CN102287308B - Thermal turbine generating set - Google Patents
Thermal turbine generating set Download PDFInfo
- Publication number
- CN102287308B CN102287308B CN 201010204954 CN201010204954A CN102287308B CN 102287308 B CN102287308 B CN 102287308B CN 201010204954 CN201010204954 CN 201010204954 CN 201010204954 A CN201010204954 A CN 201010204954A CN 102287308 B CN102287308 B CN 102287308B
- Authority
- CN
- China
- Prior art keywords
- water
- pressure stage
- valve
- tank
- inlet valve
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Images
Landscapes
- Engine Equipment That Uses Special Cycles (AREA)
Abstract
The invention provides a thermal turbine generating set, which is totally divided into four levels, wherein each level is provided with three pressure tanks and a thermal turbine, a circulating water tank and a circulating water pump. A steam outlet valve of the former level pressure tank is connected with a steam inlet valve of the next level pressure tank; and a water inlet of the former level circulating water tank is connected with a water outlet of the next level circulating water pump. In the thermal turbine generating set, the top ends of the three extra-high voltage level pressure tanks are connected with an overheat steam pipe of a boiler through steam pipes; the bottom ends of the three pressure tanks are connected with an extra-high voltage level turbine water inlets through water outlet pipes; the turbine water outlets are connected with the water inlet of the first circulating water tank through a water pipe; the water outlet of the circulating water tank is connected with the water inlet of the first circulating water pump through the water pipe; the water outlet of the first circulating water pump is respectively connected with the water inlets of the three pressure tanks and a water-feeding pump through the water pipes; and the water outlet of the water-feeding pump is connected with the water inlet of the boiler through the water pipe. The four turbines are in rigid connection with a rotating shaft of the engine.
Description
Technical field
The invention belongs to turbine power generating device, specifically, is the electricity generating device that promotes water turbine with high-temperature water.
Technical background
On February 21st, 2010, we have applied for patent of invention with the title of " thermal hydro-turbine power generating device ", and application number is: 201010110521.4.The independent claims of this application, when disclosing power station use low pressure boiler, the specific embodiments of thermal hydro-turbine power generating device.When the power station uses subcritically, during boilers, specific embodiments openly only discloses a design, namely has three rank pressurized tanks, the design of thermal hydro-turbine power generating device.
Summary of the invention
The invention discloses thermal hydro-turbine power generating device, a new specific embodiments, namely when the power station uses subcritical, boilers, the specific embodiments of thermal hydro-turbine power generating device.If other pressurized tank of same level is one, two, three etc., its embodiment just has the modes such as three kinds.
The embodiment of thermal hydro-turbine power generating device disclosed by the invention, its pressurized tank is divided into level Four: superelevation is arbitrarily downgraded, high pressure stage, medium pressure grade, low pressure stage, and every grade pressurized tank is three, totally 12 pressurized tanks.This embodiment is the scheme of assembling heavy-duty generator group, and its energy-saving effect is a best scheme, and purpose of the present invention is to be achieved by following technical proposals.
Thermal hydro-turbine power generating device of the present invention comprises boiler, pressurized tanks at different levels, and thermal hydro-turbines at different levels, generator, circulating water pump at different levels, feed water pump, water pipe, steam pipe, goes out vapour, exhaust valve, water inlets at different levels, flowing water Valve, cyclic water tanks at different levels etc. at admission at different levels.Superheated vapor in the boiler is sent in each ultrahigh pressure stage pressure tank in turn, and the saturation water in this pressurized tank is subject to the gas effect of constant elastic force, removes to promote the superelevation water turbine of arbitrarily downgrading and rotates.Saturation water after the acting enters cyclic water tank, and circulating water pump is sent the water of cyclic water tank back to pressurized tank and feed water pump.Gas in the ultrahigh pressure stage pressure tank enters in the high pressure stage pressurized tank through gas outlet valve, and the effect of the elastic force that the saturation water in the high pressure stage pressurized tank is being changed is removed to promote the high pressure stage water turbine and rotated.Gas in the high pressure stage pressurized tank enters in the medium pressure grade pressurized tank through gas outlet valve, and the gas effect of the elastic force that the saturation water in the medium pressure grade pressurized tank is being changed is removed to promote the medium pressure grade water turbine and rotated.Gas in the medium pressure grade pressurized tank enters in the low pressure stage pressurized tank through gas outlet valve, and the gas effect of the elastic force that the saturation water of low pressure stage pressurized tank is being changed is removed to promote the low pressure stage water turbine and rotated.
Description of drawings
Fig. 1 is thermal hydro-turbine power generating device general structure schematic representation;
Fig. 2 is thermal hydro-turbine power generating device example structure schematic representation;
Specific embodiments
Thermal hydro-turbine power generating device general structure schematic representation as shown in Figure 1.Comprising: boiler (1), feed water pump (2), ultrahigh pressure stage pressure tank (15), (16), (17), the superelevation water turbine (3) of arbitrarily downgrading, high pressure stage water turbine (4), medium pressure grade water turbine (5), low pressure stage water turbine (6), generator (78), the first cyclic water tank (11), the first circulating water pump (7) etc., wherein boiler (1) is by steam pipe and three ultrahigh pressure stage pressure tanks (15), (16), (17) connect, three ultrahigh pressure stage pressure tanks (15), (16), (17) water inlet, water outlet is by water pipe, respectively with the water outlet of circulating water pump (7), the arbitrarily downgrade water intake of water turbine (3) of superelevation connects.The arbitrarily downgrade water outlet of water turbine (3) of superelevation by water pipe, is connected with the water intake of the first cyclic water tank (11).The water outlet of the first circulating water pump (7), the water intake with feed water pump (2), three ultrahigh pressure stage pressure tanks (15), (16), (17) is connected respectively; The arbitrarily downgrade rotating shaft of water turbine (3), high pressure stage water turbine (4), medium pressure grade water turbine (5), low pressure stage water turbine (6), generator (78) of superelevation is and is rigidly connected.
