KR101774927B1 - Apparatus and method for transferring fluids - Google Patents

Abstract

The present invention discloses a fluid transfer device and a fluid transfer method capable of loading/unloading a fluid to/from a vessel. The fluid transfer device includes: a reservoir water bank having a reservoir water space for storing seawater; a water gate formed in the reservoir water bank, and providing an inlet and an outlet for seawater between the reservoir space and the ocean; a water gate opening/closing device formed in the reservoir water bank, and opening/closing the water gate; and a fluid delivery portion connected between a first floating body on the sea and a second floating body in the reservoir water bank. According to an embodiment of the present invention, the present invention is able to load/unload a fluid to/from a ship by using a range of tide without using a pump.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a fluid transfer apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid transfer device and a fluid transfer method, and more particularly, to a fluid transfer device and a fluid transfer method for loading or unloading fluid into a float floating on the water.

A loading / unloading device is used to transfer the fluid between the ship and the ground. The loading / unloading apparatus can be used, for example, for transporting liquid cargo carried by a ship, wastewater in a ship from the ship to the ground, transporting fuel or liquid to be transported to a ship, or for other various purposes do. Conventional loading / unloading devices transport fluids using a pump.

The present invention provides a fluid transfer apparatus and method capable of loading / unloading a fluid to a ship using a tide generator.

The present invention also provides a fluid transfer apparatus and method capable of loading / unloading fluid to a ship without using a pump.

The problems to be solved by the present invention are not limited to the above-mentioned problems. Other technical subjects not mentioned will be apparent to those skilled in the art from the description below.

According to an aspect of the present invention, there is provided a fluid transfer apparatus comprising: a water storage chamber having a water storage space for storing seawater; A water gate formed in the reservoir and providing an inflow / outflow passage for the seawater between the water storage space and the ocean; A water gate opening / closing device formed in the water storage room for opening and closing the water gate; And a fluid delivery portion connected between the first subfluid floating in the sea and the second subfluid floating in the reservoir chamber.

The water gate opening / closing apparatus can open / close the water gate according to the height of the sea surface according to the tide of the ocean and the height of the sea water stored in the water storage space.

Wherein the water gate opening / closing apparatus comprises: a water inlet opening and closing device for opening the water gate in the tide to introduce seawater into the water storage space during a loading mode in which the fluid is transferred from the second float to the first floating body, The water level of the sea water stored in the water storage space can be made higher than the sea level.

Wherein the water gate opening / closing device comprises: a water inlet opening / closing device for opening / closing the water gate during ebbing mode in which the fluid is transferred from the first subfluid to the second floating object, The water surface of the sea water stored in the water storage space can be made lower than the sea surface by closing the water gate.

The fluid conveyance device includes a first sensor unit for measuring the sea level according to the tide of the ocean; A second sensor unit for measuring a water surface height of the seawater stored in the water storage space; And a controller for controlling the water gate opening / closing apparatus according to the measured values of the first sensor unit and the second sensor unit.

Wherein the fluid transferring portion includes: a fluid transfer tube that transfers a fluid between the first subfluid and the second subfluid and at least a part of which is an extension and contraction tube; And a valve unit installed in the fluid transfer pipe and controlled to be opened and closed according to the measured values of the first sensor unit and the second sensor unit.

According to another aspect of the present invention, there is provided a method of storing seawater in a storage tank, Connecting a fluid delivery portion between a first subfluid floating in the sea and a second subfluid floating in the reservoir chamber; And forming a height difference between the sea water and the sea level stored in the reservoir to transfer fluid between the first and second float through the fluid transfer section.

Transporting the fluid may include: transferring the fluid from the second float to the first float with the height of the seawater stored in the reservoir during ebb being greater than the sea level.

The transferring of the fluid may include: transferring the fluid from the first float to the second float with the height of seawater stored in the reservoir in the tide lower than the sea level.

According to an embodiment of the present invention, there is provided a fluid transfer apparatus and method capable of loading / unloading a fluid to a ship using a tide gauge.

Further, according to the embodiment of the present invention, there is provided a fluid transfer apparatus and method capable of loading / unloading fluid to a ship without using a pump.

