JP2015004313A - Gas turbine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cooling medium supply structure with small leakage of a cooling medium during supplying the cooling medium as well as with small head loss in a gas turbine requiring the supply of the turbine cooling medium from a stationary system to a rotary system.SOLUTION: The present turbine comprises: a stator vane row; a moving blade row arranged on the combustion gas flow direction upstream side of the stator vane row or on the combustion gas flow direction downstream side thereof; a diaphragm arranged on the rotary shaft side of the stator vane row; a spacer that connects to the rotary shaft to face the diaphragm; and a seal structure provided between the inner peripheral surface of the diaphragm and the outer peripheral surface of the spacer. The turbine further comprises: a coolant supply hole for supplying the coolant that has passed through the inner peripheral surface of the diaphragm; and a coolant introduction hole provided on the outer peripheral surface side of the spacer for introducing the coolant from the coolant supply hole to the interior of the rotary shaft, in which the radius positions of a coolant outlet of the coolant supply hole and a coolant inlet of the coolant introduction hole are established on the rotary shaft center side rather than the radius position of the leakage part of the seal structure.

Description

  The present invention relates to a gas turbine and a turbine blade cooling method for a gas turbine.

  Turbine blades exposed to high-temperature combustion gas may be cooled by air extracted from a compressor in order to prevent oxidation, corrosion, creep deformation, and the like. In the past, the temperature of the mainstream gas flowing around the blades on the rear stage side of the turbine was not high enough to require cooling, so the blades on the rear stage side of the turbine were not cooled. However, in recent years, there is a tendency to increase the combustion temperature of the gas turbine from the viewpoint of improving efficiency. As the combustion temperature becomes higher, it is necessary to cool the blades on the rear stage side of the turbine.

  Therefore, a gas turbine having a high combustion temperature is provided with a cooling air supply path for cooling the rear stage blades. For example, Patent Document 1 discloses a technique using a third stage stationary blade as a cooling air supply path for supplying cooling air to a third stage moving blade of a single-shaft gas turbine. Patent Document 2 discloses a low-pressure turbine as a cooling air supply path for supplying cooling air to the first stage blades of a low-pressure turbine of a two-shaft gas turbine having a shaft system in which a high-pressure turbine and a low-pressure turbine are independent. A technique using the second stage stationary blade is disclosed.

JP 2000-310127 A JP 2011-208504 A

  The configurations disclosed in Patent Document 1 and Patent Document 2 are a part of the stationary blade diaphragm and the rotor when the cooling air supplied to the rear stage moving blade is introduced from the stationary system to the rotating system. It is configured to be introduced into an annular cavity defined by a spacer and a seal. When the cooling medium from the stationary system is once filled into the cavity defined by the seal structure and then introduced into the rotating system, a leakage of the cooling medium from the seal structure and pressure loss due to sudden expansion and contraction of the refrigerant flow path occur. . Such a coolant leakage or pressure loss is one of the factors that reduce the output and thermal efficiency of the gas turbine.

  An object of the present invention is to suppress a decrease in output and thermal efficiency of a gas turbine having a cooling medium supply structure for supplying a turbine cooling medium from a stationary system to a rotating system.

  The present invention includes a compressor that generates compressed air, a combustor that generates combustion gas by burning compressed air and fuel generated by the compressor, and a rotating shaft that is generated by the combustion gas generated by the combustor. The turbine of the gas turbine having a turbine that is driven to rotate around the stationary turbine row is attached to the stationary blade row and the rotating shaft, and is disposed on the upstream side or the downstream side in the combustion gas flow direction of the stationary blade row. A moving blade row, a diaphragm disposed on the rotating shaft side of the stationary blade row, a spacer facing the diaphragm and connected to the rotating shaft, an inner peripheral surface of the diaphragm, and an outer peripheral surface of the spacer And a seal structure that suppresses or reduces fluid flow, and includes a refrigerant supply hole that passes through the inner peripheral surface of the diaphragm and supplies the refrigerant for the moving blade, and the outer peripheral surface of the spacer On the side, said A refrigerant introduction hole that receives the refrigerant from the medium supply hole and guides the refrigerant to the inside of the rotation shaft, and the radial position of the refrigerant outlet of the refrigerant supply hole and the refrigerant inlet of the refrigerant introduction hole is greater than the radial position of the leak portion of the seal structure. Is also on the rotational axis center side.