Thermal hydro-turbine power generating device example structure schematic representation as shown in Figure 2.Comprising: boiler (1), feed water pump (2), ultrahigh pressure stage pressure tank (15), (16), (17), high pressure stage pressurized tank (18), (19), (20), medium pressure grade pressurized tank (21), (22), (23), low pressure stage pressurized tank (24), (25), (26).The superelevation water turbine (3) of arbitrarily downgrading, high pressure stage water turbine (4), medium pressure grade water turbine (5), low pressure stage water turbine (6).The first circulating water pump (7), the second circulating water pump (8), the 3rd circulating water pump (9), the 4th circulating water pump (10).The first cyclic water tank (11), the second cyclic water tank (12), the 3rd cyclic water tank (13), the 4th cyclic water tank (14).Ultrahigh pressure level steam inlet valve (27), (32), (37), high pressure stage steam inlet valve (42), (47), (52), medium pressure grade steam inlet valve (57), (61), (65), low pressure stage steam inlet valve (69), (72), (75).Superelevation arbitrarily downgrade gas outlet valve (30), (35), (40), high pressure stage gas outlet valve (45), (50), (55), medium pressure grade gas outlet valve (60), (64), (68).Superelevation arbitrarily downgrade exhaust steam valve (31), (36), (41), high pressure stage exhaust steam valve (46), (51), (56).Superelevation arbitrarily downgrade outlet valve (28), (33), (38), high pressure stage outlet valve (43), (48), (53), medium pressure grade outlet valve (58), (62), (66), low pressure stage outlet valve (70), (73), (76).Ultrahigh pressure level inlet valve (29), (34), (39), high pressure stage inlet valve (44), (49), (54), medium pressure grade inlet valve (59), (63), (67), low pressure stage inlet valve (71), (74), (77).
How does thermal hydro-turbine power generating device of the present invention start working? at first be in the pressurized tanks at different levels, filled the saturation water that designs value, the vapour pressure of the saturation water in the pressurized tank and the vapor pressure that enters in the tank are that equate or approaching equal, and secondly the time lag of each pressurized tank of design is identical.The admission of each pressurized tank of the 3rd design and water outlet, steam discharge and water inlet are that each is carrying out in the interval at the same time.The 4th start working before all valves all be in closed condition.We take admission, go out vapour, the steam discharge time lag and be 10 minutes as example, tell about working procedure of the present invention.
One, the working procedure of thermal hydro-turbine power generating device ultrahigh pressure stage pressure tank of the present invention, water turbine:
Beginning in first 10 minutes, open simultaneously steam inlet valve (27), the outlet valve (28) of ultrahigh pressure stage pressure tank (15), superheated vapor in the boiler enters in this pressurized tank, saturation water in this pressurized tank passes through water pipe, entering superelevation arbitrarily downgrades in the water turbine (3), promote this water turbine and rotate, the water after the acting enters in the first cyclic water tank (11), and first 10 minutes last steam inlet valves (27), outlet valves (28) are closed simultaneously.Second 10 minutes the beginning, the gas outlet valve (30) of ultrahigh pressure stage pressure tank (15) is opened, [steam inlet valve (42) of high pressure stage pressurized tank (18) is opened simultaneously], second 10 minutes last gas outlet valve (30) close.The 3rd beginning in 10 minutes, inlet valve (29), the exhaust steam valve (31) of ultrahigh pressure stage pressure tank (15) are opened simultaneously, steam pipe is passed through in the exhaust steam of this pressurized tank (15), enter in the first cyclic water tank (11), the first circulating water pump (7) pumps into water in this pressurized tank and the feed water pump (2), the 3rd 10 minutes last inlet valves (29), exhaust steam valve (31) are closed simultaneously, the 4th beginning in 10 minutes is exactly the beginning of for the second time periodic duty of this pressurized tank (15).
Second beginning in 10 minutes, open simultaneously steam inlet valve (32) and the outlet valve (33) of ultrahigh pressure stage pressure tank (16), superheated vapor in the boiler enters in this pressurized tank, saturation water in the pressurized tank (16) passes through water pipe, enter superelevation and arbitrarily downgrade in the water turbine (3), promote this water turbine and rotate, the water after the acting enters in the first cyclic water tank (11), second 10 minutes end, steam inlet valve (32), outlet valve (33) are closed simultaneously.The 3 10 minute the beginning, the gas outlet valve (35) in the ultrahigh pressure stage pressure tank (16) is opened, [steam inlet valve (47) of high pressure stage pressurized tank (19) is opened simultaneously], the 3rd 10 minutes last gas outlet valve (35) close.The 4th beginning in 10 minutes, the inlet valve of ultrahigh pressure stage pressure tank (16), (34), exhaust steam valve (36) are opened, steam pipe is passed through in the exhaust steam of pressurized tank (16), enter in the first cyclic water tank (11), the first circulating water pump (7) goes out water pump in this pressurized tank, the feed water pump (2), and the 4th 10 minutes last inlet valves (34), exhaust steam valve (36) are closed simultaneously.The 5th beginning in 10 minutes is exactly the beginning of for the second time periodic duty of pressurized tank (16).
