thrust device may be permanently secured to the support rod or may be able to move along a portion of the support rod length. As described above, the thrust device may be detachably attached to the support rod to be movable if necessary, so that the relative movement between the thrust device and the support rod once broken may occur. In this basic form, the anchor can take the form of a support rod (2) and a thrust device of the type shown in FIG. 1, so that the support rod can be easily embedded in the ground as indicated by the dotted line (52). The lower end of the support rod is pointed and there is no fastening device 3.

The thruster does not necessarily have to be able to move along the support rods. The thrust device may be permanently fixed at one part of the support rod, ie at the upper end adjacent to the flange 4. The choice of the size of the anchor and the size of the anchor's components, such as the thrust device, and the choice of the depth at which the anchor is embedded, are determined by the soil to be anchored and the load applied to the anchor and the direction in which the load is applied. With regard to the shape of other parts of the buried anchor, in the form of a thrust device can also be determined by the direction of load application that is also expected.

A truncated or cylindrical thruster has the advantage of being able to withstand a wide range of slopes and lower roofs from all directions. In order to facilitate fabrication, a thrust device, for example polygonal in cross section and made of a plate, can be considered to be substantially cylindrical. The thrust device may be made of two or more parts and then assembled around the support rod. If the load is applied only in a given direction and has a certain slope, a simple form of thrust device such as plate or sheet may be used. In addition, where a large number of buried anchors are used for anchoring a structure, the size and shape of each part of the anchor will depend, in part, on the number of anchors and their placement in relation to the structure.

In particular, the type of thrust device is determined by the above factors. The rods constituting the buried anchor embodying the present invention are 70 feet in length and 3 feet in diameter, one end having a cylindrical support rod having a diameter of 25 feet and a depth of 12 feet, and the other end having a length of 10 feet. There is a fastener with an anchor branch of 80 square feet in horizontal position.

If the top surface of such an anchor's thruster is embedded in the mud vertically to the depth of about 25 feet below the surface of the sea floor, the calculated maximum load capacity will be upwards of about 2003 tonnes and about 1595 tonnes in the long direction, The long-term dose is about 960tonf. When the load is applied intermittently, periodically or repeatedly, the maximum load capacity is about 1598 tons. In the sand, the upper and lower values are about 3737 tons in the short and long periods, respectively, and 1467 tons in the horizontal direction, and about 1967 tons in the case of periodic loads.

If the anchor is buried so that the top of the thrust device is about 10 feet below the bottom of the seabed vertically in the harder mud, the calculation of the maximum load capacity is about 2830tonf in the upper direction, about 2019tonf in the long term, and in the horizontal direction. The long-term dose is about 1642tonf. If the load is applied intermittently, periodically or repeatedly, the maximum load capacity is about 2014 tonnes. In the sand, the value is about 2795tonf in the short and long term, about 800tonf in the horizontal direction, and about 1381tonf in the periodic load.

It should be noted that the above embodiment is only one embodiment of a buried anchor under specific soil conditions, and that different shapes and sizes are required for different soil conditions. Thrust devices, support rods and branches, which are the main parts of the anchor, can be assembled separately in various sizes to assemble anchors that can be embedded in a particular direction or in a range in a particular soil structure.

Once anchored, the anchoring device contributes significantly to the anchor's resistance to upward motion, while the thruster provides a significant portion of the anchor's resistance to lateral motion. The combined mass of the thruster also contributes significantly to the anchor's resistance to upward motion, along with frictional resistance to motion. If additional resistance is required for the upper clouds, it may be possible to have one or more additional fastening devices of similar construction to the device 3 described above of the anchor. Such a further fixing device will be fixed at a point away from the lower end of the support rod.

If an additional fastening device is installed, it is desirable to allow the movement in the open state to take place simultaneously. It will be appreciated that with reference to FIGS. 10 and 11 other landfill techniques may also be employed. For example, embedding an anchor in the ground can be replaced or secured by drilling a vertical hole in the ground and embedding the anchor in the life preserver. The depth of the hole is determined by the terrain of where the hole is to be formed.

For example, a hole may be formed in advance through a layer of rock placed on the underlying soil through which the anchor may push, in which case the depth of the hole is shorter than the length of the anchor. If necessary, the bottom of the hole can be enlarged to allow the anchor branch to move outwards easily.

The anchor can also be opposed to the desired location using a filling rig. If the location is a seabed, the rig may be transported to the desired place by the ship or barge and lowered to the bottom. Otherwise, the rig may be held from the horizontal position on the deck of the ship to the vertical position and lowered to the bottom.

