JP2012098027A - Combustor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a structure that strikes a balance between a low NOx and a combustion stability, in a gas turbine combustor.SOLUTION: The combustor 2 includes: a combustion chamber 50 from which fuel and air are supplied; an air hole plate 33, which is located in an upstream side of the combustion chamber 50, and which has a plurality of air holes 32; and a fuel nozzle 31 for supplying fuel to the air holes 32 of the air hole plate 33. The air hole plate has an inner peripheral side plane and an outer peripheral side plane, which are the planes vertical to a central axis direction of the air hole plate in a combustion chamber side, respectively. The inner peripheral side plane is located in a downstream side more than the outer peripheral side plane, and the inner peripheral side plane is connected with the outer peripheral side plane by the plane or a smooth surface.

Description

  The present invention relates to a combustor and an operating method thereof.

  Environmental regulations and social demands are increasing day by day, and even higher efficiency and lower NOx are required for gas turbines.

  As one measure for improving the efficiency of the gas turbine, it is conceivable to raise the turbine inlet gas temperature. In this case, however, there is a concern about an increase in NOx emissions as the flame temperature rises in the gas turbine combustor. .

  Patent Document 1 includes a fuel nozzle that supplies fuel to a combustion chamber, and an oxidant nozzle that is located downstream of the fuel nozzle and that supplies oxidant. A fuel combustion nozzle having a hole and a coaxial arrangement is disclosed. Moreover, in patent document 1, in order to enable re-ignition even if the flame produced | generated by the coaxial jet by fuel and air blows off, the outer peripheral side member of the plate provided with the oxidizer nozzle is formed thicker than the center side member. (Fig. 1).

JP 2005-106305 A

  However, Cited Document 1 does not consider NOx reduction.

  Therefore, an object of the present invention is to provide a structure that achieves both low NOx and combustion stability in a combustor.

  The present invention includes a combustion chamber for mixing and burning fuel and air, an air hole plate forming an upstream side wall of the combustion chamber, and a plurality of holes formed in the air hole plate so as to be inclined with respect to a central axis thereof. And a fuel nozzle that supplies fuel to each of the plurality of air holes, wherein the air hole plate is on the combustion chamber side and is perpendicular to the central axis direction of the air hole plate, respectively. An inner peripheral plane that is a plane and an outer peripheral plane, the inner peripheral plane is located downstream of the outer peripheral plane, and the inner peripheral plane and the outer peripheral plane are planes or It is connected with a smooth surface.

  ADVANTAGE OF THE INVENTION According to this invention, the structure which makes low NOx and combustion stability compatible can be provided in a combustor.