The 3rd beginning in 10 minutes, open simultaneously steam inlet valve (37), the outlet valve (38) of ultrahigh pressure stage pressure tank (17), superheated vapor in the boiler enters in this pressurized tank, saturation water in the pressurized tank (17) enters superelevation by water pipe and arbitrarily downgrades in the water turbine (3), promoting this water turbine rotates, water after the acting enters in the first cyclic water tank (11), the 3rd 10 minutes end, and steam inlet valve (37), outlet valve (38) are closed simultaneously.The 4th beginning in 10 minutes, the gas outlet valve (40) of ultrahigh pressure stage pressure tank (17) is opened, [steam inlet valve (52) of high pressure stage pressurized tank (20) is opened simultaneously], the 4th 10 minutes last gas outlet valve (40) close, the 5th beginning in 10 minutes, inlet valve (39), the exhaust steam valve (41) of this pressurized tank (17) are opened simultaneously, steam pipe is passed through in the exhaust steam of pressurized tank (17), enter in the first cyclic water tank (11), the first circulating water pump (7) pumps into water in this pressurized tank, the feed water pump (2).The 5th 10 minutes end, inlet valve (39), exhaust steam valve (41) are closed simultaneously.The 6th beginning in 10 minutes is exactly the beginning of the periodic duty second time of pressurized tank (17).
Two, the On The Cycle Working Process of thermal hydro-turbine power generating device high pressure stage pressurized tank of the present invention, water turbine etc.:
Second beginning in 10 minutes, the gas outlet valve (30) of ultrahigh pressure stage pressure tank (15), the steam inlet valve (42) of high pressure stage pressurized tank (18), outlet valve (43) is opened simultaneously, steam in the ultrahigh pressure stage pressure tank (15) enters in the high pressure stage pressurized tank (18), saturation water in this pressurized tank passes through water pipe, enter in the high pressure stage water turbine (4), promoting this water turbine rotates, water after the acting enters in the second cyclic water tank (12), second 10 minutes last steam inlet valve (42), outlet valve (43) is closed simultaneously.The 3rd beginning in 10 minutes, the gas outlet valve (45) of high pressure stage pressurized tank (18) is opened [steam inlet valve (57) of medium pressure grade pressurized tank (21) is opened simultaneously], the 3rd 10 minutes last high pressure stage pressurized tank (18) gas outlet valve (45) close.The 4th beginning in 10 minutes, inlet valve (44), the exhaust steam valve (46) of high pressure stage pressurized tank (18) are opened simultaneously, steam pipe is passed through in the exhaust steam of pressurized tank (18), enter in the second cyclic water tank (12), the second circulating water pump (8) pumps into water in this pressurized tank, the first cyclic water tank (11), the 4th 10 minutes end, inlet valve (44), exhaust steam valve (46) are closed simultaneously, the 5th beginning in 10 minutes is exactly the beginning of for the second time periodic duty of pressurized tank (18).
The 3rd beginning in 10 minutes, the gas outlet valve (35) of ultrahigh pressure stage pressure tank (16), the steam inlet valve (47) of high pressure stage pressurized tank (19), outlet valve (48) is opened simultaneously, steam in the ultrahigh pressure stage pressure tank (16) enters in the pressurized tank (19), saturation water in the pressurized tank (19) passes through water pipe, enter in the high pressure stage water turbine (4), promoting this water turbine rotates, water after the acting enters in the second cyclic water tank (12), the 3rd 10 minutes last steam inlet valve (47), outlet valve (48) is closed simultaneously.The 4th 10 minutes the beginning high pressure stage pressurized tank (19) gas outlet valve (50) open, [steam inlet valve (61) of medium pressure grade pressurized tank (22) is opened simultaneously], the 4th 10 minutes last gas outlet valve (50) close.The 5th beginning in 10 minutes, inlet valve (49), the exhaust steam valve (51) of high pressure stage pressurized tank (19) are opened simultaneously, steam pipe is passed through in the exhaust steam of pressurized tank (19), enter in the second cyclic water tank (12), the second circulating water pump (8) pumps into water in this pressurized tank, the first cyclic water tank (11), the 5th 10 minutes end, inlet valve (49), exhaust steam valve (51) are closed simultaneously, the 6th beginning in 10 minutes is exactly the beginning of for the second time periodic duty of pressurized tank (19).
The 4th beginning in 10 minutes, the gas outlet valve (40) of ultrahigh pressure stage pressure tank (17), the steam inlet valve (52) of high pressure stage pressurized tank (20), outlet valve (53) are opened simultaneously, ground steam enters in the pressurized tank (20) in the pressurized tank (17), saturation water in the pressurized tank (20) passes through water pipe, enter in the high pressure stage water turbine (4), promoting this water turbine rotates, water after the acting enters in the second cyclic water tank (12), the 4th 10 minutes end, steam inlet valve (52), outlet valve (53) are closed simultaneously.The 5th beginning in 10 minutes, the gas outlet valve (55) of high pressure stage pressurized tank (20) is opened [steam inlet valve (65) of medium pressure grade pressurized tank (23) is opened simultaneously], the 5th 10 minutes end, gas outlet valve (55) is closed, the 6th beginning in 10 minutes, high pressure stage pressurized tank (20) inlet valve (54), exhaust steam valve (56) is opened simultaneously, steam pipe is passed through in the exhaust steam of pressurized tank (20), enter in the second cyclic water tank (12), the second circulating water pump (8) pumps into this pressurized tank to water, in the first cyclic water tank, the 6th 10 minutes end, inlet valve (54), exhaust steam valve (56) cuts out simultaneously, the 7th beginning in 10 minutes is exactly the beginning of for the second time periodic duty of pressurized tank (20).
