JP2006144720A - Steam turbine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable to efficiently use steam supplied to a steam turbine and to miniaturize the steam turbine by miniaturizing surface area of a moving blade. <P>SOLUTION: The steam turbine is provided with a housing 2 in which steam supplied from outside flows and a plurality of moving blade members 3 receiving steam flowing in a housing 2 and rotating the moving blades 30. A plurality of nozzles 10 expands and discharges flowing-in steam is formed in the housing 2. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a steam turbine and a boiler system using the steam turbine.

  Conventionally, as disclosed in Non-Patent Document 1, for example, a steam turbine is known in which steam is applied in a direction substantially perpendicular to the rotation direction of a moving blade formed on the steam turbine to rotate the moving blade. . The steam applied to the moving blade is expanded by the stationary blade formed at the rear of the moving blade, and repeatedly applied to the moving blade formed at the rear of the stationary blade, whereby a plurality of moving motions are formed. The rotor connecting the blades is rotated.

Numano Masahiro, Nakajima Ken and Kamo Nobuyuki “Steam Engineering-Introduction to Steam Plant Engineering” Asakura Shoten April 20, 1987 p. 104 Figure 8.1

  However, in the steam turbine disclosed in Non-Patent Document 1, when the steam moves between the stages formed by the moving blades and the stationary blades, the state of the steam may change, and sufficient thermal efficiency is obtained. There was a problem that could not get. Further, since it is necessary to form a plurality of stages in order to obtain sufficient thermal efficiency, the axial length of the rotor of the entire steam turbine becomes longer, and as a result, it is difficult to reduce the size of the steam turbine. It was.

  Therefore, the present invention has been made in view of such circumstances, and an object thereof is to efficiently use steam and to reduce the size of a moving blade.

  A steam turbine according to the present invention includes a housing into which steam supplied from the outside flows, and a plurality of moving blades that receive the steam that has flowed into the housing and rotate a rotor. A plurality of stationary blades for expanding and discharging the generated steam are formed.

  According to this configuration, it is possible to flow the steam flowing in from the outside of the housing to the moving blade, expand it in the stationary blade formed in the housing, and flow the expanded steam to the moving blade again.

  Moreover, the said stationary blade of the steam turbine which concerns on this invention is the nozzle formed in multiple numbers in the said housing, and the other nozzle which adjoins the vapor | steam discharged | emitted from the discharge port in one nozzle to several said nozzle. It is characterized by being arranged to flow in from the inlet.

  According to this configuration, the operation of causing the steam discharged from the discharge port of one nozzle to flow in from the inlet of another adjacent nozzle is performed a plurality of times inside the housing, so that the moving blade can be efficiently rotated. Can do.

  Further, the plurality of moving blades of the steam turbine according to the present invention are formed radially with respect to the rotor, and the discharge port of the one nozzle is between adjacent moving blades among the plurality of moving blades. The steam is discharged into the space formed in the space, and the steam discharged into the space moves in accordance with the movement of the space to a position facing the inlet of the other nozzle as the rotor rotates. It flows in from the inflow port in the nozzle.

  According to this configuration, it is not necessary to connect a plurality of steam turbines by expanding the steam using a plurality of moving blades formed in one steam turbine and a plurality of stationary blades formed in the housing. Further, the surface area of the moving blade can be reduced.

  In addition, the boiler system according to the present invention uses a heat of high-temperature gas discharged from the outside to vaporize the liquid stored inside, and powers the energy of the vapor evaporated by the steam tank. A steam turbine that converts the steam supplied from the steam turbine and a cooling device that liquefies the steam supplied from the steam turbine, the steam turbine including a housing into which the steam supplied from the steam tank flows, and the housing It is characterized by having a plurality of moving blades for rotating the rotor by receiving the inflowed steam, and stationary blades for expanding and discharging the inflowed steam.

  According to this configuration, the heat of high-temperature gas discharged from the outside is vaporized in the steam tank, and power is generated in the steam turbine using the vaporized gas. The steam that has generated the power is sent from the steam turbine to the cooling device and liquefied in the cooling device. The liquefied liquid can be made to perform the same operation again by sending it to the steam tank again. That is, power can be efficiently generated in the steam turbine using a small amount of liquid.

  With the configuration described above, the steam supplied to the steam turbine can be used efficiently, and the steam turbine can be downsized by reducing the surface area of the moving blade.

  Hereinafter, specific embodiments to which the present invention is applied will be described in detail with reference to the drawings.

  Hereinafter, a first embodiment of a steam turbine according to the present invention will be described. FIG. 1 is an exploded perspective view showing details of each member constituting the steam turbine 1. The steam turbine 1 includes a housing main body 2 a and a housing lid member 2 b that form an outer shell of the steam turbine 1, a rotor 4 having a substantially cross shape, and a plurality of blade members formed along the outer periphery of the rotor 4. 3, a rotor shaft 5 that supports the rotation of the rotor 43, and two pressure holding plates 6 disposed so as to sandwich the rotor 4 and the moving blade member 3. The moving blade member 3, the rotor 4, and the rotor shaft 5 are integrated to form a moving blade 30. In this case, the housing member 2a and the housing lid member 2b are collectively referred to as the housing 2.