It is a partial structure figure which shows the detail of the arrangement condition of the fuel nozzle header which comprises the fuel supply part of the gas turbine combustor in Example 1, a fuel nozzle, and an air hole plate. It is the front view which looked at the air hole plate of Example 1 shown in FIG. 1 from the combustion chamber side. 1 is a plant system diagram showing a schematic configuration of a gas turbine plant to which a gas turbine combustor of Example 1 is applied. It is the figure which showed the flow state of the fuel flow and air flow in a combustion chamber in arrangement | positioning of the fuel nozzle header which comprises the fuel supply part of the gas turbine combustor in Example 1, a fuel nozzle, and an air hole plate. It is a partial structure figure (modification) which shows the details of arrangement conditions of a fuel nozzle header which constitutes a fuel supply part of a gas turbine combustor in Example 1, a fuel nozzle, and an air hole plate. It is a partial structure figure (modification) which shows the details of arrangement conditions of a fuel nozzle header which constitutes a fuel supply part of a gas turbine combustor in Example 1, a fuel nozzle, and an air hole plate. It is the front view (modified example) which looked at the air hole plate of Example 1 shown in FIG. 6 from the combustion chamber side. The figure (modification) which showed the flow state of the fuel flow and air flow in a combustion chamber in arrangement of a fuel nozzle header which constitutes a fuel supply part of a gas turbine combustor which is Example 1, a fuel nozzle, and an air hole plate is there. It is a partial structure figure which shows the detail of the arrangement condition of the fuel nozzle header which comprises the fuel supply part of the gas turbine combustor which is Example 2, a fuel nozzle, and an air hole plate. It is the front view which looked at the air hole plate of Example 2 shown in FIG. 9 from the combustion chamber side. It is a partial structure figure which shows the detail of the arrangement | positioning condition of the fuel nozzle header which comprises the fuel supply part of the gas turbine combustor which is Example 3, a fuel nozzle, and an air hole plate. It is the front view which looked at the air hole plate of Example 3 shown in FIG. 11 from the combustion chamber side. It is a partial structure figure which shows the detail of the arrangement condition of the fuel nozzle header which comprises the fuel supply part of the gas turbine combustor which is Example 4, a fuel nozzle, and an air hole plate. It is the front view which looked at the air hole plate of Example 4 shown in FIG. 13 from the combustion chamber side. It is the figure which expanded the A section and B section of FIG. It is a partial structure figure which shows the detail of the arrangement condition of the fuel nozzle header which comprises the fuel supply part of the gas turbine combustor in Example 5, a fuel nozzle, and an air hole plate. It is the front view which looked at the air hole plate of Example 1 shown in FIG. 16 from the combustion chamber side. FIG. 10 is a partial structural view (modification) showing details of a state of arrangement of a fuel nozzle header, a fuel nozzle, and an air hole plate that constitute a fuel supply unit of a gas turbine combustor in a fifth embodiment. FIG. 10 is a partial structural view (modification) showing details of a state of arrangement of a fuel nozzle header, a fuel nozzle, and an air hole plate that constitute a fuel supply unit of a gas turbine combustor in a fifth embodiment. It is a partial structure figure which shows the detail of the arrangement condition of the fuel nozzle header which comprises the fuel supply part of the gas turbine combustor in Example 6, a fuel nozzle, and an air hole plate. It is the front view which looked at the air hole plate of Example 6 shown in FIG. 20 from the combustion chamber side. It is the front view which looked at the air hole plate of the gas turbine combustor which has arrange | positioned seven burners of Example 6 shown in FIG. 20 from the combustion chamber side. It is an example of the fuel-air ratio conditions in the burner which is supplying the fuel with respect to the gas turbine load of a gas turbine combustor. It is an example of the fuel-air ratio conditions in the burner which is supplying the fuel with respect to the gas turbine load of the gas turbine combustor shown in FIG. It is a partial structure figure which shows the detail of the arrangement condition of the fuel nozzle header which comprises the fuel supply part of the gas turbine combustor in Example 7, a fuel nozzle, and an air hole plate. It is the front view which looked at the air hole plate of Example 7 shown in FIG. 25 from the combustion chamber side. It is a partial structure figure which shows the detail of the arrangement condition of the fuel nozzle header which comprises the fuel supply part of the gas turbine combustor in Example 8, a fuel nozzle, and an air hole plate. It is the front view which looked at the air hole plate of Example 8 shown in FIG. 27 from the combustion chamber side.

  Each example will be described below.

  FIG. 3 is a system diagram showing the overall configuration of the power generation gas turbine plant 1000.

  In FIG. 3, the power generation gas turbine pressurizes the intake air 100 to generate the high-pressure air 101, and the high-pressure air 101 generated by the compressor 1 and the fuel 200 are burned to generate the high-temperature combustion gas 102. The combustor 2 to be generated, the turbine 3 driven by the high-temperature combustion gas 102 generated by the combustor 2, the generator 20 that is rotated by driving the turbine 3 to generate electric power, the compressor 1, the turbine 3, and the generator The shaft 21 which connects 20 integrally is provided.

  The combustor 2 is stored inside the casing 4.

  Further, the combustor 2 includes a burner 6 at the head thereof, and a combustor liner 10 having a substantially cylindrical shape separating high-pressure air and combustion gas inside the combustor 2 on the downstream side of the burner 6.

  On the outer periphery of the combustor liner 10, a flow sleeve 11 serving as an outer peripheral wall that forms an air flow path through which high-pressure air flows down is disposed. The flow sleeve 11 is larger in diameter than the combustor liner 10 and is disposed in a cylindrical shape that is substantially concentric with the combustor liner 10.