Three, thermal hydro-turbine power generating device of the present invention, the On The Cycle Working Process of medium pressure grade pressurized tank, water turbine etc.:
Beginning in the 3 10 minute, the gas outlet valve (45) of high pressure stage pressurized tank (18), the steam inlet valve (57) of medium pressure grade pressurized tank (21), outlet valve (58) is opened simultaneously, steam in the pressurized tank (18) enters in the pressurized tank (21), saturation water in the pressurized tank (21) passes through water pipe, enter in the medium pressure grade water turbine (5), promoting this water turbine rotates, water after the acting enters in the 3rd cyclic water tank (13), the 3rd 10 minutes not, steam inlet valve (57), outlet valve (58) is closed simultaneously, the 4th beginning in 10 minutes, the gas outlet valve (60) of pressurized tank (21) is opened, [steam inlet valve (69) of low pressure stage pressurized tank (24) is opened simultaneously], the 4th 10 minutes end, gas outlet valve (60) is closed, the 5th beginning in 10 minutes, the inlet valve (59) of medium pressure grade pressurized tank (21) is opened, the 3rd circulating water pump (9) pumps into this pressurized tank to water, in the second cyclic water tank (12), the 5th 10 minutes end, inlet valve (59) is closed.The 6th beginning in 10 minutes is exactly the beginning of for the second time periodic duty of pressurized tank (21).
The 4th beginning in 10 minutes, the gas outlet valve (50) of high pressure stage pressurized tank (19), the steam inlet valve (61) of medium pressure grade pressurized tank (22), outlet valve (62) is opened simultaneously, steam in the high pressure stage pressurized tank (19) enters in the medium pressure grade pressurized tank (22), saturation water in the pressurized tank (22), enter in the medium pressure grade water turbine (5), promoting this water turbine rotates, water after the acting enters in the 3rd cyclic water tank (13), the 4th 10 minutes end, steam inlet valve (61), outlet valve (62) is closed simultaneously, the 5th beginning in 10 minutes, the gas outlet valve (64) of medium pressure grade pressurized tank (22) is opened [steam inlet valve (72) of low pressure stage pressurized tank (25) is opened simultaneously], the 5th 10 minutes end, the gas outlet valve (64) of medium pressure grade pressurized tank (22) is closed.The 6th beginning in 10 minutes, the inlet valve (63) of medium pressure grade pressurized tank (22) is opened, the 3rd circulating water pump (9) pumps into water in this pressurized tank, the second cyclic water tank (12), the 6th 10 minutes last inlet valve (63) close, the 7th beginning in ten minutes is exactly the beginning of for the second time periodic duty of this pressurized tank (22).
The 5th beginning in 10 minutes, the gas outlet valve (55) of high pressure stage pressurized tank (20), the steam inlet valve (65) of medium pressure grade pressurized tank (23), outlet valve (66) is opened simultaneously, steam in the pressurized tank (20) enters in the pressurized tank (23), saturation water in the pressurized tank (23) passes through water pipe, enter in the medium pressure grade water turbine (5), promoting this water turbine rotates, water after the acting enters in the 3rd cyclic water tank (13), the 5th 10 minutes end, steam inlet valve (65), outlet valve (66) is closed simultaneously, the 6th beginning in 10 minutes, the gas outlet valve (68) of pressurized tank (23) is opened, [steam inlet valve (75) of low pressure stage pressurized tank (26) is opened simultaneously], the 6th 10 minutes end, gas outlet valve (68) is closed, the 7th beginning in 10 minutes, the inlet valve (67) of medium pressure grade pressurized tank (23) is opened, the 3rd circulating water pump (9) pumps into this pressurized tank to water, in the second cyclic water tank (12), the 7th 10 minutes end, inlet valve (67) is closed, the 8th beginning in 10 minutes is exactly the beginning of the periodic duty second time of pressurized tank (23).
Four, thermal hydro-turbine power generating device of the present invention, the working procedure of low pressure stage pressurized tank, water turbine etc.:
The 4th beginning in 10 minutes, the gas outlet valve (60) of medium pressure grade pressurized tank (21), the steam inlet valve (69) of low pressure stage pressurized tank (24), outlet valve (70) is opened simultaneously, steam in the pressurized tank (21) enters in the pressurized tank (24), saturation water in the pressurized tank (24) passes through water pipe, enter in the low pressure stage water turbine (6), promoting this water turbine rotates, water after the acting, enter in the 4th cyclic water tank (14), the 4th 10 minutes last steam inlet valve (69), outlet valve (70) is closed simultaneously, [the low pressure stage pressurized tank does not have gas outlet valve, flooding time is designed to 20 minutes], the 5th beginning in 10 minutes, the inlet valve (71) of low pressure stage pressurized tank (24) is opened, the 4th circulating water pump (10) pumps into this pressurized tank to water, in the 3rd cyclic water tank (13), the 6th 10 minutes end, inlet valve (71) is closed, the 7th beginning in 10 minutes is exactly the beginning of for the second time periodic duty of pressurized tank (24).
The 5th beginning in 10 minutes, the gas outlet valve (64) of medium pressure grade pressurized tank (22), the steam inlet valve (72) of low pressure stage pressurized tank (25), outlet valve (73) is opened simultaneously, steam in the pressurized tank (22) enters in the pressurized tank (25), saturation water in the pressurized tank (25) passes through water pipe, enter in the low pressure stage water turbine (6), promoting this water turbine rotates, water after the acting, enter in the 4th cyclic water tank (14), the 5th 10 minutes last steam inlet valve (72), outlet valve (73) is closed simultaneously, the 6th beginning in 10 minutes, inlet valve (74) is opened, the 4th circulating water pump (10) pumps into this pressurized tank to water, in the 3rd cyclic water tank (13), the 7th 10 minutes end, inlet valve (74) is closed, and the 8th beginning in 10 minutes is exactly the beginning of for the second time periodic duty of pressurized tank (25).
