KR20150092487A - Apparatus for supplying working fluid - Google Patents

Abstract

The present invention relates to an apparatus for supplying a working fluid. More specifically, according to an embodiment of the present invention, an apparatus for supplying a working fluid to supply a working fluid to a plurality of hydraulic cylinders adjusting a height of a plurality of upper vertical bearings rotationally supporting a turret installed on a ship comprises: a fluid pump unit storing and supplying the working fluid; and a manifold transmitted with the working fluid from the fluid pump unit to distribute the working fluid to the hydraulic cylinders.

Description

[0001] APPARATUS FOR SUPPLYING WORKING FLUID [0002]

The present invention relates to a working fluid supply apparatus.

A drill ship or LNG-FPSO (floating oil production and storage facility) that drills gas or crude oil from the sea bed has a turret to aid drilling. The turret is usually mounted on a moon pool including a vertical opening provided at one end of the ship, usually at the tip of the ship, and is fixed to a subsea well platform of the seabed by a chain or the like to moor the ship.

The turret is also mounted on the vessel so that the vessel can rotate relative to the turret as a central axis, providing a stable and continuous transport path for the transfer of gas or crude oil from the ore platform to the vessel during drilling operations.

In other words, even when the ship is flowed by wind, waves or algae while the gas or crude oil is being transported, the ship can freely rotate around the fixed turret as the center axis, so that the gas or crude oil is fixed And can be stably transported through a tube or the like inside the turret. In this case, an example of a structure for allowing the ship to rotate around the turret is such that the bearing provided on the door frame of the hull is in sliding contact with the side wall of the turret so that the turret can rotate.

There are three types of bearings installed in the doorpane: a lower horizontal bearing, an upper horizontal bearing, and an upper vertical bearing. The lower horizontal bearing is provided to be in sliding contact with the lower part of the peripheral wall of the turret, the upper horizontal bearing being provided to be in sliding contact with the upper part of the peripheral wall of the turret, And is provided so as to come into sliding contact with the lower surface of the protruded upper part.

On the other hand, after inserting the turret into the opening of the door, a rotating test is performed in which the rope is wound around the inserted turret to perform the rotation test. This turret rotation test is performed by rotating the swivel To set the required machining amount for the assembly surface of the swivel and then to perform the machining to adjust the shape tolerance to the design requirement level.

As a preliminary work to perform the rotating test, the turret on the structure of the hull is lifted up to about 35 mm by using the upper vertical bearing. The turret resting on the structure of the hull is supported by the upper vertical bearing, The rotation is possible. In order to raise the turret by about 35 mm using the upper vertical bearing, a hydraulic cylinder is added to the upper vertical bearing, and when the working fluid is supplied to the hydraulic cylinder, the roller of the bearing rises to form the upper vertical bearing .

However, since a plurality of upper vertical bearings are disposed at regular intervals along the circumference of the turret to support the turret, in order to lift the turret by using the upper vertical bearing, the working fluid must be supplied while applying uniform hydraulic pressure to the plurality of bearings There is a need.

In the process of installing the turret on the hull, the turret is lifted and rotated to perform the rotating test. The turret should be lifted while installing the turret on the hull, and the operating fluid supply system provided on the hull is to be used There is a need for a working fluid supply system that is temporarily installed in the hull for the purpose of rotating test of the turret so as to uniformly supply working fluid to the hydraulic cylinder of a plurality of upper vertical bearings.

The present invention has been made in view of the above-mentioned need, and it is an object of the present invention to provide a working fluid supply apparatus capable of distributing a working fluid to a hydraulic cylinder which raises an upper vertical bearing for supporting a turret, And methods.

According to an embodiment of the present invention, there is provided a working fluid supply apparatus for supplying a working fluid to a plurality of hydraulic cylinders for adjusting the height of a plurality of upper vertical bearings rotatably supporting a turret installed on a ship, A fluid pump unit for storing and supplying the fluid; And a manifold that receives the working fluid from the fluid pump unit and distributes the working fluid to the plurality of hydraulic cylinders.