The effects of the present invention are not limited to the effects described above. Unless stated, the effects will be apparent to those skilled in the art from the description and the accompanying drawings.

1 is a plan view of a fluid delivery device according to an embodiment of the present invention.
2 is a cross-sectional view taken along the line AA 'in FIG.
3 is an enlarged perspective view of the 'B' portion of FIG.
4 to 7 are views for explaining the operation of the fluid transfer device according to the embodiment of the present invention.

Other advantages and features of the present invention and methods for accomplishing the same will be apparent from the following detailed description of embodiments thereof taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, and the present invention is only defined by the scope of the claims. Although not defined, all terms (including technical or scientific terms) used herein have the same meaning as commonly accepted by the generic art in the prior art to which this invention belongs. A general description of known configurations may be omitted so as not to obscure the gist of the present invention. In the drawings of the present invention, the same reference numerals are used as many as possible for the same or corresponding configurations. To facilitate understanding of the present invention, some configurations in the figures may be shown somewhat exaggerated or reduced.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises", "having", or "having" are intended to specify the presence of stated features, integers, steps, operations, components, Steps, operations, elements, parts, or combinations thereof, whether or not explicitly described or implied by the accompanying claims.

1 is a plan view of a fluid delivery device according to an embodiment of the present invention. 2 is a cross-sectional view taken along line A-A 'in Fig. Referring to FIGS. 1 and 2, the fluid transfer apparatus according to the present invention transfers fluid between vessels using only the tide interval tide. The fluid transfer apparatus includes a reservoir 110, And a second float 20 in the reservoir 110. The first float 110 is connected to the first float 10 and the second float 20 in the reservoir 110. The float 118 is connected to the float 118, Fuel, raw material, water, wastewater, etc.).

The water storage room (110) has a water storage space (110a) for storing seawater. The water storage room (110) may be provided so that one side wall is in contact with the sidewall side and the other side wall is in contact with the ocean side. The water storage chamber 110 may be provided in a form of surrounding the water storage space 110a in all directions. The bottom surface of the water storage tank 110 may be provided so as to have a lower height than the sea surface during the low water level. The reservoir bank 110 may be provided to have a height higher than the sea level during high tide. The water surface of the seawater introduced into the water storage tank 110 may have a height between the sea surface during the low water level and the sea surface during the high water level.

The water gate 118 provides a flow path for the sea water between the water storage space 110a and the ocean. The water gates 118 may be formed through the marine sidewalls of the water storage basin 110. The water gate 118 is connected to the wall of the water storage chamber 110 so that seawater flows into the water storage space 110a during high tide and seawater flows into the water side in the water storage space 110a at low tide, And may be formed on the lower side.

The water gate opening and closing devices 112 and 114 are formed in the water storage room 110 to open and close the water gate 118. In one embodiment, the water gate opening / closing apparatus may include an opening / closing door 112 for opening / closing the water gate 118 and a driving unit 114 for driving the opening / closing door 112. The reservoir chamber 110 may include a groove portion 110b through which the opening and closing door 112 can slide and a guide portion through which the movement of the opening and closing door 112 is guided within the groove portion 110b . The driving unit 114 can elevate and lower the opening / closing door 112 by various driving methods such as a rack / pinion, a hydraulic cylinder, and a hydraulic motor. In the illustrated example, the opening / closing door 112 is installed to move up and down, but may be changed to a structure such as moving in the horizontal direction and opening / closing the water gate 118.

When the water gate 118 is opened, that is, when the opening / closing door 112 rises, seawater flows into the water storage space 110a through the water gate 118 at the time of tide, and seawater in the water storage space 110a flows into the water gate 118 ) To the ocean. In one embodiment, the water gate opening / closing apparatuses 112 and 114 can open and close the water gate 118 according to the height of the sea surface according to the tide of the ocean and the water surface height of the sea water stored in the water storage space 110a.