  On the downstream side of the combustor liner 10, a tail cylinder inner cylinder 12 for guiding the high-temperature combustion gas 102 generated in the combustion chamber 50 of the combustor 2 to the turbine 3 is disposed. Further, a tail cylinder outer cylinder 13 is disposed on the outer peripheral side of the tail cylinder inner cylinder 12.

  The suction air 100 becomes high-pressure air 101 after being compressed by the compressor 1. After the high pressure air 101 is filled in the casing 4, the high pressure air 101 flows into the space between the tail cylinder inner cylinder 12 and the tail cylinder outer cylinder 13, and convectively cools the tail cylinder inner cylinder 12 from the outer wall surface.

  Furthermore, the high-pressure air 101 flows toward the combustor head through an annular flow path formed between the flow sleeve 11 and the combustor liner 10. The high-pressure air 101 is used for convective cooling of the combustor liner 10 while flowing.

  A part of the high-pressure air 101 flows into the combustor liner from a number of cooling holes provided in the combustor liner 10 and is used for film cooling of the combustor liner 10.

  High-pressure air 101 that has not been used for film cooling of the combustor liner 10 flows into the combustor liner 10 from a number of air holes 32 provided in the air hole plate 33 located on the upstream side wall surface of the combustion chamber 50.

  The high-pressure air 101 that has flowed into the combustor liner 10 from a large number of air holes 32 is combusted in the combustion chamber 50 together with the fuel 200 ejected from the fuel nozzle 31 to generate high-temperature combustion gas 102. This high-temperature combustion gas 102 is supplied to the turbine 3 through the transition piece inner cylinder 12.

  The high-temperature combustion gas 102 is discharged after driving the turbine 3 to become exhaust gas 103.

  The driving force obtained by the turbine 3 is transmitted to the compressor 1 and the generator 20 through the shaft 21.

  Part of the driving force obtained by the turbine 3 drives the compressor 1 to pressurize the air and generate high-pressure air. Further, another part of the driving force obtained by the turbine 3 rotates the generator 20 to generate electric power.

  Next, the configuration of the combustor 2 will be described.

  In the burner 6 of the combustor 2 of the present embodiment, a large number of fuel nozzles 31 for ejecting fuel are attached to the fuel nozzle header 30. Also, a large number of air holes 32 provided in the air hole plate 33 correspond to each one of the fuel nozzles 31 and are located downstream of the corresponding fuel nozzles 31.

  15A and 15B show the arrangement relationship between the pair of fuel nozzles 31 and the air holes 32 in the A part and the B part in the combustor 2 shown in FIG.

  In part A, the air holes 32 provided in the fuel nozzle 31 and the air hole plate 33 are arranged so that the axes of both are located on the same line. On the other hand, in the part B, the central axis of the air hole 32 is inclined with respect to the central axis of the fuel nozzle 31 (details will be described later). Therefore, the cut surface shape of the air hole plate by a plane including the central axis of the air hole plate is expressed as shown in the B part detailed view. In addition, all the air hole shapes in FIGS. 1-14 are represented by a straight pipe shape for convenience. Like the A part and the B part, the air jet 36 flows around the fuel jet 35 inside the air hole. The same number of the coaxial jets of the fuel jet 35 and the air jet 36 are formed as many as the number of pairs of the fuel nozzle 31 and the air holes 32. In the present invention, a pair of a fuel nozzle and an air hole is called a coaxial jet nozzle.

  By forming many small coaxial jets of the fuel jet 35 and the air jet 36, the interface between the fuel and air increases. Therefore, an air-fuel mixture in which mixing of the fuel jet 35 and the air jet 36 is promoted is formed on the outlet side of the air hole 32. By burning this air-fuel mixture in the combustion chamber 50 of the combustor 2, the flame temperature can be made uniform and the amount of NOx generated can be suppressed.

  Further, the burner 6 is provided with two fuel systems of F1 fuel 201 and F2 fuel 202. Each fuel system includes fuel flow rate adjustment valves 211 and 212. The flow rate of the F1 fuel 201 is adjusted by the fuel flow rate adjustment valve 211, and the flow rate of the F2 fuel 202 is adjusted by the fuel flow rate adjustment valve 212. Then, the power generation amount of the gas turbine plant 1000 is controlled.

