1. A coastal electric power generating station with one or more nuclear reactor powered generating units for operation and situation offshore on a floor of a large body of water, comprising:
at least one unmanned buoyant submersible hull structure comprising a containment for nuclear steam and electricity generators;
at least one mooring element removably attached to said at least one unmanned buoyant submersible hull structure, said at least one mooring element being adapted to moor said at least one unmanned buoyant submersible hull structure to said floor; and
a surface facility disposed above and isolated by said large body of water from said at least one buoyant submersible hull structure and said at least one mooring element, said surface facility controlling the operation of said one or more nuclear reactor powered generating units including said at least one mooring element and said at least one unmanned buoyant submersible hull structure.
2. The station of claim 1, said at least one mooring element further comprising at least one seafloor element and at least one controllable restraining element mounted thereon,
said at least one controllable restraining element being adapted to permit controlled variation of the relationship between said seafloor element and said buoyant submersible hull structure.
3. The station of claim 2, wherein said at least one seafloor element comprises a gravity mat; and
said at least one controllable restraining element comprises at least one installed winch, vertical cable and buoy system.
4. The station of claim 3, wherein said at least one controllable restraining element comprises a plurality of said installed winch, vertical cable and buoy systems disposed around and within the periphery of said gravity mat and adapted to control said at least one buoyant submersible hull structure’s ascent and descent.
5. The station of claim 1, further comprising a tensioning system for maintaining cable tension on a plurality of vertical cables removably attached to said buoyant submersible hull structure, comprising:
a plurality of winches driven by, or reversely, driving a fluid, said winches being coupled to respective elements of said vertical cables,
at least one pair of manifolds adapted to distribute said fluid under pressure to and between said plurality of winches;
at least one hydraulic pump unit coupled to said at least one pair of manifolds, said at least one pump adapted to discharge said fluid under pressure to at least a portion of said winches for reeling in thereof; and
at least one flow resisting subsystem coupled to said at least one pair of manifolds, said at least one flow resisting subsystem adapted to receive said fluid under pressure from said plurality of winches for reeling out thereof;
wherein said fluid under pressure is distributed to and between said winches substantially in proportion to said tension placed on each winch by its respective cable.
6. The station of claim 5, wherein said fluid driven winches removably attached to said buoyant submersible hull structure are adapted for submerging said buoyant submersible hull structure and setting said buoyant submersible hull structure’s operating depth.
7. The station of claim 5, wherein at least a portion of said winches are adapted to balance the tension applied to each said winch by its respective cable by driving fluid through said at least one pair of manifolds to or from other ones of said winches.
8. The station of claim 5, wherein said winches flow resistant subsystem is adapted to control the surfacing of said buoyant submersible hull structure.
9. The station of claim 1, wherein said at least one buoyant submersible hull structure containing nuclear steam and electricity generators comprises:
a frame comprising a plurality of beams and tubes;
said beams adapted to intersect and support partial domes forming the shell of said buoyant submersible hull structure; and
said tubes interconnected to support a plurality of columns of said buoyant submersible hull structure;
wherein all of said beams are of substantially the same size.
10. The station of claim 9, wherein said partial domes forming said shell of said buoyant submersible hull structure are smaller than said buoyant submersible hull structure.
11. The station of claim 9, wherein said partial domes transfer heat from the interior of said buoyant submersible hull structure to seawater.
12. The station of claim 9, wherein said plurality of tubes interconnected to support columns are open at both ends to free flood and allow warmed seawater to rise and exhaust.
13. A coastal electric power generating station with one or more nuclear reactor powered generating units for operation and situation offshore on a floor of a large body of water, comprising:
at least one unmanned buoyant submersible hull structure comprising a containment for nuclear steam and electricity generators;
at least one mooring element removably attached to said at least one unmanned buoyant submersible hull structure, said at least one mooring element being adapted to moor said at least one unmanned buoyant submersible hull structure to said floor via a plurality of cables and further adapted to balance the tension of said plurality of cables between said unmanned buoyant submersible hull structure and said mooring element; and
control means to control one or more aspects of said unmanned buoyant submersible hull structure disposed above and isolated by said large body of water from said at least one buoyant submersible hull structure and said at least one mooring element.