In addition, the manifold may be provided with a working fluid supply device for uniformly distributing the working fluid to the plurality of hydraulic cylinders.

In addition, the fluid pump unit may be provided with a working fluid supply device that applies pressure to the working fluid at a pressure not lower than a minimum pressure at which the working fluid is uniformly distributed to the plurality of hydraulic cylinders.

The fluid pump unit may further include an external supply line connected to the fluid pump unit and providing a flow path through which the working fluid is delivered to the outside of the fluid pump unit, An internal supply line for providing a flow path through which fluid is transferred; A pump provided on the internal supply line and for pumping the working fluid; A pressure gauge for measuring a hydraulic pressure inside the internal supply line; And a valve that opens and closes the flow path of the internal supply line may be provided.

Further, the pressure gauge is provided at the rear end of the pump, the valve is provided at the rear end of the pressure gauge, the valve is opened when the hydraulic pressure measured by the pressure gauge is equal to or higher than a predetermined pressure, A working fluid supply device may be provided which is a minimum pressure at which the working fluid is uniformly distributed to the plurality of hydraulic cylinders.

In addition, the fluid pump unit may be provided with a working fluid supply device, further comprising a storage tank connected to the internal supply line and storing the working fluid.

The fluid pump unit may further include: an air passage for introducing air from the outside to provide a flow path to the pump; An air filter provided in the air passage for filtering the air; An air regulator for controlling the pressure of the air; And an air passage valve for opening and closing the air passage.

Further, on the external supply line, a working fluid supply device may be provided in which a filter for filtering impurities contained in the working fluid is provided.

Further, it is also possible to provide a working fluid supply apparatus further comprising a recovery drum for recovering and storing the working fluid supplied to the hydraulic cylinder.

Further comprising a recovery line connected to the internal supply line and recovering a working fluid remaining in the internal supply line when the supply of the working fluid is stopped, wherein the recovery line is a working fluid connected to the recovery drum A feeding device may be provided.

It is also possible to provide a working fluid supply apparatus which further comprises an auxiliary drum provided outside the fluid pump unit and supplying the working fluid to the fluid pump unit.

Further, when the working fluid is supplied to the hydraulic cylinder, the hydraulic cylinder may raise the roller of the upper vertical bearing so that the turret is pushed up.

Also, the working fluid is supplied to the hydraulic cylinder before the rotation test of the turret is started, and during the rotation test, the hydraulic pressure of the working fluid supplied from the fluid pump unit is uniformly maintained A fluid supply device may be provided.

According to an embodiment of the present invention, there is an effect that the turret can be stably lifted as a preliminary work for a rotating test of the turret.

FIG. 1 is a view showing a state where a turret is inserted into a doorway provided in a hull.
FIG. 2 is a side view of the upper vertical bearing of FIG. 1. FIG.
3 is a hydraulic circuit diagram of a working fluid supply device according to an embodiment of the present invention.
Fig. 4 is an enlarged view of the manifold of Fig. 3 enlarged.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a view showing a state where a turret is inserted into a door frame provided in a hull, and FIG. 2 is a side view of the upper vertical bearing of FIG. 1.

Referring to FIG. 1, a turret T is installed on a door frame 10 formed on a ship such as an oil tanker. The turret T installed on the ship can be rotatably supported by a plurality of bearings including an upper vertical bearing 20 provided on the top of the portal 10. [ A plurality of upper vertical bearings 20 are arranged at regular intervals along the periphery of the turret T and serve as general roller bearings for supporting the upper portion of the turret T from below. Further, when the turret T is installed on the hull, it is necessary to perform a preliminary operation for raising the hull from the hull by about 35 mm for a rotating test of the turret T after the insertion into the opening of the door frame 10 do.