The water gate opening and closing devices 112 and 114 can open and close the water gate 118 such that a difference in height is generated between the water surface of the sea water flowing into the water storage space 110a and the sea surface. In one embodiment, in the loading mode for transferring fluid from the second fluid 20 to the first fluid 20, the fluid is forced to flow from the second fluid 20 to the first fluid 20 by self- The water gate opening and closing devices 112 and 114 open the water gate 118 in the tide to introduce the seawater into the water storage space 110a so that the water can be transported to the fluid 10, Can be made higher than sea level.

In one embodiment, in the unloading mode in which fluid is transferred from the first fluid 10 to the second fluid 20, the fluid is forced to flow from the first fluid 10 to the second fluid 20 by self- The water gate opening and closing devices 112 and 114 open the water gates 118 in the ebb and tide to discharge the seawater from the water storage space 110a and close the water gates 118 in the tide, ) Can be lower than the sea level.

The fluid transfer part 120 and 130 includes a first fluid transfer part 120 for transferring (loading) the fluid from the second fluid 20 to the first fluid 10, And a second fluid delivery portion 130 for transferring (unloading) the fluid to the fluid 20. The first fluid transferring part 120 and the second fluid transferring part 130 may include fluid transferring pipes 122 and 132 and valve parts 150 and 160 installed in the fluid transferring pipes 122 and 132.

The fluid transfer tubes 122 and 132 are connected to the first fluid reservoir 12 of the first fluid reservoir 10 and the second fluid reservoir 22 of the second fluid reservoir 20, At least a part of which can be provided to the expansion and contraction pipes 124, 126, 134 and 136 so as to correspond to the height variation of the first fluid 10 and the second fluid 20 according to the tide. The expansion and contraction pipes 124, 126, 134, and 136 may be provided by a bellows pipe or the like.

3 is an enlarged perspective view of the 'B' portion of FIG. Referring to FIGS. 2 and 3, a support member 116 is formed in the reservoir 110 for supporting the fluid transfer parts 120 and 130. The support member 116 is formed on the upper surface of the reservoir chamber 110 and supports the first fluid transfer pipe 122 for fluid loading into the first fluid unit 10 on the upper side and the first fluid unit 10 The second fluid transfer tube 132 for fluid unloading from the second fluid transfer tube 132 is supported on the lower side.

The first fluid transfer tube 122 is inserted into and supported by the upper side through hole 116a of the support member 116 and the second fluid transfer tube 132 is inserted into the lower side through hole 116b of the support member 116, As shown in Fig. The fluid conveyance pipes 122 and 132 are formed in the through holes (not shown) so that the angles of the fluid conveyance pipes 122 and 132 can be changed due to the height variations of the first and second submerged fluids 10 and 20, 116b may be provided as bent portions 122a, 132a such as corrugated pipes. The first float 10 is provided with a first support 14 and the second float 20 is provided with a second support 24 to support the distal end of the fluid transfer tubes 120 and 130. The first support portion 14 and the second support portion 24 may be provided in a structure similar to the support member 116. [ The fluid transfer pipes 122 and 132 may be provided in a horizontal direction when the float 10 or 20 is located at the maximum height or may be provided so as to be inclined downward from the distal end toward the support member 116.

The sensor unit 140 may be provided to measure the sea level according to the tide of the ocean and the sea level of the sea water stored in the water storage space 110a. The sensor unit 140 may be provided with a fluid sensor or various means capable of detecting the height of the water surface. The sensor unit 140 includes a first sensor unit 142 and a second sensor unit 144 for measuring the sea level according to the tide of the ocean and a second sensor unit 144 and 148 for measuring the sea level of the sea water stored in the water storage space 110a. ).

In one embodiment, the first sensor portion 142, 146 may include a first upper sensor 142 for detecting high tide and a first lower sensor 146 for detecting low tide. The second sensor units 144 and 148 may include a second upper sensor 144 installed on the inner wall of the upper end of the water storage tank 110 to have the same height as that of the first upper sensor 142, And a second lower sensor 148 installed on the inner wall of the lower end side to have the same height as the first lower sensor 146.