  The housing body 2a has a disk shape with a predetermined thickness, and has a predetermined thickness that allows the rotor 4 and the rotor blade member 3 to be loosely inserted into a circular surface and rotated in the circumferential direction. A disc-like cavity 7 is formed. A plurality of sets of inlets 8 and outlets 9 are formed on the surface of the cavity 7. The pair of inflow ports 8 and outflow ports 9 are connected inside the housing main body 2a to form a nozzle 10 as a stationary blade. The nozzle 10 has a substantially bowl shape and is formed such that the opening area in the vicinity of the inflow port 8 is larger than the opening area in the vicinity of the outflow port 9. FIG. 2A is an elevation view showing details of each member constituting the steam turbine, and FIG. 2B is an elevation view showing details of the housing lid member. As shown in FIG. A spiral heat sink groove 14 for releasing heat accumulated in the cavity 7 is formed on the bottom surface of the.

  The housing lid member 2b has a disk shape, and a helical heat sink groove 14 is formed on the bottom surface in the same manner as the housing body 2a. Further, a gasket groove 16 for improving confidentiality is formed at a position in contact with the pressure holding plate 6 on the same surface as the surface on which the heat sink groove 14 is formed.

  The rotor 4 and the moving blade member 3 are members that form the moving blade of the steam turbine 1. The rotor 4 mainly supports a plurality of blade members 3 formed radially along the outer periphery of the rotor 4, and the blades 30 are rotated by the pressure received in the blade members 3. One end of the rotor shaft 5 is connected to, for example, a power generator. Thereby, the rotational force of the rotor shaft 5 can be converted into electric power. The plurality of moving blade members 3 may be all connected, or may be individually separated and fixed to the rotor 4. Further, in this case, it is preferable to have a curved surface that can enclose steam that flows in by a method described later.

  The steam turbine 1 is in contact with an inflow nozzle 20 through which steam can flow into the space 7 from the outside, and an outflow nozzle 21 through which steam inside the steam turbine 1 can be discharged to the outside. In this case, the opening area of one end facing the space 7 of the inflow nozzle 20 is preferably smaller than the opening area of the other end of the inflow nozzle 20.

  The steam flowing in from the inflow nozzle 20 is accumulated in a space 15 formed between the adjacent blade members 3 among the plurality of blade members 3. At this time, the moving blade 30 is rotated in the direction of arrow A by the steam force applied to the moving blade member 3. By continuously injecting the steam, the moving blade 30 continues to rotate in the direction of arrow A, and the steam continues to accumulate in the space 15 facing the inflow nozzle 20 by the rotation. For convenience of explanation, only the vapor accumulated in one space 15 will be described here.

  The steam that has flowed into the space 15 by the above-described method is moved inside the steam turbine 1 by the rotation of the rotor blade member 3, but when facing the inlet 8 formed in the housing body 2a, The part flows into the nozzle 10. At this time, the vicinity of the outlet 9 of the nozzle 10 is preferably formed narrower than the vicinity of the inlet 8. That is, by reducing the interval between the wall surfaces of the nozzles 10 in the vicinity of the outlet 9, pressure loss occurs in the flowing steam, and the steam expands. Thereafter, the expanded steam flows out from the outlet 9 to the space 15.

  The steam that has flowed out of the outlet 9 into the space 13 strikes the rotor blade member 3 again, so that the rotational force of the rotor blade member 3 in the direction of arrow A can be promoted. Since a series of these operations is generated every time the steam reaches the nozzle 10, the same effect as that obtained when the steam turbine 1 passes through a stage formed by a plurality of moving blades and stationary blades can be obtained. Can do.

  After repeating these operations, the steam is moved to a position facing the outflow nozzle 21 by the rotation of the moving blade member 3 and discharged from the outflow nozzle 21 to the outside of the steam turbine 1. At this time, the kinetic energy can be efficiently obtained by connecting the rotor shafts 5 of the plurality of steam turbines 1 and connecting the outflow nozzle 21 and the inflow nozzle 20 of the adjacent steam turbine 1.

  With the above-described configuration, the nozzles 10 as a plurality of stationary blades are formed inside the housing member 2a, and the steam that has flowed in by rotating the moving blade 30 using the nozzles 10 can be used efficiently. .

  As described above, the steam turbine 1 includes a housing 2 into which steam supplied from the outside flows, and a plurality of blade members 3 that receive the steam that flows into the housing 2 and rotate the rotor shaft 5. The housing 2 is formed with a nozzle 10 that expands and discharges the inflowed steam, so that the steam applied to the moving blade member 3 flows into the nozzle 10 and is applied again to the moving blade member 30. Can be converted into power efficiently. As a result of trial manufacture and experiment of the steam turbine 1 as described above, a thermal efficiency of about 40% can be obtained.