To this end, an upper vertical bearing 20 including a hydraulic cylinder 22 connected to a roller as shown in Fig. 2 is used, and when a working fluid is supplied to the hydraulic cylinder 22, the upper vertical bearing 20 Can be raised. When the rollers of the upper vertical bearing 20 are raised, the turret T is also lifted together, so that it is possible to stably perform the preliminary work for the turret T spinning test. At this time, the turret T needs to be raised by a predetermined height at all points along the circumference of the turret T for stable testing, so that the pressure of the working fluid supplied to the plurality of upper vertical bearings 20 is uniformly set Need to be. Here, the working fluid may be oil used in a common hydraulic cylinder.

Hereinafter, with reference to a specific configuration of a working fluid supply device capable of supplying a working fluid with a uniform hydraulic pressure to a plurality of upper vertical bearings 20 so as to stably lift the turret T as one embodiment of the present invention 3 and Fig.

 FIG. 3 is a hydraulic circuit diagram of a working fluid supply device according to an embodiment of the present invention, and FIG. 4 is an enlarged view of the manifold of FIG.

3 and 4, the working fluid supply device according to the present embodiment may be connected to a plurality of upper vertical bearings 20 through a pipe or a hose supplying a working fluid.

The working fluid supply device according to the present embodiment may be temporarily installed to be connected to the upper vertical bearing 20 for a preliminary work for the rotation test of the turret T during the drying process of the ship. Further, when the rotation test is finished, it can be separated from the upper vertical bearing 20.

The working fluid supply device includes a fluid pump unit 100 that stores and supplies working fluid, a filter 200 that filters impurities contained in the working fluid that is connected to the fluid pump unit 100 and flows out of the fluid pump unit 100 A manifold 300 which is connected to the filter 200 and receives the working fluid passed through the filter 200 and distributes the working fluid to the hydraulic cylinder 22, A recovery drum 400 for recovering and storing the working fluid supplied to the upper vertical bearing 20 and an auxiliary drum 500 connected to the fluid pump unit 100 and supplying the working fluid to the fluid pump unit 100 can do.

The fluid pump unit 100 can supply the working fluid stored therein or the working fluid supplied from the auxiliary drum 500 to each upper vertical bearing 20. [ The fluid pump unit 100 includes a reservoir tank 110 for storing a working fluid, a pump 120 connected to the reservoir tank 110 and for pumping the working fluid, an air pump 120 for regulating the pressure of air supplied to the pump 120, And a pressure gauge 140 that measures the hydraulic pressure of the working fluid that has passed through the regulator 130 and the pump 120.

In the present embodiment, the storage tank 110 may be a general oil storage tank, one side connected to a supplementary line 101 connected to the auxiliary drum 500, and the other side connected to an internal supply line (Not shown). When the working fluid remains in the storage tank 110, the remaining working fluid can be supplied to the outside through the internal supply line 105 from the storage tank 110. If there is no remaining working fluid, The working fluid can be supplied from the auxiliary drum 500 provided outside the pump unit 100. Since the storage tank 110 is provided inside the fluid pump unit 100, the capacity may be very small as compared with the auxiliary drum 500.

The internal supply line 105 may be provided with a first valve 102 and the outlet of the working fluid from the storage tank 110 may be controlled as the first valve 102 is opened or closed.

The pump 120 is connected to the outside through an air passage 103 and is capable of pumping the working fluid from the storage tank 110 via the internal supply line 105 using air coming through the air passage 103 . The pump 120 may be a general manual fluid pump, but may be an automatic fluid pump in which pumping control of the working fluid is automatically performed based on a sensed value by a separate sensor (not shown) according to a previously input algorithm . The pump 120 may also be provided in the middle of the internal supply line 105 to pump the working fluid that is stored in the storage tank 110 or replenished from the auxiliary drum 500 via the internal supply line 105, have.

The air passage 103 may be provided with an air regulator 130 and an air filter 132. The air regulator 130 is a general air regulator which regulates the pressure of the air passing through the air passage 103 Can be controlled. The air filter 132 can filter the impurity particles contained in the air to be transferred and can prevent the cylinder 22 and various valves from being damaged by impurities. Further, the air passage 103 may be provided with an air passage valve 104 for adjusting the amount of air to be delivered.