The upper sensors 142 and 144 may be installed at the same height as the sea level during high tide or lower than the sea level during high tide and higher than the lower sensors 146 and 148. The lower sensors 146 and 148 may be installed at the same height as the sea level at the time of low tide or may be installed at a position higher than the sea level at the time of low tide and lower than the upper sensors 142 and 144. The controller (not shown) can control the opening and closing of the valve units 150 and 160 and the driving of the water gate switching units 112 and 114 according to the measured values of the first sensor units 142 and 146 and the second sensor units 144 and 148.

4 to 7 are views for explaining the operation of the fluid transfer device according to the embodiment of the present invention. First, the process of transferring (loading) the fluid from the second fluid 20 to the first fluid 10 will be described with reference to FIGS. 4 and 5. FIG. 4, seawater is sensed by the first upper sensor 142, and the water gate 118 of the water reservoir 110 is opened to increase the water level of the water reservoir 110. As shown in FIG. Accordingly, the seawater is introduced from the ocean into the water storage room 110 through the water gate 118, and the water level of the water storage room 110 is increased.

When the seawater is sensed by the second upper sensor 144, the water gate 118 is closed so that the water level of the water reservoir 110 is not lowered while the fresh water is changing to ebb. The seawater is not detected in the first upper sensor 142 while the tide is changing from tide to ebb. At this time, the height of the first fluid 10 becomes lower than that of the second fluid 20, so that the first fluid transfer tube 122 is moved downward from the second fluid 20 toward the first fluid 10 Tilted. 5, when a height difference is formed between the sea water and the sea surface stored in the reservoir chamber 110a, the first valve portion 150 of the first fluid conveyance pipe 122 is opened, and the fluid Is loaded into the first fluid (10) from the second fluid (20). When the fluid loading is completed, the first valve portion 150 is closed.

Next, the process of transferring (unloading) the fluid from the first sub-fluid 10 to the second sub-fluid 20 will be described with reference to FIGS. 6 and 7. FIG. 6, the seawater is not sensed by the first lower sensor 146 and the water gate 118 of the water reservoir 110 is opened to lower the water level of the water reservoir 110. As a result, do. Accordingly, the seawater is discharged from the water storage chamber 110 to the ocean through the water gate 118, and the water level of the water storage chamber 110 is lowered.

When the seawater is not detected by the second lower sensor 148 as the water level of the water storage tank 110 is lowered, the water level of the water storage tank 110 is not increased during the change of tide water, The water gate 118 is closed. The seawater is detected at the first lower sensor 146 while the fresh water changes from the low tide to the tide, and when the tide time comes, the first upper sensor 142 detects the seawater. 7, the height of the first fluid 10 is higher than that of the second fluid 20, and the second fluid 20 is directed from the first fluid 10 to the second fluid 20. In this case, (132) is inclined downward.

When the height difference between the sea water and the sea surface stored in the water storage tank 110a is formed as described above, the first valve portion 160 of the second fluid transfer pipe 132 is opened, Is unloaded from the float (10) to the second float (20). When the fluid unloading is completed, the second valve portion 160 is closed. When the fluid is unloaded into the second fluid reservoir 22 of the second fluid 20, the second fluid reservoir 22 is again filled with seawater in the reservoir bank 110, To the transportation means 30, and can be transported to the destination.

According to the embodiment of the present invention, the fluid can be transferred between the vessels by the weight of the fluid without using the pump by using the difference between the tides. Therefore, the cost of driving the pump can be reduced, and the fluid transportation cost can be reduced by utilizing the auxiliary water for fluid transportation. According to the embodiment of the present invention, since the lengths of the fluid conveyance pipes 122 and 132 are changed by the expansion and contraction pipes 124, 126, 134, and 136, As shown in FIG.

It is to be understood that the above-described embodiments are provided to facilitate understanding of the present invention, and do not limit the scope of the present invention, and it is to be understood that various modifications are possible within the scope of the present invention. It is to be understood that the technical scope of the present invention should be determined by the technical idea of the claims and the technical scope of protection of the present invention is not limited to the literary description of the claims, To the invention of the invention.