The 6th beginning in 10 minutes, the gas outlet valve (68) of medium pressure grade pressurized tank (23), the steam inlet valve (75) of low pressure stage pressurized tank (26), outlet valve (76) is opened simultaneously, steam in the pressurized tank (23) enters in the pressurized tank (26), saturation water in the pressurized tank (26) passes through water pipe, enter in the low pressure stage water turbine (6), promoting this water turbine rotates, water after the acting, enter in the 4th cyclic water tank (14), the 6th 10 minutes last steam inlet valve (75), outlet valve (76) is closed simultaneously, the 7th beginning in 10 minutes, inlet valve (77) is opened, the 4th circulating water pump (10) pumps into this pressurized tank to water, in the 3rd cyclic water tank (13), the 8th 10 minutes end, inlet valve (77) is closed, and the 9th beginning in 10 minutes is exactly the beginning of for the second time periodic duty of pressurized tank (26).
Thermal hydro-turbine power generating device of the present invention can make the periodic duty of three other pressurized tanks of level, water turbine etc. into.Only need to change the admission time (or admission value) of existing ultrahigh pressure stage pressure tank (15), (16), (17), other, quantity, the circulating working time of component etc. all do not change, just can will have the thermal hydro-turbine power generating device of level Four, 12 tanks now, become three grades, the thermal hydro-turbine power generating device of 9 tanks.Superheated vapor is entered time in the ultrahigh pressure stage pressure tank, when reducing to 1/5th to 1/3rd interval of original entry time, or, enter into the volume of the superheated vapor of ultrahigh pressure stage pressure tank, be 1/5th to 1/3rd when interval of pressurized tank volume, close the steam inlet valve of ultrahigh pressure stage pressure tank, at this moment, saturation water in the pressurized tank, be subject to the effect of the elastic force that changing, pressure is arbitrarily downgraded by superelevation and is reduced to high pressure stage, ultrahigh pressure stage pressure tank becomes the high pressure stage pressurized tank, therefore, just can remove the existing high pressure stage circulatory system, thereby realized the thermal hydro-turbine power generating device by level Four 12 tanks, becoming is the thermal hydro-turbine power generating device of three grade of 9 tank.
Claims (2)
1. thermal hydro-turbine power generating device, comprising: boiler (1), feed water pump (2), the first ultrahigh pressure stage pressure tank (15), the second ultrahigh pressure stage pressure tank (16), the 3rd ultrahigh pressure stage pressure tank (17), the superelevation water turbine (3) of arbitrarily downgrading, the first ultrahigh pressure level steam inlet valve (27), the second ultrahigh pressure level steam inlet valve (32), the 3rd ultrahigh pressure level steam inlet valve (37), the first superelevation gas outlet valve (30) of arbitrarily downgrading, the second superelevation gas outlet valve (35) of arbitrarily downgrading, the 3rd superelevation gas outlet valve (40) of arbitrarily downgrading, the first superelevation exhaust steam valve (31) of arbitrarily downgrading, the second superelevation exhaust steam valve (36) of arbitrarily downgrading, the 3rd superelevation exhaust steam valve (41) of arbitrarily downgrading, the first ultrahigh pressure level inlet valve (29), the second ultrahigh pressure level inlet valve (34), the 3rd ultrahigh pressure level inlet valve (39), the first superelevation outlet valve (28) of arbitrarily downgrading, the second superelevation outlet valve (33) of arbitrarily downgrading, the 3rd superelevation outlet valve (38) of arbitrarily downgrading, the first high pressure stage pressurized tank (18), the second high pressure stage pressurized tank (19), the third high pressurized tank (20) of arbitrarily downgrading, high pressure stage water turbine (4), the first high pressure stage steam inlet valve (42), the second high pressure stage steam inlet valve (47), the third high steam inlet valve (52) of arbitrarily downgrading, the first high pressure stage gas outlet valve (45), the second high pressure stage gas outlet valve (50), the third high gas outlet valve (55) of arbitrarily downgrading, the first high pressure stage exhaust steam valve (46), the second high pressure stage exhaust steam valve (51), the third high exhaust steam valve (56) of arbitrarily downgrading, the first high pressure stage inlet valve (44), the second high pressure stage inlet valve (49), the third high inlet valve (54) of arbitrarily downgrading, the first high pressure stage outlet valve (43), the second high pressure stage outlet valve (48), the third high outlet valve (53) of arbitrarily downgrading, the first medium pressure grade pressurized tank (21), the second medium pressure grade pressurized tank (22), the 3rd medium pressure grade pressurized tank (23), medium pressure grade water turbine (5), the first medium pressure grade steam inlet valve (57), the second medium pressure grade steam inlet valve (61), the 3rd medium pressure grade steam inlet valve (65), the first medium pressure grade gas outlet valve (60), the second medium pressure grade gas outlet valve (64), the 3rd medium pressure grade gas outlet valve (68), the first medium pressure grade inlet valve (59), the second medium pressure grade inlet valve (63), the 3rd medium pressure grade inlet valve (67), the first medium pressure grade outlet valve (58), the second medium pressure grade outlet valve (62), the 3rd medium pressure grade outlet valve (66), the first low pressure stage pressurized tank (24), the second low pressure stage pressurized tank (25), the 3rd low pressure stage pressurized tank (26), low pressure stage water turbine (6), the first low pressure stage steam inlet valve (69), the second low pressure stage steam inlet valve (72), the 3rd low pressure