A pressure gauge 140 may be provided at the rear end of the pump 120 and the pressure gauge 140 may be a generally used hydraulic pressure measuring device and may measure the pressure of the fluid passing through the internal supply line 105 The pumping amount of the pump 120 can be used as a controlled reference. A second valve 106 may be provided at the rear end of the pressure gauge 140.

The filter 200 may be provided in the middle of an external supply line 109 connected to the internal supply line 105 of the fluid pump unit 100 and may filter out the working fluid flowing out of the fluid pump unit 100, If it is included, it can be filtered out. The filter 200 is a general fluid filter, and a detailed description of its construction will be omitted.

The manifold 300 may be provided at the rear end of the filter 200 and connected to the external supply line 109 to receive the operating fluid from the external supply line 109. Further, the plurality of T-type connecting pipes may have a structure in which they are stitched to each other, and a plurality of bifurcation points may be formed in one common pipe. Each branch point is connected to a separate supply line 310 individually connected to a plurality of hydraulic cylinders 22 assembled to the upper vertical bearing 20 so that the working fluid supplied from the external supply line 109 is supplied to each hydraulic cylinder 22, (22). ≪ / RTI >

A plurality of hydraulic cylinders 22 may be connected to each of the individual supply lines 310. In this embodiment, as shown in FIG. 3, a total of four hydraulic cylinders 22 are provided for each of the individual supply lines 310 However, the present invention is not limited thereto. One hydraulic cylinder 22 may be connected to each of the individual supply lines 310 according to the number of the upper vertical bearings 20 provided. Or two or more hydraulic cylinders 22 may be connected.

The hydraulic cylinder 22 can be connected to an individual recovery line 410 through which the working fluid that has been supplied to the hydraulic cylinder 22 is recovered on the side opposite to the side to which the separate supply line 310 is connected. Further, the individual recovery line 410 may be connected to the recovery drum 400.

When the turret T which has been raised after the completion of the rotation test of the turret T is to be lowered again, the working fluid is recovered from the hydraulic cylinder 22 and the roller of the upper vertical bearing 20 is lowered. At this time, the working fluid supplied to the hydraulic cylinder 22 may be collected through the individual collecting line 410 and introduced into the collecting drum 400.

The recovery drum 400 may be connected to a recovery line 107 which branches off between the pump 120 and the second valve 106 in the internal supply line 105 of the fluid pump unit 100. Since the working fluid remaining in the fluid pump unit 100 as well as the hydraulic cylinder 22 may be present after the completion of the rotation test, the remaining working fluid may also flow through the recovery drum 107 ). ≪ / RTI > Further, the recovery line 107 may be provided with a third valve 108, and may further include a fluid pump for pumping and recovering the remaining working fluid.

Although the recovery line 107 is branched between the pump 120 and the second valve 106 in the present embodiment, the idea of the present invention is not necessarily limited thereto. For example, (107) may be connected to the rear end of the second valve (106) and may be provided to be connected to a position optimal for the recovery of the residual fluid depending on the internal piping arrangement state of the fluid pump unit (100) It is also possible to connect.

The auxiliary drum 500 may be a large capacity drum storing the working fluid of the fluid pump unit 100, and the storage capacity thereof may be very large as compared with the storage tank 110. The auxiliary drum 500 may include a pump (not shown) to transfer the working fluid stored therein to the storage tank 110 and may include a switch 510 for operating the pump provided in the auxiliary drum 500 can do. When the switch 510 is operated by the operator, the working fluid stored in the auxiliary drum 500 can be replenished to the storage tank 110 through the replenishment line 101. The switch 510 may be, for example, a pump rotary lever capable of pumping a working fluid by rotating a lever by an operator, but the present invention is not limited thereto.