10: first fluid 12: first fluid storage part
14: first support part 20: second part fluid
22: second fluid storage part 24: second support part
110: Reservoir bank 110a: Reservoir space
110b: groove portion 112: opening / closing door
114: driving part 116: supporting member
118: Water gate 120: First fluid conveying part
122: first fluid conveying pipe 122a: first bending part
124, 126: first extension pipe 130: second fluid transfer part
132: second fluid conveying pipe 132a: second bending portion
134, 136: second extension pipe 140:
142: first upper sensor 144: second upper sensor
146: first lower sensor 148: second lower sensor
150: first valve unit 160: second valve unit

Claims (9)

A reservoir having a water storage space for storing seawater;
A water gate formed in the reservoir and providing an inflow / outflow passage for the seawater between the water storage space and the ocean;
A water gate opening / closing device formed in the water storage room for opening and closing the water gate; And
And a fluid transferring portion connected between the first sub-fluid floating in the sea and the second sub-fluid floating in the water storage chamber,
The water gate opening / closing apparatus comprises:
In the loading mode in which the fluid is transferred from the second float to the first floating body, seawater is introduced into the water storage space by opening the water gate in the tide and the water gate is closed while changing from tide to ebb, A fluid conveyance device for making stored sea water higher than sea level. The method according to claim 1,
Wherein the water gate opening / closing device opens / closes the water gate according to the height of the sea surface according to the tide of the ocean and the water surface height of the sea water stored in the water storage space. delete A reservoir having a water storage space for storing seawater;
A water gate formed in the reservoir and providing an inflow / outflow passage for the seawater between the water storage space and the ocean;
A water gate opening / closing device formed in the water storage room for opening and closing the water gate; And
And a fluid transferring portion connected between the first sub-fluid floating in the sea and the second sub-fluid floating in the water storage chamber,
Wherein the water gate opening / closing device opens and closes the water gate according to the height of the sea surface according to the tide of the ocean and the water surface height of the sea water stored in the water storage space,
The water gate opening / closing apparatus comprises:
In an unloading mode in which fluid is transferred from the first sub-fluid to the second floating body,
Wherein the water gate is opened during low tide to discharge seawater from the water storage space and closing the water gate while changing from low to low tide to make the water surface of the sea water stored in the water storage space lower than the sea surface. The method according to any one of claims 1, 2, and 4,
A first sensor unit for measuring the sea level according to the tide of the ocean;
A second sensor unit for measuring a water surface height of the seawater stored in the water storage space; And
And a control device for controlling the water gate opening / closing device according to the measured values of the first sensor part and the second sensor part. A reservoir having a water storage space for storing seawater;
A water gate formed in the reservoir and providing an inflow / outflow passage for the seawater between the water storage space and the ocean;
A water gate opening / closing device formed in the water storage room for opening and closing the water gate;
A fluid conveyance part connected between a first sub-fluid floating in the sea and a second sub-fluid floating in the water storage room;
A first sensor unit for measuring the sea level according to the tide of the ocean;
A second sensor unit for measuring a water surface height of the seawater stored in the water storage space; And
And a controller for controlling the water gate opening / closing apparatus according to the measured values of the first sensor unit and the second sensor unit,
Wherein the fluid transferring portion comprises:
A fluid conveyance pipe for conveying the fluid between the first and second subsidiary fluids and at least a part of which is made up of an expansion and contraction tube; And
And a valve unit installed in the fluid transfer pipe and controlled to be opened and closed according to the measured values of the first sensor unit and the second sensor unit. Storing seawater in a reservoir;
Connecting a fluid delivery portion between a first subfluid floating in the sea and a second subfluid floating in the reservoir chamber; And
Forming a height difference between the sea water and the sea level stored in the reservoir to transfer fluid between the first and second float through the fluid transfer portion. 8. The method of claim 7,
Transferring the fluid comprises:
And transporting the fluid from the second float to the first float by elevating the height of the seawater stored in the reservoir to a level higher than the sea level. 9. The method according to claim 7 or 8,
Transferring the fluid comprises:
And transporting the fluid from the first float to the second float with the height of the seawater stored in the reservoir lower than the sea level.

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