stage steam inlet valve (75), the first low pressure stage inlet valve (71), the second low pressure stage inlet valve (74), the 3rd low pressure stage inlet valve (77), the first low pressure stage outlet valve (70), the second low pressure stage outlet valve (73), the 3rd low pressure stage outlet valve (76), the first circulating water pump (7), the first cyclic water tank (11), the second circulating water pump (8), the second cyclic water tank (12), the 3rd circulating water pump (9), the 3rd cyclic water tank (13), the 4th circulating water pump (10), the 4th cyclic water tank (14), steam pipe, water pipe, it is characterized in that: the superheated vapor of boiler (1) passes through steam pipe, respectively with the first ultrahigh pressure level steam inlet valve (27), the second ultrahigh pressure level steam inlet valve (32), the steam inlet of the 3rd ultrahigh pressure level steam inlet valve (37) connects, the first ultrahigh pressure level steam inlet valve (27), the second ultrahigh pressure level steam inlet valve (32), the steam ouput of the 3rd ultrahigh pressure level steam inlet valve (37), respectively with the first ultrahigh pressure stage pressure tank (15), the second ultrahigh pressure stage pressure tank (16), the 3rd ultrahigh pressure stage pressure tank (17) top connects, the first ultrahigh pressure stage pressure tank (15), the second ultrahigh pressure stage pressure tank (16), the bottom of the 3rd ultrahigh pressure stage pressure tank (17) respectively with the first superelevation outlet valve (28) of arbitrarily downgrading, the second superelevation outlet valve (33) of arbitrarily downgrading, the arbitrarily downgrade water intake of outlet valve (38) of the 3rd superelevation connects, the first superelevation outlet valve (28) of arbitrarily downgrading, the second superelevation outlet valve (33) of arbitrarily downgrading, the 3rd superelevation the arbitrarily downgrade water intake of water turbine (3) of water outlet and the superelevation of outlet valve (38) of arbitrarily downgrading is connected, the arbitrarily downgrade water outlet of water turbine (3) of superelevation is connected by the water intake of water pipe with the first cyclic water tank (11), the water outlet of the first cyclic water tank (11) passes through water pipe, be connected with the water intake of the first circulating water pump (7), the water outlet of the first circulating water pump (7) passes through water pipe, respectively with the water intake of feed water pump (2), the first ultrahigh pressure level inlet valve (29), the second ultrahigh pressure level inlet valve (34), the water intake of the 3rd ultrahigh pressure level inlet valve (39) connects, the water outlet of feed water pump (2) passes through water pipe, be connected with the water intake of boiler (1), the first ultrahigh pressure level inlet valve (29), the second ultrahigh pressure level inlet valve (34), the water outlet of the 3rd ultrahigh pressure level inlet valve (39) by water pipe respectively with the first ultrahigh pressure stage pressure tank (15), the second ultrahigh pressure stage pressure tank (16), the bottom of the 3rd ultrahigh pressure stage pressure tank (17) connects, the first ultrahigh pressure stage pressure tank (15), the second ultrahigh pressure stage pressure tank (16), the top of the 3rd ultrahigh pressure stage pressure tank (17) respectively with the first superelevation gas outlet valve (30) of arbitrarily downgrading, the second superelevation gas outlet valve (35) of arbitrarily downgrading, the 3rd superelevation gas outlet valve (40) of arbitrarily downgrading, the first superelevation exhaust steam valve (31) of arbitrarily downgrading, the second superelevation exhaust steam valve (36) of arbitrarily downgrading, the arbitrarily downgrade steam inlet of exhaust steam valve (41) of the 3rd superelevation connects, the first superelevation exhaust steam valve (31) of arbitrarily downgrading, the second superelevation exhaust steam valve (36) of arbitrarily downgrading, the 3rd superelevation is arbitrarily downgraded the steam ouput of exhaust steam valve (41) by pipeline, is connected with the first cyclic water tank (11); The first superelevation gas outlet valve (30) of arbitrarily downgrading, the second superelevation gas outlet valve (35) of arbitrarily downgrading, the 3rd superelevation arbitrarily downgrade gas outlet valve (40) steam ouput by steam pipe respectively with the first high pressure stage steam inlet valve (42), the second high pressure stage steam inlet valve (47), the arbitrarily downgrade steam inlet of steam inlet valve (52) of third high connects, the first high pressure stage steam inlet valve (42), the second high pressure stage steam inlet valve (47), the arbitrarily downgrade steam ouput of steam inlet valve (52) of third high passes through steam pipe, respectively with the first high pressure stage pressurized tank (18), the second high pressure stage pressurized tank (19), the arbitrarily downgrade top of pressurized tank (20) of third high, the first high pressure stage gas outlet valve (45), the second high pressure stage gas outlet valve (50), the third high gas outlet valve (55) of arbitrarily downgrading, the first high pressure stage exhaust steam valve (46), the second high pressure stage exhaust steam valve (51), the arbitrarily downgrade steam inlet of exhaust steam valve (56) of third high connects, the first high pressure stage exhaust steam valve (46), the second high pressure stage exhaust steam valve (51), the arbitrarily downgrade steam ouput of exhaust steam valve (56) of third high passes through steam pipe, be connected with the second cyclic water tank (12), the first high pressure stage outlet valve (43), the second high pressure stage outlet valve (48), third high is arbitrarily downgraded the water intake of outlet valve (53) by water pipe and the first high pressure stage pressurized tank (18), the