  FIG. 1 is an enlarged schematic cross-sectional view of a peripheral portion of a fuel nozzle 31 and an air hole 32 in the gas turbine plant of FIG. FIG. 2A is a front view of the air hole plate 33 as viewed from the combustion chamber 50 side.

  In this embodiment, the air holes 32 are concentrically arranged in three rows, and six, twelve, and eighteen air holes 32 are provided from the inner peripheral side of the burner. Each air hole row is defined as a first row of air holes 32a, a second row of air holes 32b, and a third row of air holes 32c from the inner peripheral side.

  Further, in order to form a swirling flow in the combustion chamber 50, the first row of air holes 32a is disposed so as to be inclined by θ with respect to the burner axial direction (the central axis of the fuel nozzle). FIG. 2B shows a view in which the air holes 32a in the first row are cut in the circumferential direction of the burner.

  Further, the fuel system of the present embodiment is divided into two systems: a system that supplies F1 fuel 201 and a system that supplies F2 fuel 202. Here, the F1 fuel 201 is supplied to the fuel nozzle 31a (first fuel nozzle group) corresponding to the first row of air holes 32a, and the F2 fuel 202 is supplied to the second row of air holes 32b and the third row of air holes. The fuel nozzles 31b and 31c (second fuel nozzle group) corresponding to 32c are supplied.

  In this embodiment, the first row of fuel nozzles 31a to which the F1 fuel 201 is supplied and the air holes 32a paired therewith are referred to as an inner circumferential coaxial jet nozzle group 51. The second row of fuel nozzles 31b and the third row of fuel nozzles 31c to which the F2 fuel 202 is supplied, and the second row of air holes 32b and the third row of air holes 32c paired with the second row of fuel nozzles 31b and the third row of fuel nozzles 31c 52. And the part enclosed by the dashed-dotted line of FIG. That is, the burner 6 has an air hole plate and fuel nozzles 31a, 31b, 31c corresponding to the plurality of air holes 32a, 32b, 32c provided in the air hole plate.

  The combustion chamber side wall surface of the air hole plate 33 is a surface on which the air hole outlet is located. And about the combustion chamber side wall surface, an inner peripheral side wall surface is located in a combustion chamber downstream from an outer peripheral side wall surface. Therefore, the outlets of the first row of air holes 32a located on the inner peripheral side wall surface are located on the downstream side of the combustion chamber as compared to the outlets of the third row of air holes 32c located on the outer peripheral side wall surface. In addition, the wall surface of the connecting portion connecting the inner peripheral wall surface and the outer peripheral wall surface on the combustion chamber side with respect to the central axis is set so that the radial distance from the air hole plate central axis decreases on the downstream side compared to the upstream side of the combustion chamber. Is inclined. Therefore, the connection portion wall surface of the air hole plate has a truncated cone shape.

  With such an air hole plate shape, the outer peripheral coaxial jet nozzle group 52 is disposed upstream of the inner peripheral coaxial jet nozzle group 51 in the burner axial direction.

  FIG. 4 shows a schematic shape of a flame and a fluid flow obtained by using the burner of this embodiment.

  The combustion chamber side wall surface of the air hole plate 33 constituting the inner peripheral coaxial jet nozzle group 51 is perpendicular to the burner axis (that is, the center axis of the air hole plate). Therefore, the stagnation regions 42a and 42b are formed in a region near the outlet of the first row of air holes 32a.

  In the vicinity of the stagnation regions 42a and 42b, the flow is stagnated and the flow velocity becomes slow, and there is a portion where the combustion speed and the flow velocity are locally balanced. A flame 41 is formed with a portion where the combustion speed and the flow velocity are balanced as a base point. Furthermore, the air holes 32a in the first row are arranged to be inclined with respect to the burner shaft (the central axis of the air hole plate), and thus a circulation flow 40 is generated. By this circulating flow 40, high-temperature combustion gas is transported from the downstream to the upstream of the flame 41, and thermal energy is transported from the downstream to the upstream. Therefore, the unburned air-fuel mixture supplied from the air holes 32 to the combustion chamber is heated to increase the reactivity, and the combustion stability can be improved. From the above, the inner peripheral coaxial jet nozzle group 51 can be a burner with high combustion stability.

