Single-working-medium vapor combined cycle
Abstract
The single-working-medium vapor combined cycle is provided in this invitation and belongs to the field of energy and power technology. A single-working-medium vapor combined cycle consists of seven processes which are conducted with M1 kg of working medium and M2 kg of working medium separately or jointly: a pressurization process 1-2 of M1 kg of working medium, a heat-absorption and vaporization process 2-3 of M1 kg of working medium, a pressurization process 6-3 of M2 kg of working medium, a heat-absorption process 3-4 of M3 kg of working medium, a depressurization process 4-5 of M3 kg of working medium, a heat-releasing process 5-6 of M3 kg of working medium, and a heat-releasing and condensation process 6-1 of M1 kg of working medium, M3 is the sum of M1 and M2.
Claims
exact text as granted — not AI-modifiedWhat is claimed is:
1 . A single-working-medium vapor combined cycle method consisting of seven processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state ( 2 ) to ( 3 ) of the M 1 kg of working medium, performing a pressurization process to set a state ( 6 ) to ( 3 ) of the M 2 kg of working medium, performing a heat-absorption process to set the state ( 3 ) to ( 4 ) of the M 3 kg of working medium, performing a depressurization process to set the state ( 4 ) to ( 5 ) of the M 3 kg of working medium, performing a heat-releasing process to set the state ( 5 ) to ( 6 ) of the M 3 kg of working medium, and performing a heat-releasing and condensation process to set the state ( 6 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .
2 . A single-working-medium vapor combined cycle method consisting of eight processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state ( 2 ) to ( 3 ) of the M 1 kg of working medium, performing a depressurization process to set the state ( 3 ) to ( 5 ) of the M 1 kg of working medium, performing a pressurization process to set a state ( 7 ) to ( 4 ) of the M 2 kg of working medium, performing a heat-absorption process to set the state ( 4 ) to ( 5 ) of the M 2 kg of working medium, performing a depressurization process to set the state ( 4 ) to ( 5 ) of the M 3 kg of working medium, performing a heat-releasing process to set a state ( 6 ) to ( 7 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 7 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .
3 . A single-working-medium vapor combined cycle method consisting of eight processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state ( 2 ) to ( 5 ) of the M 1 kg of working medium, performing a pressurization process to set a state ( 7 ) to ( 3 ) of the M 2 kg of working medium, performing a heat-absorption process to set the state ( 3 ) to ( 4 ) of the M 2 kg of working medium, performing a depressurization process to set the state ( 4 ) to ( 5 ) of the M 2 kg of working medium, performing a depressurization process to set the state ( 5 ) to ( 6 ) of the M 3 kg of working medium, performing a heat-releasing process to set the state ( 6 ) to ( 7 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 7 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .
4 . A single-working-medium vapor combined cycle method consisting of nine processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state ( 2 ) to ( 3 ) of the M 1 kg of working medium, performing a depressurization process to set the state ( 3 ) to ( 7 ) of the M 1 kg of working medium, performing a pressurization process to set a state ( 8 ) to ( 4 ) of the M 2 kg of working medium, performing a heat-absorption process to set the state ( 4 ) to ( 5 ) of the M 2 kg of working medium, performing a depressurization process to set the state ( 5 ) to ( 6 ) of the M 2 kg of working medium, performing a heat-releasing process to set the state ( 6 ) to ( 7 ) of the M 2 kg of working medium, performing a heat-releasing process to set the state ( 7 ) to ( 8 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 8 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .
5 . A single-working-medium vapor combined cycle method consisting of nine processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state ( 2 ) to ( 3 ) of the M 1 kg of working medium, performing a depressurization process to set the state ( 3 ) to ( 4 ) of the M 1 kg of working medium, performing a heat-releasing process to set the state ( 4 ) to ( 7 ) of the M 1 kg of working medium, performing a pressurization process to set a state ( 8 ) to ( 5 ) of the M 2 kg of working medium, performing a heat-absorption process to set the state ( 5 ) to ( 6 ) of the M 2 kg of working medium, performing a depressurization process to set the state ( 6 ) to ( 7 ) of the M 2 kg of working medium, performing a heat-releasing process to set the state ( 7 ) to ( 8 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 8 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .
6 . A single-working-medium vapor combined cycle method consisting of ten processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state ( 2 ) to ( 3 ) of the M 1 kg of working medium, performing a pressurization process to set the state ( 8 ) to ( 3 ) of the M 2 kg of working medium, performing a heat-absorption process to set the state ( 3 ) to ( 4 ) of the M 3 kg of working medium, performing a depressurization process to set the state ( 4 ) to ( 7 ) of the X kg of working medium, performing a heat-absorption process to set a state ( 4 ) to ( 5 ) of the (M 3 −X) kg of working medium, performing a depressurization process to set the state ( 5 ) to ( 6 ) of the (M 3 −X) kg of working medium, performing a heat-releasing process to set the state ( 6 ) to ( 7 ) of the (M 3 −X) kg of working medium, performing a heat-releasing process to set the state ( 7 ) to ( 8 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 8 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .
7 . A single-working-medium vapor combined cycle method consisting of ten processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption process to set the state ( 2 ) to (b) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state (b) to ( 3 ) of the of (M 1 +M) kg of working medium, performing a pressurization process to set a state ( 6 ) to (a) of the M 2 kg of working medium, performing a heat-releasing and condensation process to set the state (a) to (b) of the M kg of working medium, performing a pressurization process to set a state (a) to ( 3 ) of the (M 2 −M) kg of working medium, performing a heat-absorption process to set the state ( 3 ) to ( 4 ) of the M 3 kg of working medium, performing a depressurization process to set the state ( 4 ) to ( 5 ) of the M 3 kg of working medium, performing a heat-releasing process to set the state ( 5 ) to ( 6 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 6 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .
8 . A single-working-medium vapor combined cycle method consisting of eleven processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption process to set the state ( 2 ) to (b) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state (b) to ( 3 ) of the of (M 1 +M) kg of working medium, performing a depressurization process to set the state ( 3 ) to ( 5 ) of the (M 1 +M) kg of working medium, performing a pressurization process to set a state ( 7 ) to (a) of the M 2 kg of working medium, performing a heat-releasing and condensation process to set the state (a) to (b) of the M kg of working medium, performing a pressurization process to set a state (a) to ( 4 ) of the (M 2 −M) kg of working medium, performing a heat-absorption process to set the state ( 4 ) to ( 5 ) of the (M 2 −M) kg of working medium, performing a depressurization process to set the state ( 4 ) to ( 5 ) of the M 3 kg of working medium, performing a heat-releasing process to set the state ( 6 ) to ( 7 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 7 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .
9 . A single-working-medium vapor combined cycle method consisting of eleven processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption process to set the state ( 2 ) to (b) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state (b) to ( 5 ) of the of (M 1 +M) kg of working medium, performing a pressurization process to set a state ( 7 ) to (a) of the M 2 kg of working medium, performing a heat-releasing and condensation process to set the state (a) to (b) of the M kg of working medium, performing a pressurization process to set the state (a) to ( 3 ) of the (M 2 −M) kg of working medium, performing a heat-absorption process to set the state ( 3 ) to ( 4 ) of the (M 2 −M) kg of working medium, performing a depressurization process to set the state ( 4 ) to ( 5 ) of the (M 2 −M) kg of working medium, performing a depressurization process to set the state ( 4 ) to ( 5 ) of the M 3 kg of working medium, performing a heat-releasing process to set the state ( 6 ) to ( 7 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 7 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .
10 . A single-working-medium vapor combined cycle method consisting of twelve processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption process to set the state ( 2 ) to (b) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state (b) to ( 3 ) of the of (M 1 +M) kg of working medium, performing a depressurization process to set the state ( 3 ) to ( 7 ) of the (M 1 +M) kg of working medium, performing a pressurization process to set a state ( 8 ) to (a) of the M 2 kg of working medium, performing a heat-releasing and condensation process to set the state (a) to (b) of the M kg of working medium, performing a pressurization process to set a state (a) to ( 4 ) of the (M 2 −M) kg of working medium, performing a heat-absorption process to set the state ( 4 ) to ( 5 ) of the (M 2 −M) kg of working medium, performing a depressurization process to set the state ( 4 ) to ( 5 ) of the (M 2 −M) kg of working medium, performing a heat-releasing process to set the state ( 6 ) to ( 7 ) of the (M 2 −M) kg of working medium, performing a heat-releasing process to set the state ( 7 ) to ( 8 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 8 ) to ( 1 ) of the M 1 kg of working medium, M 3 is a sum of M 1 and M 2 .
12 . A single-working-medium vapor combined cycle method consisting of twelve processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption process to set the state ( 2 ) to (b) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state (b) to ( 3 ) of the of (M 1 +M) kg of working medium, performing a depressurization process to set the state ( 3 ) to ( 4 ) of the (M 1 +M) kg of working medium, performing a heat-releasing process to set the state ( 4 ) to ( 7 ) of the (M 1 +M) kg of working medium, performing a pressurization process to set a state ( 8 ) to (a) of the M 2 kg of working medium, performing a heat-releasing and condensation process to set the state (a) to (b) of the M kg of working medium, performing a pressurization process to set a state (a) to ( 5 ) of the (M 2 −M) kg of working medium, performing a heat-absorption process to set the state ( 5 ) to ( 6 ) of the (M 2 −M) kg of working medium, performing a depressurization process to set the state ( 6 ) to ( 7 ) of the (M 2 −M) kg of working medium, performing a heat-releasing process to set the state ( 7 ) to ( 8 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 8 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .
12 . A single-working-medium vapor combined cycle method consisting of thirteen processes which are conducted with M 1 kg of working medium and M 2 kg of working medium separately or jointly: performing a pressurization process to set a state ( 1 ) to ( 2 ) of the M 1 kg of working medium, performing a heat-absorption process to set the state ( 2 ) to (b) of the M 1 kg of working medium, performing a heat-absorption and vaporization process to set the state (b) to ( 3 ) of the of (M 1 +M) kg of working medium, performing a pressurization process to set a state ( 8 ) to (a) of the M 2 kg of working medium, performing a heat-releasing and condensation process to set the state (a) to (b) of the M kg of working medium, performing a pressurization process to set the state (a) to ( 3 ) of the (M 2 −M) kg of working medium, performing a heat-absorption process to set the state ( 3 ) to ( 4 ) of the M 3 kg of working medium, performing a depressurization process to set the state ( 4 ) to ( 7 ) of the X kg of working medium, performing a heat-absorption process to set a state ( 4 ) to ( 5 ) of the (M 3 −X) kg of working medium, performing a depressurization process to set the state ( 5 ) to ( 6 ) of the (M 3 −X) kg of working medium, performing a heat-releasing process to set the state ( 6 ) to ( 7 ) of the (M 3 −X) kg of working medium, performing a heat-releasing process to set the state ( 7 ) to ( 8 ) of the M 3 kg of working medium, performing a heat-releasing and condensation process to set the state ( 8 ) to ( 1 ) of the M 1 kg of working medium, wherein M 3 is a sum of M 1 and M 2 .Cited by (0)
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