Recovery and re-use of waste energy in industrial facilities

The invention claimed is: 1. A method implemented in a crude oil refining facility, the method comprising: heating a first plurality of streams in a first plurality of plants in a crude oil facility using a second plurality of streams in a second plurality of plants in the crude oil refining facility using a plurality of heat exchangers that receive at least one of the first plurality of streams and at least one of the second plurality of streams, wherein the first plurality of plants comprises an amine regeneration plant comprising an acid gas regenerator bottoms stream comprising a weak amine salt, an aromatics complex benzene extraction unit benzene column bottoms stream, a raffinate column bottom stream, a naphtha splitter column bottom stream, the aromatics complex comprising at least one of benzene, toluene or xylene, a sour water stripper plant comprising a stripper bottom stream, a sulfur recovery plant comprising an amine regenerator bottoms stream, a gas separation plant comprising a C3/C4 splitter column bottom stream and a de-ethanizer column bottoms stream, wherein a stream in the gas separation plant comprises at least one of C2 to C4 flows, and wherein the second plurality of plants comprises an aromatics plant xylene products separation unit comprising a raffinate column overheads stream and an extract column overheads stream, a hydrocracking plant comprising a second stage reaction cold high pressure separator, a product stripper stream, a diesel product stream, a kerosene product cooling stream from a main fractionator column, a kerosene pumparound stream, a first stage reaction feed stream to a cold high pressure separator, and a diesel hydro-treating plant. 2. The method of claim 1 , wherein heating the first plurality of streams comprises directly heating the first plurality of streams using the second plurality of streams. 3. The method of claim 2 , wherein directly heating the stream comprises: heating, in a first heat exchanger, the acid gas regenerator bottoms stream in the amine regeneration plant using a branch of raffinate column overheads stream in the aromatics plant xylene products separation unit; heating, in a second heat exchanger, a branch of the stripper bottom stream in the sour water stripper plant using a diesel stripper bottom stream in the diesel hydro-treating plant; heating, in a third heat exchanger, a branch of the stripper bottom stream using a branch of the extract column overheads stream in the aromatics plant xylene products separation unit; heating, in a fourth heat exchanger, a branch of the amine regenerator bottoms stream in the sulfur recovery plant using a feed stream to a first stage reaction cold high pressure separator; heating, in a fifth heat exchanger, a branch of the C3/C4 splitter column bottom stream in the gas separation plant using the diesel stripper bottom stream exiting the second heat exchanger; heating, in a sixth heat exchanger, a branch of the de-ethanizer column bottoms stream in the gas separation plant using the diesel stripper bottom stream exiting the fifth heat exchanger; heating, in a seventh heat exchanger, a branch of the benzene column bottoms stream in the aromatics complex benzene extraction unit using a branch of the raffinate column overheads stream; and heating, in an eighth heat exchanger, a branch of the raffinate column bottom stream in the aromatics complex benzene extraction unit using a feed stream to the second stage reaction cold high pressure separator in the hydrocracking plant. 4. The method of claim 3 , wherein the first heat exchanger and the seventh heat exchanger are fluidically coupled to each other in parallel, wherein the second heat exchanger, the fifth heat exchanger and the sixth heat exchanger are fluidically coupled to each other in series, wherein the second heat exchanger and the third heat exchanger are fluidically coupled to each other in parallel. 5. The method of claim 4 , wherein the heat exchanger, the heat exchanger B, the heat exchanger C, the heat exchanger D, the heat exchanger E and the heat exchanger F are fluidically coupled to each other in parallel, wherein the heat exchanger B and a combination of the first heat exchanger and the seventh heat exchanger are fluidically coupled to each other in series. 6. The method of claim 3 , wherein directly heating the stream comprises: heating, in heat exchanger A, a branch of the naphtha splitter column bottoms stream using a diesel stripper overhead stream in the diesel hydro-treating plant; heating, in heat exchanger B, a branch of the naphtha splitter column bottom stream in the aromatics complex benzene extraction unit using the raffinate column overheads stream; heating, in heat exchanger C, a branch of the naphtha splitter bottoms stream using the product stripper stream in the hydrocracking plant; heating, in heat exchanger D, a branch of the naphtha splitter bottoms stream using the diesel product stream in the hydrocracking plant; heating, in heat exchanger E, a branch of the naphtha splitter bottoms stream using the kerosene product cooling stream from the main fractionator column in the hydrocracking plant; and heating, in heat exchanger F, a branch of the naphtha splitter bottoms stream using the kerosene pumparound stream in the hydrocracking plant. 7. The method of claim 6 , wherein the branches of the naphtha splitter bottoms stream are flowed in parallel to the heat exchanger A, the heat exchanger B, the heat exchanger C, the heat exchanger D, the heat exchanger E and the heat exchanger F. 8. The method of claim 6 further comprising: flowing the branches of the heated naphtha splitter bottoms stream to the aromatics complex benzene extraction unit; flowing the branches of the branches of the heated stripper bottom stream to the sour water stripper plant; flowing the branches of the heated C3/C4 splitter bottom streams and the de-ethanizer column bottoms stream to the gas separation plant; flowing the branches of the heated amine regenerator bottoms stream to the sulfur recovery plant; and flowing the branches of the heated acid gas regenerator bottoms streams to the amine regeneration plant. 9. The method of claim 1 , wherein heating the first plurality of streams comprises indirectly heating the first plurality of streams using the second plurality of streams. 10. The method of claim 9 , wherein the buffer fluid comprises at least one of oil or water. 11. The method of claim 9 , wherein heating the first plurality of streams comprises indirectly heating the first plurality of streams through a buffer fluid using the second plurality of streams. 12. The method of claim 11 , wherein indirectly heating the first plurality of streams through the buffer fluid comprises: heating, in a first heat exchanger, a branch of the buffer fluid using a raffinate column overheads stream; heating, in a second heat exchanger, a branch of the buffer fluid using the extract column overheads stream in the aromatics plant xylene products separation unit; heating, in a third heat exchanger, a branch of the buffer fluid using the first stage reaction feed stream to a cold high pressure separator in the hydrocracking plant; and collecting the branches of the heated buffer fluid in a buffer fluid collection header. 13. The method of claim 12 , wherein the first heat exchanger, the second heat exchanger and the third heat exchanger are fluidically coupled to each other in parallel. 14. The method of claim 13 , further comprising directly heating the stream, wherein directly heating the stream comprises: heating, in heat exchanger A, a branch of the naphtha sp