  ADVANTAGE OF THE INVENTION According to this invention, the output of a gas turbine provided with the cooling medium supply structure which supplies a turbine cooling medium from a stationary system to a rotating system, and the fall of thermal efficiency can be suppressed.

1 is a partial view of a meridional section of a gas turbine that is an embodiment of the present invention. 1 is a partial view of an axial cross section of a gas turbine according to an embodiment of the present invention. 1 is a partial view of a meridional section of a gas turbine that is an embodiment of the present invention. 1 is a partial view of an axial cross section of a gas turbine according to an embodiment of the present invention. 1 is a partial view of a meridional section of a gas turbine that is an embodiment of the present invention. 1 is a partial view of an axial cross section of a gas turbine according to an embodiment of the present invention. 1 is a schematic configuration diagram of a gas turbine that is an embodiment of the present invention. 1 is a partial view of a meridional section of a gas turbine that is an embodiment of the present invention.

  Unlike a single-shaft gas turbine, a two-shaft gas turbine is divided into a low-pressure turbine shaft and a high-pressure turbine shaft. Therefore, it is difficult to apply the cooling air supply method to the high pressure turbine side such as the first stage moving blade and the second stage moving blade as it is to the blade on the low pressure turbine shaft side of the two-shaft gas turbine. For example, it is difficult to provide, as a cooling air passage from the compressor discharge section, a passage in which a cooling air passage provided in the center of the rotor is directly connected to the turbine rear blade section.

  Also, techniques that can be easily applied to single-shaft gas turbines are often difficult to adopt for twin-shaft gas turbines. For example, in the invention described in Patent Document 1, a cooling air passage extending from the third stage stationary blade portion to the third stage moving blade portion is formed in the single-shaft gas turbine. However, in the two-shaft gas turbine, there is no shaft on the inner peripheral side of the third stage stationary blade. Therefore, compared with the third stage blade non-cooled gas turbine, a new design change or construction such as extension of the shaft is required, and the time, labor, and cost required for the design and manufacture of the turbine increase. When making such a design change, it is usually necessary to change the design in many other places. If it is said that the reliability accumulated in the operation results of the conventional machine cannot be inherited, more time is required for a test for ensuring the reliability. This effect is particularly significant in large power generation facilities such as gas turbines.

  Thus, hereinafter, as an embodiment of the present invention, a structural example of a two-shaft gas turbine will be described with reference to the drawings. It should be noted that the refrigerant supply structure of each embodiment described below is applicable to a single-shaft gas turbine and is not limited to a two-shaft gas turbine.

  First, the configuration of a two-shaft gas turbine that is an embodiment of the present invention will be described with reference to FIG.

  FIG. 7 is a schematic configuration diagram of a two-shaft gas turbine. The two-shaft gas turbine is mainly composed of a gas generator and a power turbine. The gas generator is mainly composed of a compressor 1, a combustor 2 and a high-pressure turbine 3. The power turbine is composed of a low-pressure turbine 4. The compressor 1 compresses the atmospheric air 11 to generate compressed air 12, and sends the generated compressed air 12 to the combustor 2. The combustor 2 generates a combustion gas 14 by mixing and burning the generated compressed air 12 and the fuel 13 and sends the combustion gas 14 to the high-pressure turbine 3.

  The high-pressure turbine 3 generates a rotational force on the high-pressure turbine shaft 6 by the combustion gas 14 having a high energy sent from the combustor 2. The low-pressure turbine 4 collects the energy of the combustion gas 15 sent from the high-pressure turbine 3 to generate a rotational force on the low-pressure turbine shaft 4. The load 5 connected to the low pressure turbine 4 is driven by the rotational force of the low pressure turbine shaft. The combustion gas 15 is exhausted as exhaust 16 after energy is recovered by the low-pressure turbine 4.