  On the other hand, the outer peripheral coaxial jet nozzle group 52 includes a connecting portion 43 that connects the inner peripheral side wall surface and the outer peripheral side wall surface. The connecting portion wall surface is inclined so that the radial distance from the central axis of the air hole plate of the connecting portion wall surface is closer to the downstream side than the upstream side of the combustion chamber. The wall surface of the connecting portion between the outlet of the second row of air holes 32b and the outlet of the third row of air holes 32c is inclined with respect to the burner axis, so that the flow is difficult to stagnate. Accordingly, no flame is formed in the vicinity of the air hole plate 33 constituting the outer peripheral coaxial jet nozzle group 52. Therefore, as shown in FIG. 4, a flame 41 is formed using the inner peripheral coaxial jet nozzle group 51 as a fire type. In addition, the radial distance from the central axis of the air hole plate of the connection part wall surface is inclined so that the downstream side is closer to the downstream side than the upstream side of the combustion chamber. It can be suppressed and the flow is difficult to stagnate.

  In this embodiment, the coaxial jet fuel and air flowing through the internal flow path of the air hole 32 are mixed in the internal flow path. Further, the flow path is rapidly expanded from the internal flow path to the combustion chamber space. Therefore, even after the fuel and air flow into the combustion chamber, the mixing of the fuel and air further proceeds.

  When the mixing of fuel and air is sufficiently advanced, the local combustion temperature is made uniform. Therefore, the structure of this embodiment is effective for reducing NOx. That is, in the burner configured by a large number of coaxial jets of fuel and air as in the present embodiment, it is desirable to burn the fuel at a position where the mixing of fuel and air has sufficiently progressed. That is, it is preferable to form the flame 41 at a position away from the outlet of the air hole 32.

  In the present embodiment, as shown in FIG. 4, the flame 41 is stably formed based on the inner peripheral coaxial jet nozzle group 51 which is a burner having high combustion stability. Therefore, in the combustion chamber side wall surface of the air hole plate, the inner peripheral side wall surface is formed on the downstream side of the combustion chamber from the outer peripheral side wall surface, so that the outlet of the second row of air holes 32b provided in the outer peripheral coaxial jet nozzle group 52 and A flame 41 is formed away from the outlet of the third row of air holes 32c. That is, the mixing of the fuel and the air proceeds not only at the effect of sudden expansion at the outlet of the air hole 32 but also between reaching the flame 41 from the outlet of the air hole 32. Therefore, in the outer peripheral coaxial jet nozzle group 52, the flame temperature is made uniform and low NOx combustion is realized.

  Thus, by providing the inner peripheral coaxial jet nozzle group and the outer peripheral coaxial jet nozzle group of this embodiment, it is possible to provide a structure that achieves both low NOx and combustion stability.

  In the present embodiment, the connecting portion wall surface connecting the inner peripheral side wall surface and the outer peripheral side wall surface is tapered. However, a similar combustor can also be realized by connecting the inner coaxial jet nozzle group 51 and the outer coaxial jet nozzle group 52 with a curve as shown in FIG.

  That is, if the inner peripheral side wall surface and the outer peripheral side wall surface are connected by a flat surface or a smooth surface, a low NOx effect can be obtained. The distance between the flame formed on the downstream side of the inner peripheral side wall surface and the air holes 32b and 32c provided on the connection surface and the outer peripheral side wall surface can be secured, and the fuel passes through these air holes 32b and 32c. This is because mixing of air and air can be promoted.

  Here, the smooth surface may be a surface that is so smooth that the change in inclination does not cause stagnation or separation of the flow more than necessary. This is because the above-described effect can be obtained if the flame holding of the flame formed near the center of the air hole plate 33 is not significantly adversely affected. As long as this is the case, a combination of planes having different angles with respect to the axial direction or a combination of these and a curved surface may be used.