Hereinafter, the operation and effects of the working fluid supply device having the above-described configuration will be described.

The working fluid supply device according to the present embodiment can be connected to the hydraulic cylinder 22 of the upper vertical bearing 20 and lift the roller of the upper vertical bearing 20 by supplying the working fluid to the hydraulic cylinder 22 . To this end, the individual supply line 310 and the individual recovery line 410 may be connected to the hydraulic cylinder 22, respectively.

The remaining valves may be closed to open only the first valve 102 and the air passage valve 104 and drive the pump 120 so that the working fluid is filled in the internal supply line 105 to raise the hydraulic pressure. At this time, when there is no working fluid in the storage tank 110, the operation fluid in the auxiliary drum 500 can be supplemented to the storage tank 110 by operating the switch 510 of the auxiliary drum 500. The amount of residual working fluid in the storage tank 110 may be measured by a flow rate sensor (not shown) provided inside the storage tank 110. In addition, when the pump is driven, the air filter 132 and the air regulator 130 are operated to remove impurities from the air supplied to the pump 120 and adjust the pressure of the air.

The hydraulic pressure can be measured by the pressure gauge 140 while driving the pump 120 to increase the hydraulic pressure in the internal supply line 105. [ When the hydraulic pressure measured by the pressure gauge 140 becomes equal to or higher than a predetermined pressure, the second valve 106 is opened to supply the working fluid to the external supply line 109. Even after the second valve 106 is opened The pump 120 can be continuously driven to prevent the hydraulic pressure from dropping below the predetermined pressure. For this, the operator can monitor the measured value of the pressure gauge 140 in real time and drive the pump 120 accordingly.

The predetermined pressure may be determined as a minimum pressure at which the working fluid is uniformly distributed to each of the hydraulic cylinders 22. If the hydraulic pressure of the working fluid is lower than the predetermined pressure, there is a possibility that the working fluid is delivered to a part of the hydraulic cylinder 22 due to insufficient pressure, so that it may become difficult to uniformly supply the working fluid.

The working fluid passing through the external supply line 109 can be removed while passing through the filter 200 and the working fluid from which the impurities have been removed can flow into the manifold 300 to separate the individual supply lines 310 And can be supplied to each of the hydraulic cylinders 22 via the hydraulic cylinders. When the working fluid is supplied to the hydraulic cylinder 22, the piston of the hydraulic cylinder 22 is pushed by the working fluid and is ejected. As the piston is injected, the roller of the upper vertical bearing 20 rises and pushes up the turret T .

In this case, since the hydraulic pressure of the working fluid supplied to each hydraulic cylinder 22 can be uniform by keeping the hydraulic pressure of the working fluid at a predetermined amount or more as described above, and the hydraulic cylinders 22 are supplied with the uniform hydraulic pressure, Can all be driven by the same amount. Since the hydraulic cylinder 22 is driven by the same amount, the turret T can be stably raised without being tilted.

After lifting the turret (T), the turret (T) can be subjected to a rotating test using a rotating testing machine. When the rotation test is completed, the working fluid supplied to the hydraulic cylinder 22 is recovered to the recovery drum 400 through the individual recovery line 410, so that the piston of the hydraulic cylinder 22 returns to its original position , So that the turret T also descends. To this end, the recovery drum 400 may be provided with a fluid pump (not shown) for recovering working fluid.

When the rotating test is terminated, not only the working fluid which has been supplied to the hydraulic cylinder 22 by closing the second valve 106 and opening the third valve 108 but also the working fluid which has been supplied to the hydraulic cylinder 22, Can also be recovered. For this purpose, the pump 120 may be continuously driven, but may be recovered by a pump provided separately to the recovery drum 400.

As described above, the working fluid supply device according to this embodiment is temporarily connected to the plurality of hydraulic cylinders 22 to supply the working fluid at a uniform hydraulic pressure, thereby stabilizing the turret T during the pre- As shown in Fig.