14. A coastal electric power generating station with one or more nuclear reactor powered generating units for operation and situation offshore on a floor of a large body of water, comprising:
at least one unmanned buoyant submersible hull structure comprising a containment for nuclear steam and electricity generators;
at least one mooring element attached to said at least one unmanned buoyant submersible hull structure, said at least one mooring element further comprising at least one seafloor element and at least one controllable restraining element mounted thereon, said at least one controllable restraining element being adapted to permit controlled variation of the relationship between said at least one seafloor element and said at least one unmanned buoyant submersible hull structure;
control means to control one or more aspects of said unmanned buoyant submersible hull structure disposed above and isolated by said large body of water from said at least one buoyant submersible hull structure and said at least one mooring element; and
a tensioning system for maintaining cable tension on a plurality of vertical cables removably attached to said at least one unmanned buoyant submersible hull structure, comprising:
a plurality of winches driven by, or reversely driving, a fluid, and wherein each of said plurality of winches are coupled to respective elements of said vertical cables,
at least one pair of manifolds adapted to distribute said fluid under pressure to and between said plurality of winches;
at least one hydraulic pump unit coupled to said at least one pair of manifolds, said at least one pump adapted to discharge said fluid under pressure to at least a portion of said plurality of winches for reeling in thereof; and
at least one flow resisting subsystem coupled to said at least one pair of manifolds, said at least one flow resisting subsystem adapted to receive said fluid under pressure from said plurality of winches for reeling out thereof;
wherein said fluid under pressure is distributed to and between said plurality of winches substantially in proportion to said tension placed on each of said plurality of winches by its respective cable;
wherein at least a portion of said plurality of winches are adapted to balance the tension applied to each of said winches by its respective cable by driving fluid through said at least one pair of manifolds to or from other ones of said plurality of winches.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. A method for manufacturing a display device, comprising:
forming a metal layer on a first substrate;
disposing a second substrate on the metal layer;
supplying a current to the metal layer to heat the metal layer; and
separating the secondsubstrate from the metal layer and the first substrate.
2. The method of claim 1, wherein the metal layer comprises at least one of titanium, magnesium, zirconium, hafnium, and aluminum.
3. The method of claim 1, wherein a thickness of the metal layer is in a range of 10 \u03bcM to 50 \u03bcm.
4. The method of claim 3, wherein the thickness of the metal layer is in a range of 20 \u03bcM to 40 \u03bcm.
5. The method of claim 1, further comprising,
before the second substrate is disposed on the metal layer,
depositing a gas inflow blocking agent on the metal layer in a region where a circumference of the second substrate is to be disposed.
6. The method of claim 5, wherein the gas inflow blocking agent comprises a heat resistive resin.
7. The method of claim 6, wherein the heat resistive resin comprises at least one of a phenyl methyl silicon resin and a polyimide.
8. The method of claim 5, wherein a deposition thickness of the gas inflow blocking agent is in a range of 10 \u03bcm to 40 \u03bcm.
9. The method of claim 8, wherein the deposition thickness of the gas inflow blocking agent is in a range of 15 \u03bcm to 25 \u03bcm.
10. The method of claim 5, wherein the second substrate is disposed on the metal layer within a circumference of the deposited gas inflow blocking agent.
11. The method of claim 6, further comprising, after the second substrate is disposed on the metal layer, curing the gas inflow blocking agent.
12. The method of claim 11, wherein curing the gas inflow blocking agent comprises heating.
13. The method of claim 12, wherein the gas inflow blocking agent is heated in a range of 100\xb0 C. to 300\xb0 C.
14. The method of claim 13, wherein the gas inflow blocking agent is heated in a range of 130\xb0 C. to 250\xb0 C.
15. The method of claim 14, wherein the gas inflow blocking agent is heated in a range of 5 to 40 minutes.
16. The method of claim 15, wherein the gas inflow blocking agent is heated in a range of 10 to 30 minutes.