  As shown in FIG. 7, the gas generator including the high-pressure turbine 3 and the power turbine including the low-pressure turbine 4 are independent rotating shafts. That is, the high pressure turbine shaft and the low pressure turbine shaft rotate independently of each other.

  FIG. 8 shows a partial cross-sectional view of a two-shaft gas turbine. Elements having the same reference numerals as in FIG. 7 are the same elements. FIG. 8 shows the first stage stationary blade 31n, the first stage stationary blade 31b, the second stage stationary blade 32n, the second stage stationary blade 32b, the third stage stationary blade 43n, the third stage stationary blade 43b, the fourth stage stationary blade 44n, and the fourth stage stationary blade. 44b, a partition plate 41 is shown.

  The compressor 1, the high pressure side intermediate rotary shaft 6, the first stage wheel 31w having the first stage blade 31b assembled on the outer periphery side, the high pressure side spacer 32s, and the second stage blade 32b assembled on the outer periphery side. The second stage wheel 32w thus formed is connected by a stacking bolt to constitute a high-pressure turbine shaft. The combustion gas 14 works in the high-pressure turbine 3 and generates rotational power on the high-pressure turbine shaft. The generated power is consumed as driving power for the compressor 1.

  Similarly, the third-stage wheel 43w having the third-stage moving blade 43b assembled on the outer peripheral side, the low-pressure side spacer 44s, and the fourth-stage wheel 44w having the fourth-stage moving blade 44b assembled on the outer peripheral side are stacked. Connected by bolts to form a low-pressure turbine shaft. The combustion gas 15 works in the low-pressure turbine 4 and generates rotational power in the low-pressure turbine shaft. The load 5 is driven by the generated power.

  The third stage stationary blade 43n is attached to the gas turbine casing, and is installed between the second stage moving blade 32b and the third stage moving blade 43b. A partition plate 41, which is a partition member that separates the high-pressure turbine 3 and the low-pressure turbine 4, is disposed between the high-pressure turbine 3 and the low-pressure turbine 4, and is fixed to the third-stage stationary blade 43n via a third-stage stationary blade diaphragm 43d. .

  The fourth stage stationary blade 44n is attached to the turbine casing, and is installed between the third stage moving blade 43b and the fourth stage moving blade 44b. A fourth stage stationary blade diaphragm 44d is attached to the inner peripheral side of the fourth stage stationary blade 44n.

  The cooling air supply structure to the third stage rotor blade 43b will be described with reference to FIGS. FIG. 1 is a partial cross-sectional view including a third stage moving blade 43b, a fourth stage stationary blade 44n, and a fourth stage moving blade 44b of the gas turbine according to the present embodiment. FIG. 2 is a view of a cross section AA in FIG. 1 as viewed in the direction of the arrow. 1, 2, 7, and 8, the elements having the same reference numerals are the same elements.

  A cavity is formed in the outer peripheral portion of the fourth stage stationary blade 44n, and a bleed pipe extending from the intermediate stage of the compressor 1 is connected thereto. A part of the air is extracted as cooling air from the compressor 1 and guided to the cavity through the extraction pipe.

  The fourth stage stationary blade 44n has a hollow structure and communicates with the outer peripheral cavity. A fourth stage stationary blade diaphragm 44d is attached to the inner peripheral side of the fourth stage stationary blade 44n to form a cavity. That is, the cooling air guided to the outer peripheral cavity passes through the fourth stage stationary blade 44n and is guided to the inner peripheral cavity 44i. The cooling air performs convection cooling when passing through the fourth stage stationary blade 44n.

  A front orifice 44p and a rear orifice 44q are formed in the fourth stage stationary blade diaphragm 44d. A part of the cooling air guided to the inner peripheral cavity 44i passes through the front orifice 44p and is ejected to the wheel space 44e which is an axial gap between the third stage moving blade 43b and the fourth stage stationary blade 44n. The cooling air thus ejected prevents the mainstream gas from entering the wheel space 44e. Further, the remaining cooling air guided to the inner peripheral cavity 44i passes through the rear orifice 44q and is ejected into the wheel space 44f which is the axial gap between the fourth stage stationary blade 44n and the fourth stage rotor blade 44b. The cooling air ejected prevents mainstream gas from entering the wheel space 44f.