  In the present embodiment, the inner peripheral side wall surface means the combustion chamber side wall surface of the air hole plate 33 constituting the inner peripheral coaxial jet nozzle group 51. The inner peripheral side wall surface is a plane perpendicular to the central axis direction of the air hole plate 33. The outer peripheral side wall surface is also a plane perpendicular to the central axis direction of the air hole plate 33. In this embodiment, the outer peripheral side wall means the outer surface of the line connecting the air holes 32c shown in FIG.

  Further, in this embodiment, two fuel systems, that is, an F1 fuel 201 supplied to the inner peripheral coaxial jet nozzle group 51 and an F2 fuel 202 supplied to the outer peripheral coaxial jet nozzle group 52 are provided.

  Here, increasing the ratio of the fuel flow rate to the air flow rate is an effective method for improving the combustion stability. That is, by increasing the fuel flow rate per unit supplied to the fuel nozzle 31a as compared to the fuel flow rate per unit supplied to the fuel nozzles 31b and 31c, the fuel flow rate relative to the air flow rate in the inner peripheral coaxial jet nozzle group 51 is increased. And the temperature of the flame holding point of the flame 41 rises. Therefore, the combustion stability of the flame 41 formed by the burner 6 can be enhanced.

  However, merely increasing the flow rate of the F1 fuel 201 ejected from the inner peripheral coaxial jet nozzle group 51 changes the flow rate of the fuel 200 supplied to the entire burner 6, and thus the output obtained also changes. Therefore, in this embodiment, the flow rate ratio of the F1 fuel 201 is increased and at the same time the flow rate ratio of the F2 fuel 202 is decreased. Then, the ratio of the fuel flow rate to the air flow rate can be increased in the inner peripheral coaxial jet nozzle group 51 without increasing the fuel flow rate of the fuel 200 supplied to the entire burner 6.

  That is, in this embodiment, the flow rate of fuel per fuel nozzle supplied to the first fuel nozzle 31a group corresponding to the first air hole 32a group is set to the second air holes 32b and 32c group. More than the corresponding second fuel nozzles 31b and 31c.

  Since the flow rate of the fuel 200 supplied to the entire burner 6 is not changed in this way, the output obtained is not changed. Therefore, the combustion stability of the flame 41 formed by the burner 6 can be enhanced, and an increase in the NOx emission amount discharged from the entire burner 6 can be suppressed.

  FIG. 6 shows a modification in which the width of the connecting portion wall surface connecting the inner peripheral wall surface and the outer peripheral wall surface of the air hole plate is widened. Specifically, the inner peripheral coaxial jet nozzle group 51 has a structure that is tapered from the outermost peripheral position (position A in the figure) of the air hole 32a in the outer peripheral direction.

  Here, FIG. 7 is a front view of FIG. 6 viewed from the combustion chamber 50 side.

  FIG. 8 shows a schematic shape of a flame and a fluid flow obtained by using the burner of FIG. In FIG. 8, the position where the flow velocity and the combustion speed are balanced is formed in the region of the stagnation 42, that is, the inner region of the first row of air holes 32a. Therefore, the flame 41 is formed as shown in FIG.

  Next, the gas turbine combustor of Example 2 will be described with reference to FIG.

  The configuration of the gas turbine combustor according to the present embodiment is the same as the configuration of the gas turbine combustor according to the first embodiment. Therefore, the description of the configuration common to both is omitted and only the configuration that is different is omitted. This will be described below.

  FIG. 9 is an enlarged schematic cross-sectional view of the peripheral portion of the fuel nozzle 31 and the air hole 32, and FIG. 10 is a front view of the air hole plate 33 viewed from the combustion chamber 50.

  In this embodiment, the thickness of the air hole plate 33 is substantially the same in the radial direction. That is, the combustion chamber side wall surface of the air hole plate and the fuel nozzle side wall surface are parallel.

  In the present embodiment, since the thickness of the air hole plate 33 is substantially the same in the radial direction, the internal flow path lengths of all the air holes are also the same. Therefore, the pressure loss generated when the air jet 36 passes through the air hole 32 can be made constant regardless of the position of the air hole 32.