second high pressure stage pressurized tank (19), third high pressurized tank (20) bottom of arbitrarily downgrading connects, the first high pressure stage outlet valve (43), the second high pressure stage outlet valve (48), the arbitrarily downgrade water outlet of outlet valve (53) of third high is connected by the water intake of water pipe with high pressure stage water turbine (4), the water outlet of this water turbine is connected by the water intake of water pipe with the second cyclic water tank (12), the water outlet of this cyclic water tank passes through water pipe, be connected with the water intake of the second circulating water pump (8), the water outlet of this circulating water pump passes through water pipe, respectively with the first cyclic water tank (11), the first high pressure stage inlet valve (44), the second high pressure stage inlet valve (49), the arbitrarily downgrade water intake of inlet valve (54) of third high connects, the first high pressure stage inlet valve (44), the second high pressure stage inlet valve (49), the arbitrarily downgrade water outlet of inlet valve (54) of third high passes through water pipe, respectively with the first high pressure stage pressurized tank (18), the second high pressure stage pressurized tank (19), the arbitrarily downgrade bottom of pressurized tank (20) of third high connects;
The first high pressure stage gas outlet valve (45), the second high pressure stage gas outlet valve (50), third high each steam ouput of gas outlet valve (55) of arbitrarily downgrading passes through pipeline, respectively with the first medium pressure grade steam inlet valve (57), the second medium pressure grade steam inlet valve (61), the steam inlet of the 3rd medium pressure grade steam inlet valve (65) connects, the first medium pressure grade steam inlet valve (57), the second medium pressure grade steam inlet valve (61), the 3rd each steam ouput of medium pressure grade steam inlet valve (65) passes through steam pipe, respectively with the first medium pressure grade pressurized tank (21), the second medium pressure grade pressurized tank (22), the top of the 3rd medium pressure grade pressurized tank (23), the first medium pressure grade gas outlet valve (60), the second medium pressure grade gas outlet valve (64), the steam inlet of the 3rd medium pressure grade gas outlet valve (68) connects, the first medium pressure grade pressurized tank (21), the second medium pressure grade pressurized tank (22), water pipe is passed through in the 3rd each bottom of medium pressure grade pressurized tank (23), respectively with the first medium pressure grade outlet valve (58), the second medium pressure grade outlet valve (62), the 3rd each water intake of medium pressure grade outlet valve (66), the first medium pressure grade inlet valve (59), the second medium pressure grade inlet valve (63), each water outlet of the 3rd medium pressure grade inlet valve (67) connects, the first medium pressure grade outlet valve (58), the second medium pressure grade outlet valve (62), the 3rd each water outlet of medium pressure grade outlet valve (66) is connected by the water intake of water pipe with medium pressure grade water turbine (5), the water outlet of this water turbine is connected by the water intake of water pipe with the 3rd cyclic water tank (13), the water outlet of this cyclic water tank (13) passes through water pipe, be connected with the water intake of the 3rd circulating water pump (9), the water outlet of this circulating water pump (9) passes through water pipe, respectively with the second cyclic water tank (12) water intake, the first medium pressure grade inlet valve (59), the second medium pressure grade inlet valve (63), the water intake of the 3rd medium pressure grade inlet valve (67) connects, the first medium pressure grade gas outlet valve (60), the second medium pressure grade gas outlet valve (64), the 3rd each steam ouput of medium pressure grade gas outlet valve (68) passes through steam pipe, respectively with the first low pressure stage steam inlet valve (69), the second low pressure stage steam inlet valve (72), the steam inlet of the 3rd low pressure stage steam inlet valve (75) connects, the first low pressure stage steam inlet valve (69), the second low pressure stage steam inlet valve (72), the 3rd each steam ouput of low pressure stage steam inlet valve (75) passes through steam pipe, respectively with the first low pressure stage pressurized tank (24), the second low pressure stage pressurized tank (25), the top of the 3rd low pressure stage pressurized tank (26) connects, the first low pressure stage pressurized tank (24), the second low pressure stage pressurized tank (25), water pipe is passed through in the 3rd low pressure stage pressurized tank (26) bottom, respectively with the first low pressure stage outlet valve (70), the second low pressure stage outlet valve (73), the 3rd low pressure stage outlet valve (76) water intake, the first low pressure stage inlet valve (71), the second low pressure stage inlet valve (74), the water outlet of the 3rd low pressure stage inlet valve (77) connects, the first low pressure stage outlet valve (70), the second low pressure stage outlet valve (73), the 3rd low pressure stage outlet valve (76) water outlet is connected by the water intake of water pipe with low pressure stage water turbine (6), the water outlet of this water turbine is connected by the water intake of water pipe with the 4th cyclic water tank (14), the water outlet of this cyclic water tank (14) passes through water pipe, be connected with the water intake of the 4th circulating water pump (10), the water outlet of this circulating water pump (10) is by water pipe, respectively with the 3rd cyclic water tank (13) water intake, the first low pressure stage inlet valve (71), the second low pressure stage inlet valve (74), the water intake of the 3rd low pressure stage inlet valve (77) connects.