  Between the third-stage wheel 43w in which the third-stage moving blade 43b is implanted and the fourth-stage wheel 44w in which the fourth-stage moving blade 44b is implanted, a third and fourth inter-stage spacer 44s is provided. Is incorporated. The outer peripheral surface of the spacer 44s and the inner peripheral surface of the fourth stage stationary blade diaphragm 44d face each other, and a honeycomb seal 44h is formed between both surfaces. When the static pressures of the wheel space 44e and the wheel space 44f described above are compared, the wheel space 44e is higher. The honeycomb seal 44h suppresses or reduces a gas flow, that is, leakage, from the wheel space 44e to the wheel space 44f caused by the static pressure difference.

  Next, the refrigerant supply structure to the moving blade via the stationary blade will be described. In the present embodiment, the refrigerant supply pipe 81A is connected to the outer peripheral cavity of the fourth stage stationary blade 44n described above. The refrigerant supply pipe 81A passes through the inner peripheral surface of the diaphragm through the fourth stage stationary blade 44n and the fourth stage stationary blade diaphragm 44d, and extends from the inner peripheral surface of the fourth stage stationary blade diaphragm 44d to the third fourth interstage spacer 44s. The structure extends toward the outer peripheral surface. The outlet of the refrigerant supply pipe 81A is formed so that the speed of the jetted refrigerant has a radially inner component and a circumferential component in the same direction as the rotation direction of the spacer 44s. With such a configuration, the refrigerant ejected from the refrigerant supply pipe 81A can easily flow into the refrigerant introduction hole 82, so that leakage can be reduced.

  On the other hand, a groove is formed in the spacer 44s over the entire circumference in the circumferential direction, and spacer refrigerant introduction holes 82 are formed intermittently in the circumferential direction from the bottom surface of the groove toward the inner circumferential surface of the spacer 44s. The size of the introduction hole is almost the same as the outlet of the refrigerant supply pipe. In the present embodiment, the spacer refrigerant introduction hole 82 is formed such that the direction of the circumferential component of the relative speed when the refrigerant passes through the refrigerant introduction hole 82 is opposite to the rotation direction of the spacer 44s. . Even with such a configuration, the refrigerant can easily flow into the refrigerant introduction hole 82, so that leakage can be reduced.

  The cooling air guided to the outer peripheral side cavity of the fourth stage stationary blade 44n flows through the refrigerant supply pipe 81A and is ejected. The ejected refrigerant (cooling air) has a radially inner component and a circumferential component in the same direction as the rotation direction of the spacer 44s. When the circumferential phase does not coincide with the spacer refrigerant introduction hole 82, the refrigerant is once inserted into the groove. Along the circumferential direction, flows into the refrigerant introduction hole 82, and is guided to the third and fourth wheel cavities 44c. In this case, when the flow path is viewed from the refrigerant, it rapidly expands when flowing from the refrigerant supply pipe 81 </ b> A into the ejection groove and rapidly contracts when flowing into the spacer refrigerant introduction hole 82.

  On the other hand, when the circumferential phase coincides with the spacer coolant introduction hole 82, it flows directly into the coolant introduction hole 82 and is guided to the third and fourth wheel cavities 44c. In this case, when the flow path is viewed from the refrigerant, it immediately flows into the spacer refrigerant introduction hole 82 after being ejected from the refrigerant supply pipe 81A, so there is no sudden expansion or contraction of the flow path observed when the phases do not match. .

  The refrigerant guided to the third and fourth wheel cavities 44c passes through a slit 43j formed on the bottom surface of the third stage moving blade 43b, and is guided to a refrigerant flow path 43k formed inside the moving blade, thereby moving the moving blade 43b. Cool down.