Such rigs may also be installed on special support devices for ships built to perform anchor reclamation. If necessary, the rig may be lowered to the bottom of the sea through the entrance to the ship's hull. 12 and 13 are, respectively, one side elevation and a plan view of the filing league, with the rig and associated components shown in outline only.

The rig consists of an open lattice tower 44 and the lattice tower is supported by three legs 45, each leg being pivotally coupled to the tower 44. A shoe 46 is fitted at the lower end of the leg 45, and the shoe includes a leveling device for vertically standing the top 44.

In the lattice tower, a device for driving the hammer 47 is installed, and the reciprocating motion is transmitted to the hammer through the cable 48 from the drive device. The elevating cable 49 fixed to the upper end of the tower 44 serves to allow the rig to descend to the desired position. The hammer 47 is guided by a guide surface on the tower 44 and strikes the anchor 1 via a drive driven body 50 which allows the anchor to be buried below the surface if necessary. The driven body preferably extends upwards in the hammer because it improves the stability of the hammer motion. The upper part of the driven body is equipped with a protective helmet, with a wooden cushion between the helmet and the end of the driven body. The cushion not only serves to reduce the maximum impact of the hammer impact, but also prolongs the impact period, making the push faster. The cushion also reduces dents at the top of the driven body.

The driven body is not essential, and the hammer may be transmitted directly to the shaft. The filing rig is used in the conventional manner once it has been transported to the desired position and reached the position where it is to be anchored. Once the anchor is buried, the rig is recovered for another landfill.

If necessary, buoyancy tanks may be attached to the rig so that it floats in the desired position at sea. When the desired position is reached, water enters the tank, causing the rig to sink to the sea floor. The rig floats in a horizontal position and, upon reaching a designated location, moves the tank vertically to selectively allow water to enter the tank before or during the descent operation.

When the anchor is buried, air is pumped into the tank, causing the rig to float to the surface. The fastening device may take a different form than the anchor branch described above. For example, a hollow bulb may be attached to the lower end of the support rod to allow the interior of the bulb and the interior of the support rod to pass through. The bulb can form weak lines that form a series of prongs that resemble anchor branches.

Bulbs are shaped to facilitate entry into the ground during landfilling. When landfilled to the desired length, the bulb ruptures along the weak line, and the pout opens out into the nearby soil. The bursting out action is achieved by injecting a fluid material into the bulb by explosive filling inside the bulb or through a support rod. The material can be liquid concrete, liquid mortar or epoxy resin.

The flowable material may be contained in the bulb or support rod and may be compressed to rupture the bulb or spill the material to form a rigid shape around the canister to form an effective fixation device. Alternatively, the material may be injected into the bulb via a supply line directly connected to the bulb or directly to the support rod.

Proton bursts and protruding actions can be caused by explosives and then injected into the ruptured bulb to form the solid shape mentioned above. The protruding action can be caused in part by explosive filling and in part by injecting fluid into the bulb. Alternatively, explosive filling can be used to rupture weak lines in the bulb without causing the prongs to move by the flowable material.

14 schematically shows that the bulb is ruptured so that the anchor is embedded and the prong 50 pops out so that the flowable material is injected into the bulb to form a rigid body 50 around the pro. As a reinforcing agent, for example, a flexible wire or a spiral wound form of a rod may be mounted on the support rod to be pushed out by the flowable material.

The flowable material can be pushed into the aggregate to rupture the bulb to form a prong, and then grout can be injected into the space within the aggregate to form a rigid shape inside and on the prong. If desired, a fluid binding material may be used in connection with the anchoring branch anchoring device of the anchor as described with reference to FIGS. 1-9. After the landfill is completed and the anchor branch is moved outwards, the material is injected into the space within the anchor branch, forming a solid wedge between them to keep the anchor branch in an unfolded form.

If necessary, the anchor can be easily manufactured to remove from the ground when it is no longer needed. In this case, for the anchor described with reference to Figs. 1 to 9, there should be a device for reducing the anchor branch back to the folded state. Otherwise, you can pull the anchor out of the ground by applying the appropriate force.

Claims (1)

Fixing device that can be changed from the form that can be easily buried in the ground with respect to the bottom of the supporting rod or its adjacent part buried in the ground so that it can bear most of the total resistance to upward movement when it is buried in the ground. In fixing the anchoring cable or chain to fix the anchoring cable or chain, the thrust device 5 which is generally cylindrical and extends in the extending direction of the supporting rod 2 and opens at the lower end thereof is at least as long as the supporting rod 2. A buried anchor characterized by being attached to move along a portion.