2. thermal hydro-turbine power generating device according to claim 1, it is characterized in that: enter the first ultrahigh pressure stage pressure tank (15) from boiler (1), the second ultrahigh pressure stage pressure tank (16), the admission time of the superheated vapor in the 3rd ultrahigh pressure stage pressure tank (17) gives to reduce, when being reduced to 1/5th to 1/3rd interval of original service life, or when entering into the first ultrahigh pressure stage pressure tank (15), the second ultrahigh pressure stage pressure tank (16), when the superheated vapor in the 3rd ultrahigh pressure stage pressure tank (17) is 1/5th to 1/3rd interval of this pressurized tank volume, close the first ultrahigh pressure level steam inlet valve (27), the second ultrahigh pressure level steam inlet valve (32), the 3rd ultrahigh pressure level steam inlet valve (37), arrive this, superelevation is arbitrarily downgraded and is become the high pressure stage pressurized tank, the existing high pressure stage circulatory system can be removed, level Four 12 tank thermal hydro-turbine power generating devices become three grade of 9 tank thermal hydro-turbine power generating device.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN 201010204954 CN102287308B (en) | 2010-06-21 | 2010-06-21 | Thermal turbine generating set |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN 201010204954 CN102287308B (en) | 2010-06-21 | 2010-06-21 | Thermal turbine generating set |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CN102287308A CN102287308A (en) | 2011-12-21 |
| CN102287308B true CN102287308B (en) | 2013-04-17 |
Family
ID=45333991
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN 201010204954 Expired - Fee Related CN102287308B (en) | 2010-06-21 | 2010-06-21 | Thermal turbine generating set |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN102287308B (en) |
Families Citing this family (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN106285807A (en) * | 2016-08-05 | 2017-01-04 | 张世严 | Energy transformation method and system |
Citations (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN201202499Y (en) * | 2008-05-20 | 2009-03-04 | 张秀枝 | Working apparatus of steam water turbine |
| DE102008013159A1 (en) * | 2008-03-07 | 2009-09-10 | Arnold Zajonz | Water pressure rotor for e.g. stationary application, has impeller propelled to discharge water to lower part of body, where water flows back into water container to form closed loop, and axle that serves for driving purposes |
| CN101709661A (en) * | 2009-12-11 | 2010-05-19 | 中冶京诚工程技术有限公司 | Waste heat generating system and generating method |
Family Cites Families (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP2003097224A (en) * | 2001-09-26 | 2003-04-03 | Toshiba Eng Co Ltd | Power generating unit |
-
2010
- 2010-06-21 CN CN 201010204954 patent/CN102287308B/en not_active Expired - Fee Related
Patent Citations (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| DE102008013159A1 (en) * | 2008-03-07 | 2009-09-10 | Arnold Zajonz | Water pressure rotor for e.g. stationary application, has impeller propelled to discharge water to lower part of body, where water flows back into water container to form closed loop, and axle that serves for driving purposes |
| CN201202499Y (en) * | 2008-05-20 | 2009-03-04 | 张秀枝 | Working apparatus of steam water turbine |
| CN101709661A (en) * | 2009-12-11 | 2010-05-19 | 中冶京诚工程技术有限公司 | Waste heat generating system and generating method |
Non-Patent Citations (1)
| Title |
|---|
| JP特开2003-97224A 2003.04.03 |
Also Published As
| Publication number | Publication date |
|---|---|
| CN102287308A (en) | 2011-12-21 |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN103644004B (en) | The cogeneration system of a kind of pair of turbine, combined cycle | |
| CN103452611B (en) | Combined-cycle combined heat and power system | |
| CN101650022A (en) | Steam turbine interstage back-heating heater cross-class connecting system | |
| CN109855147B (en) | Combined cycle device based on heat supply and power peak regulation coupling and operation method thereof | |
| CN205028667U (en) | Thermoelectric cogeneration system of marine nuclear energy | |
| CN106949521A (en) | A kind of heat supply remodeling method for realizing the operation of turbine condenser high vacuum | |
| CN112856363B (en) | System and method for improving heat supply steam parameters of deep peak shaving heat supply unit | |
| CN114233416B (en) | Dynamically-reconstructed steam turbine generator unit and operation method | |
| Lei et al. | Experimental study and theoretical analysis of a Roto-Jet pump in small scale organic Rankine cycles | |
| CN109854315A (en) | A kind of heating system and its operation method integrated for Combined cycle gas-steam turbine unit steam extraction | |
| CN208380640U (en) | System is utilized for the pressure difference in the case of load fluctuation | |
| CN102287308B (en) | Thermal turbine generating set | |
| CN203796333U (en) | Ultra-supercritical double reheat bypass system for double-shaft steam turbine | |
| CN206694081U (en) | A kind of heat regenerative system for thermal power plant | |
| CN210088955U (en) | Combined cycle device for steam extraction integration and heat storage peak regulation coupling | |
| CN105298555A (en) | Pure-condensation-high-back-pressure circulating water heat supply dual-mode single-rotor steam turbine and system thereof | |
| CN205618205U (en) | Cogeneration of heat and power solar heating makeup water system | |
| CN210483828U (en) | Energy-saving power generation and utilization system utilizing exhaust steam waste heat of steam turbine of thermal power plant | |
| CN104456519A (en) | Novel efficient water supply heat recovery system for secondary reheating unit | |
| CN104329127B (en) | Multicomputer associating capacity-enlarging system | |
| CN210179723U (en) | Combined cycle device based on heat supply and electric power peak regulation coupling | |
| CN103790657A (en) | Steam distributing method and device for waste heat generating system of charcoal ink factory | |
| US9399928B2 (en) | Steam power plant with heat reservoir and method for operating a steam power plant | |
| CN206942815U (en) | Steam Turbine attachment structure | |
| CN202659288U (en) | 60Hz and 200MV of three-pressure reheat combined-cycle steam turbine |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| C06 | Publication | ||
| PB01 | Publication | ||
| C10 | Entry into substantive examination | ||
| SE01 | Entry into force of request for substantive examination | ||
| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| CF01 | Termination of patent right due to non-payment of annual fee | ||
| CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20130417 Termination date: 20180621 |