  Thus, in this embodiment, the radial position of the refrigerant outlet of the refrigerant supply pipe 81A and the refrigerant inlet of the refrigerant introduction hole 82 is the radial position of the tooth tip corresponding to the leak portion of the honeycomb seal 44h formed on the outer peripheral surface of the spacer 44s. Is set closer to the rotation axis center side. According to the configuration of the present embodiment in which the tooth tip of the honeycomb seal 44h through which the leak flow from the wheel space 44e to the wheel space 44f passes and the radial position of the refrigerant outlet of the refrigerant supply pipe 81A are different, the refrigerant outlet Since the jetted cooling medium can be prevented from flowing directly to the outer peripheral side of the tooth tip, which is a leak site, it is possible to suppress or reduce a decrease in the supply path of the moving blade refrigerant.

  Further, in the configuration of the present embodiment, the refrigerant supply pipe 81A is inserted into the groove extending in the circumferential direction of the spacer 44s, and the refrigerant introduction hole 82 is formed in the groove, so that the refrigerant flows directly into the leak portion. This can be prevented more remarkably.

  In the gas turbine design, the refrigerant flow rate to be extracted from the compressor is determined in consideration of the decrease rate in the middle of the supply path. If the decrease rate is reduced, the amount extracted from the compressor can be reduced. Therefore, according to the configuration of the present embodiment that suppresses the decrease in the refrigerant, the gas turbine output and the thermal efficiency can be improved.

  In this embodiment, the outlet of the refrigerant supply pipe 81A is arranged so as to face the bottom surface of the groove, and the refrigerant inlet of the refrigerant introduction hole 82 is formed on the bottom surface of the groove. Thereby, when the phase of the outlet of the refrigerant supply pipe 81A coincides with the phase of the spacer refrigerant introduction hole 82, the flow path reaches the third and fourth wheel cavities 44c because there is no sudden expansion or contraction of the flow path when viewed from the refrigerant. The pressure loss up to can be reduced.

  In the gas turbine design, the refrigerant pressure to be extracted from the compressor is determined in consideration of the pressure loss along the supply path. If the pressure loss is reduced, the pressure of the refrigerant extracted from the compressor can be reduced. Therefore, according to the configuration of the present embodiment, the average pressure loss is reduced by periodically matching the phases of the outlet of the refrigerant supply pipe 81A and the spacer refrigerant introduction hole 82, so that the gas turbine output and the thermal efficiency are reduced. Can be improved.

  Next, a second embodiment will be described with reference to FIGS. FIG. 3 is a partial cross-sectional view including the third stage moving blade 43b, the fourth stage stationary blade 44n, and the fourth stage moving blade 44b of the gas turbine according to the present embodiment. FIG. 4 is a view of section AA in FIG. 3 as seen in the direction of the arrow. 1 to 4, 7, and 8, elements having the same reference numerals are the same elements. Hereinafter, description of the same structure as that of the first embodiment will be omitted, and different structures will be mainly described.

  In the present embodiment, a refrigerant ejection hole 81B is formed on the inner peripheral surface side of the fourth stage stationary blade diaphragm 44d. The refrigerant supply pipe 81B has a structure extending from the inner peripheral surface of the fourth stage stationary blade diaphragm 44d toward the outer peripheral surface of the third fourth inter-stage spacer 44s. The jet outlet of the refrigerant supply pipe 81B is formed such that the speed of the jetted refrigerant has a radially inner component and a circumferential component in the same direction as the rotation direction of the spacer 44s.

  On the other hand, a groove is formed in the spacer 44s over the entire circumference in the circumferential direction, and spacer refrigerant introduction holes 82 are formed intermittently in the circumferential direction from the bottom surface of the groove toward the inner circumferential surface of the spacer 44s. The size of the introduction hole is almost the same as the outlet of the refrigerant supply pipe. In the present embodiment, the spacer refrigerant introduction hole 82 is formed such that the direction of the circumferential component of the relative speed when the refrigerant passes through the refrigerant introduction hole 82 is opposite to the rotation direction of the spacer 44s. .

The cooling air guided to the fourth stage stationary blade diaphragm cavity 44i flows through the refrigerant supply pipe 81B and is ejected. The ejected refrigerant has a radially inner component and a circumferential component in the same direction as the rotation direction of the spacer 44s. When the circumferential phase does not coincide with the spacer coolant introduction hole 82, the circumferential direction is once along the groove. , Flows into the refrigerant introduction hole 82, and is guided to the third and fourth wheel cavities 44c. In this case, when the flow path is viewed from the refrigerant, it rapidly expands when flowing into the ejection groove from the refrigerant supply pipe 81 </ b> B and rapidly contracts when flowing into the spacer refrigerant introduction hole 82.