  Further, in order to obtain sufficient power in the conventional vertical steam turbine, it is necessary that the surface area of the moving blade is large. However, in the steam turbine 1, sufficient power is obtained by the moving blade member 3 and the rotor 4. Therefore, the moving blade member 3 can be downsized. Accordingly, the steam turbine 1 can be reduced in size, and the cost can be reduced as the number of members is reduced.

  The steam turbine 1 can be applied to a boiler mechanism as shown in FIG. 3, for example. For convenience of explanation, a vehicle having a boiler mechanism will be described. However, the use of the boiler mechanism is not limited and can be appropriately changed without departing from the gist of the present invention.

  The boiler mechanism includes a steam boiler 1, a water boiler 22 that evaporates water using heat of exhaust gas discharged from an external device such as the engine 40, and a purification mechanism 23 that purifies the exhaust gas and discharges it to the outside. And a cooling device 24 that cools, liquefies, and stores water discharged from the steam turbine 1.

  The water boiler 22 is formed by passing an exhaust pipe 31 that transfers exhaust gas discharged from an external device through a steam tank 30 that can store a certain amount of water. A steam pipe 32 having one end connected to the inflow nozzle 20 of the steam turbine 1 is fixed to the steam tank 30 so that steam generated in the steam tank 30 can be sent to the steam turbine 1. The outflow nozzle 21 of the steam turbine 1 is connected to the cooling device 24. The cooling device 24 is connected so that water obtained by liquefying steam can be sent to the steam tank 30.

  Hot exhaust gas generated by combustion in the engine 40 is sent to the water boiler 22. Thereby, the water flowing through the steam tank 30 is evaporated by the heat of the exhaust gas sent to the water boiler 22. Thereafter, the exhaust gas is sent to the purification mechanism 23, purified, and then discharged to the outside.

  The steam evaporated in the water boiler 22 is sent to the steam turbine 1 and sent from the inflow nozzle 20 into the steam turbine 1. At this time, the moving blade member 3 and the rotor 4 are rotated by the steam, and the rotor shaft 5 is also rotated in synchronization. When the rotor shaft 5 rotates, power is supplied to the turbo fan 41, and the turbo fan 41 can be rotated. The turbo fan 41 rotated by the steam turbine 1 can intake air and send the intake air to the engine 40. Further, the power source 42 connected to the other end of the rotor shaft 5 can convert the kinetic energy of the rotor shaft 5 into electric power and supply electricity to an electric device such as an air conditioner mounted in the vehicle.

  The steam sent from the inflow nozzle 20 to the inside of the steam turbine 1 is discharged from the outflow nozzle 21 through the inside of the steam turbine 1 and sent to the cooling device 24. The steam is liquefied by the cooling device 24 and sent to the water boiler 22 again, and the same operation is repeated.

  With the configuration as described above, exhaust gas generated in the engine 40 is effectively used, and steam is supplied to the steam turbine 1, whereby driving power and power can be supplied to the turbo fan 41 and the power source 42, and gasoline and the like can be consumed. Can be reduced.

It is a perspective view which shows the detail of each member which comprises the steam turbine shown as embodiment. (A) is an elevation which shows the detail of each member which comprises a steam turbine, (b) is an elevation which shows the detail of a housing cover member. It is a figure which shows the structure of the boiler mechanism to which the steam turbine shown as embodiment is applied.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Steam turbine 2 Housing 3 Rotor blade member 4 Rotor 5 Rotor shaft 10 Nozzle 22 Water boiler 24 Cooling device

Claims (4)

A housing into which steam supplied from outside flows in;
A plurality of rotor blades for receiving the steam flowing into the housing and rotating the rotor,
A steam turbine, wherein the housing is formed with a stationary blade that expands and discharges the flow-in steam. The stationary blades are nozzles formed in a plurality on the housing,
2. The steam turbine according to claim 1, wherein the plurality of nozzles are arranged to allow steam discharged from an outlet of one nozzle to flow from an inlet of another adjacent nozzle. 3. . The plurality of blades are formed radially with respect to the rotor,
From the discharge port of the one nozzle, steam is discharged into a space formed between adjacent blades among the plurality of blades.
The steam discharged into the space flows from the inlet of the other nozzle as the space moves to a position facing the inlet of the other nozzle as the rotor rotates. The steam turbine according to claim 2. A boiler that vaporizes the liquid stored inside using the heat of the high-temperature gas discharged from the outside;
A steam turbine for converting energy of steam vaporized by the boiler into power;
A cooling device for cooling and liquefying the steam supplied from the steam turbine,
The steam turbine is
A housing into which steam supplied from the boiler flows,
A plurality of moving blades for rotating the rotor in response to the steam that has flowed into the housing, wherein the housing is formed with a stationary blade that expands and discharges the flowed-in steam. Boiler system.