Although the preferred embodiments of the working fluid supply device according to the present invention have been described above, the present invention is not limited thereto. The present invention is not limited to this, and may be interpreted as having the widest range according to the basic idea disclosed in this specification . Skilled artisans may implement a pattern of features that are not described in a combinatorial and / or permutational manner with the disclosed embodiments, but this is not to depart from the scope of the present invention. It will be apparent to those skilled in the art that various changes and modifications may be readily made without departing from the spirit and scope of the invention as defined by the appended claims.

T: Turret 10:
20: Upper vertical bearing 22: Hydraulic cylinder
100: fluid pump unit 101: supplementary line
102: first valve 103: air passage
104: Air passage valve 105: Internal supply line
106: second valve 107: recovery line
108: Third valve 109: External supply line
110: Storage tank 120: Pump
130: air regulator 132: air filter
140: pressure gauge 200: filter
300: Manifold 310: Individual supply line
400: recovery drum 410: individual recovery line
500: auxiliary drum 510: switch

Claims (13)

A working fluid supply device for supplying a working fluid to a plurality of hydraulic cylinders for adjusting the height of a plurality of upper vertical bearings rotatably supporting a turret installed in a ship,
A fluid pump unit for storing and supplying the working fluid; And
And a manifold that receives the working fluid from the fluid pump unit and distributes the working fluid to the plurality of hydraulic cylinders. The method according to claim 1,
Wherein the manifold uniformly distributes the working fluid to the plurality of hydraulic cylinders. 3. The method of claim 2,
Wherein the fluid pump unit applies pressure to the working fluid over a minimum pressure at which the working fluid is evenly distributed to the plurality of hydraulic cylinders. The method according to claim 1,
Further comprising an external supply line connected to the fluid pump unit and providing a flow path through which the working fluid is delivered to the outside of the fluid pump unit,
The fluid pump unit includes:
An internal supply line for providing a flow path through which the working fluid is transferred within the fluid pump unit;
A pump provided on the internal supply line and for pumping the working fluid;
A pressure gauge for measuring a hydraulic pressure inside the internal supply line; And
And a valve that opens and closes the flow path of the internal supply line. 5. The method of claim 4,
The pressure gauge being provided at a rear end of the pump,
The valve being provided at a rear end of the pressure gauge,
The valve is opened when the hydraulic pressure measured by the pressure gauge is equal to or higher than a predetermined pressure,
Wherein the predetermined pressure is a minimum pressure at which the working fluid is uniformly distributed to the plurality of hydraulic cylinders. 5. The method of claim 4,
The fluid pump unit includes:
And a storage tank connected to the internal supply line and storing the working fluid. 5. The method of claim 4,
The fluid pump unit includes:
An air passage for introducing air from outside into the pump and providing a flow path to the pump;
An air filter provided in the air passage for filtering the air;
An air regulator for controlling the pressure of the air; And
And an air passage valve for opening and closing the air passage. 5. The method of claim 4,
Wherein a filter is provided on the external supply line to filter impurities contained in the working fluid. The method according to claim 1,
And a recovery drum for recovering and storing the working fluid supplied to the hydraulic cylinder. 10. The method of claim 9,
An internal supply line for providing a flow path through which the working fluid is transferred within the fluid pump unit; And
Further comprising a recovery line connected to the internal supply line and recovering the working fluid remaining in the internal supply line when the supply of the working fluid is stopped,
And the recovery line is connected to the recovery drum. The method according to claim 1,
And an auxiliary drum provided outside the fluid pump unit and supplying the working fluid to the fluid pump unit. 12. The method according to any one of claims 1 to 11,
Wherein when the working fluid is supplied to the hydraulic cylinder, the hydraulic cylinder raises the roller of the upper vertical bearing so that the turret is pushed upward. 13. The method of claim 12,
The working fluid is supplied to the hydraulic cylinder before the rotation test of the turret is started,
And the hydraulic pressure of the working fluid supplied from the fluid pump unit is uniformly maintained during the rotating test.

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