  On the other hand, when the circumferential phase coincides with the spacer coolant introduction hole 82, it flows directly into the coolant introduction hole 82 and is guided to the third and fourth wheel cavities 44c. In this case, when the flow path is viewed from the refrigerant, since it flows through the spacer refrigerant introduction hole 82 immediately after being ejected from the refrigerant supply pipe 81B, there is no sudden expansion or contraction of the flow path observed when the phases do not match. .

  The refrigerant guided to the third and fourth wheel cavities 44c passes through a slit 43j formed on the bottom surface of the third stage moving blade 43b, and is guided to a refrigerant flow path 43k formed inside the moving blade, thereby moving the moving blade 43b. Cool down.

  As described above, in the present embodiment, the radial position of the refrigerant outlet of the refrigerant supply pipe 81B and the refrigerant inlet of the refrigerant introduction hole 82 is the radial position of the tooth tip corresponding to the leak portion of the honeycomb seal 44h formed on the outer peripheral surface of the spacer 44s. Is set closer to the rotation axis center side. By making the radial positions of the tooth tips of the honeycomb seal 44h through which the leak flow from the wheel space 44e to the wheel space 44f passes and the radial position of the refrigerant jet outlet of the refrigerant supply pipe 81B differ, the cooling medium ejected from the refrigerant jet outlet leaks. It is possible to prevent a direct flow to the outer peripheral side of the tooth tip, which is a part, and to suppress or reduce a decrease in the supply path of the moving blade coolant.

  Further, in the present embodiment, as a more specific configuration, the refrigerant supply pipe 81B is inserted into the groove extending in the circumferential direction of the spacer 44s, and the refrigerant introduction hole 82 is formed in the groove. Direct inflow can be prevented more remarkably. In order to make the flow velocity or pressure of the refrigerant flowing through the annular space formed by the stationary blade diaphragm and the rotor uniform, it is preferable that the portion where the refrigerant supply pipe protruding to the annular space is provided is as small as possible. In addition, as shown in FIG. 4, by tilting the protruding portion with respect to the radial direction, it is possible to reduce the disturbance of the refrigerant flow, and the flow velocity or pressure tends to be uniform.

  In the gas turbine design, the refrigerant flow rate to be extracted from the compressor is determined in consideration of the decrease rate in the middle of the supply path. If the decrease rate is reduced, the amount extracted from the compressor can be reduced. Therefore, according to the configuration of the present embodiment that suppresses the decrease in the refrigerant, the gas turbine output and the thermal efficiency can be improved.

  In this embodiment, the outlet of the refrigerant supply pipe 81B is disposed so as to face the bottom surface of the groove, and the refrigerant inlet of the refrigerant introduction hole 82 is formed on the bottom surface of the groove. Thereby, when the phase of the outlet of the refrigerant supply pipe 81B and the spacer refrigerant introduction hole 82 coincide with each other, there is no sudden expansion and contraction of the flow path when viewed from the refrigerant, so that the third and fourth wheel cavities 44c are reached. The pressure loss up to can be reduced.

  In the gas turbine design, the refrigerant pressure to be extracted from the compressor is determined in consideration of the pressure loss along the supply path. If the pressure loss is reduced, the pressure of the refrigerant extracted from the compressor can be reduced. Therefore, according to the configuration of the present embodiment, since the average pressure loss is reduced by periodically matching the phases of the outlet of the refrigerant supply pipe 81B and the spacer refrigerant introduction hole 82, the gas turbine output and the thermal efficiency are reduced. Can be improved.

  In this embodiment, the refrigerant ejection hole 81B is integrated with the fourth stage stationary blade diaphragm 44d. However, the refrigerant ejection hole 81B may be a separate part and assembled to the fourth stage stationary blade diaphragm 44d.

  Next, a third embodiment will be described with reference to FIGS. FIG. 5 is a partial cross-sectional view including the third stage moving blade 43b, the fourth stage stationary blade 44n, and the fourth stage moving blade 44b of the gas turbine according to the present embodiment. 6 is a cross-sectional view taken along the line AA in FIG. 5 in the direction of the arrow. 1 to 8, the elements having the same reference numerals are the same elements. A description of the same structure as in the first and second embodiments will be omitted, and a different structure will be mainly described.

  In the present embodiment, similarly to the second embodiment, a refrigerant ejection hole 81B is formed on the inner peripheral surface side of the fourth stage stationary blade diaphragm 44d. The refrigerant supply pipe 81B has a structure extending from the inner peripheral surface of the fourth stage stationary blade diaphragm 44d toward the outer peripheral surface of the third fourth inter-stage spacer 44s. The jet outlet of the refrigerant supply pipe 81B is formed such that the speed of the jetted refrigerant has a radially inner component and a circumferential component in the same direction as the rotation direction of the spacer 44s.

  On the other hand, a groove is formed in the spacer 44s over the entire circumference in the circumferential direction, and spacer refrigerant introduction holes 82 are formed intermittently in the circumferential direction from the bottom surface of the groove toward the inner circumferential surface of the spacer 44s. The size of the introduction hole is almost the same as the outlet of the refrigerant supply pipe. A labyrinth seal 83 is formed on the side surface in the axial direction of the groove. In the present embodiment, the spacer refrigerant introduction hole 82 is formed such that the direction of the circumferential component of the relative speed when the refrigerant passes through the refrigerant introduction hole 82 is opposite to the rotation direction of the spacer 44s. .

  The cooling air guided to the fourth stage stationary blade diaphragm cavity 44i flows through the refrigerant supply pipe 81B and is ejected. The ejected refrigerant has a radially inner component and a circumferential component in the same direction as the rotation direction of the spacer 44s. When the circumferential phase does not coincide with the spacer coolant introduction hole 82, the circumferential direction is once along the groove. , Flows into the refrigerant introduction hole 82, and is guided to the third and fourth wheel cavities 44c. In this case, when the flow path is viewed from the refrigerant, it rapidly expands when flowing into the ejection groove from the refrigerant supply pipe 81 </ b> B and rapidly contracts when flowing into the spacer refrigerant introduction hole 82.

  On the other hand, when the circumferential phase coincides with the spacer coolant introduction hole 82, it flows directly into the coolant introduction hole 82 and is guided to the third and fourth wheel cavities 44c. In this case, when the flow path is viewed from the refrigerant, since it flows through the spacer refrigerant introduction hole 82 immediately after being ejected from the refrigerant supply pipe 81B, there is no sudden expansion or contraction of the flow path observed when the phases do not match. .

  The refrigerant guided to the third and fourth wheel cavities 44c passes through a slit 43j formed on the bottom surface of the third stage moving blade 43b, and is guided to a refrigerant flow path 43k formed inside the moving blade, thereby moving the moving blade 43b. Cool down.

  As described above, in the present embodiment, the radial position of the refrigerant outlet of the refrigerant supply pipe 81B and the refrigerant inlet of the refrigerant introduction hole 82 is the radial position of the tooth tip corresponding to the leak portion of the honeycomb seal 44h formed on the outer peripheral surface of the spacer 44s. Is set closer to the rotation axis center side. By making the radial positions of the tooth tips of the honeycomb seal 44h through which the leak flow from the wheel space 44e to the wheel space 44f passes and the radial position of the refrigerant jet outlet of the refrigerant supply pipe 81B differ, the cooling medium ejected from the refrigerant jet outlet leaks. It is possible to prevent a direct flow to the outer peripheral side of the tooth tip, which is a part, and to suppress or reduce a decrease in the supply path of the moving blade coolant.

  Furthermore, in the present embodiment, the labyrinth seal 83 provided on the side surface of the groove also causes the cooling medium ejected from the coolant ejection port to flow directly to the outer peripheral side of the tooth tip, which is the leak site of the honeycomb seal 44h. Therefore, it is possible to more significantly suppress or reduce the decrease in the supply path of the moving blade refrigerant.

  In the gas turbine design, the refrigerant flow rate to be extracted from the compressor is determined in consideration of the decrease rate in the middle of the supply path. If the decrease rate is reduced, the amount extracted from the compressor can be reduced. Therefore, according to the configuration of the present embodiment that further suppresses the decrease of the refrigerant by the action of the labyrinth seal 83, the gas turbine output and the thermal efficiency can be further improved.

  In this embodiment, the outlet of the refrigerant supply pipe 81B is disposed so as to face the bottom surface of the groove, and the refrigerant inlet of the refrigerant introduction hole 82 is formed on the bottom surface of the groove. Thereby, when the phase of the outlet of the refrigerant supply pipe 81B and the spacer refrigerant introduction hole 82 coincide with each other, there is no sudden expansion and contraction of the flow path when viewed from the refrigerant, so that the third and fourth wheel cavities 44c are reached. The pressure loss up to can be reduced.

  In the gas turbine design, the refrigerant pressure to be extracted from the compressor is determined in consideration of the pressure loss along the supply path. If the pressure loss is reduced, the pressure of the refrigerant extracted from the compressor can be reduced. Therefore, according to the configuration of the present embodiment, since the average pressure loss is reduced by periodically matching the phases of the outlet of the refrigerant supply pipe 81B and the spacer refrigerant introduction hole 82, the gas turbine output and the thermal efficiency are reduced. Can be improved.

1: compressor, 2: combustor, 3, 4: turbine, 6, 7: rotating shaft, 43b, 44b: moving blade, 44c: inside rotating shaft, 44d: diaphragm, 44h: seal, 44n: stationary blade, 44s : Spacer, 81A: 81B: Refrigerant supply hole, 83: Groove, 84: Seal

Claims (6)

A compressor that generates compressed air, a combustor that generates combustion gas by burning compressed air and fuel generated by the compressor, and a rotation axis that is rotated about the rotation axis by the combustion gas that is generated by the combustor A gas turbine comprising a driving turbine,
The turbine includes a stationary blade row;
A moving blade row attached to the rotating shaft and disposed upstream or downstream in the combustion gas flow direction of the stationary blade row;
A diaphragm disposed on the rotating shaft side of the stationary blade row;
A spacer facing the diaphragm and connected to the rotating shaft;
A seal structure provided between the inner peripheral surface of the diaphragm and the outer peripheral surface of the spacer for suppressing or reducing fluid flow;
A refrigerant supply hole that passes through the inner peripheral surface of the diaphragm and supplies a refrigerant for the moving blade;
On the outer peripheral surface side of the spacer, a refrigerant introduction hole that receives the refrigerant from the refrigerant supply hole and guides it into the rotating shaft,
The gas turbine according to claim 1, wherein a radial position of a refrigerant outlet of the refrigerant supply hole and a refrigerant inlet of the refrigerant introduction hole is closer to the rotation shaft center side than a radial position of a leak portion of the seal structure. The gas turbine according to claim 1, wherein
The outer peripheral surface of the spacer includes a groove extending in the circumferential direction of the rotating shaft,
The gas turbine, wherein the refrigerant supply hole is inserted into the groove, and the refrigerant introduction hole is formed in the groove. The gas turbine according to claim 2, wherein
The refrigerant outlet of the refrigerant supply hole faces the bottom surface of the groove,
A gas turbine, wherein a refrigerant inlet of the refrigerant introduction hole is formed on a bottom surface of the groove. The gas turbine according to claim 2 or 3,
A gas turbine comprising a seal structure for suppressing or reducing leakage of refrigerant supplied from the refrigerant supply hole on a side surface of the groove. In the gas turbine according to any one of claims 1 to 4,
The gas turbine, wherein the refrigerant supply hole is formed so that the refrigerant to be ejected has a radially inward velocity component and a circumferential velocity component in the same direction as the rotation direction of the rotating shaft. In the gas turbine according to any one of claims 1 to 4,
The direction of the circumferential component of the relative speed with respect to the rotation axis when the refrigerant flowing into the rotation axis passes through the refrigerant introduction hole is opposite to the rotation direction of the rotation axis. It is formed in the gas turbine characterized by the above-mentioned.