  Further, in order to make all the distances from the ejection holes of the fuel nozzles 31 to the inlets of the air holes 32 the same as the lengths of the fuel nozzles 31 in the third row, the fuel nozzles 31 in the first row and the second row. The length of the. As a result, the flow distribution at the inlet of the air hole can be kept equal, and the inlet pressure loss that occurs when the air jet 36 flows into the air hole 32 can be made constant regardless of the position of the air hole 32.

  In this way, the pressure loss generated when the air jet 36 passes through the air hole 32 and when the air jet 36 flows into the air hole 32 is made constant regardless of the position of the air hole 32. The pressure difference between the upstream side and the downstream side of the air hole plate 33 is made constant regardless of the position of the air hole 32.

  By doing so, it is possible to prevent a deviation in the flow rate of the air jet 36 depending on the position of the air hole 32 in the air hole plate 33.

  Therefore, since the ratio of the air flow rate to the fuel flow rate can be made constant regardless of the position of the air hole 32 in the air hole plate 33, an unintended local increase in the flame temperature can be prevented and low NOx combustion can be achieved. can do.

  Thus, sufficient combustion stability is ensured in the inner peripheral coaxial jet nozzle group 51 and low NOx combustion is realized in the outer peripheral coaxial jet nozzle group 52, so that both combustion stability and low NOx combustion can be achieved.

  Next, the gas turbine combustor of Example 3 will be described with reference to FIG.

  The configuration of the gas turbine combustor according to the present embodiment is the same as the configuration of the gas turbine combustor according to the first embodiment. Therefore, the description of the configuration common to both is omitted and only the configuration that is different is omitted. This will be described below.

  FIG. 11 is an enlarged schematic cross-sectional view of the peripheral portion of the fuel nozzle 31 and the air hole 32, and FIG. 12 is a front view of the air hole plate 33 viewed from the combustion chamber 50.

  In the present embodiment, the configuration of the inner peripheral coaxial jet nozzle group 51 is the same as that of the first embodiment. However, the air hole diameters of the air holes 32 b and 32 c provided in the outer peripheral coaxial jet nozzle group 52 differ depending on the arrangement positions on the air hole plate 33. That is, among the third row of air holes 32c arranged in the outer peripheral coaxial jet nozzle group 52, those having a large inter-hole distance from the second row of air holes 32b have an enlarged hole diameter, and those having a small distance are made to have a hole diameter. to shrink.

  This will be specifically described with reference to FIG.

  First, attention is paid to the air holes 32 c-1 that are part of the air holes 32 c in the third row among the air holes 32 provided in the outer peripheral coaxial jet nozzle group 52. The positions of the air holes 32c-1 in the circumferential direction are provided between the air holes 32b in the second row adjacent to the air holes 32c-1 and arranged in the circumferential direction. That is, since the third row of air holes 32c-1 and the second row of air holes 32b are farthest apart, the diameter of the holes is increased as shown.

  On the other hand, attention is paid to a portion of the air hole 32c-2 in the third row that is different from the air hole 32c-1. Here, since the air holes 32c-2 are close to the air holes 32b in the second row, the diameter of the air holes 32c-2 is reduced as illustrated.

  As described above, the hole diameter of the air hole 32c is enlarged or reduced according to the distance between the air holes 32b in the adjacent second row. That is, the remaining thickness of the air hole plate 33 between the third row of air holes 32 c and the second row of air holes 32 b is made substantially equal on the air hole plate 33.

  On the side wall surface of the combustion chamber of the air hole plate 33, the regions 43a and 43b where the air holes 32 are not provided are made small to prevent the flow from stagnating. By eliminating the place where the flow stagnates in this way, a point where the combustion speed and the flow velocity balance in the vicinity of the regions 43a and 43b is not generated, and the flame 41 becomes difficult to form in the vicinity of the regions 43a and 43b.

  On the other hand, in the inner peripheral coaxial jet nozzle group 51, as in the first embodiment, a stable flame 41 is formed in the vicinity of the stagnation 42 and based on the position where the flow velocity matches the combustion speed.

  Accordingly, in the outer peripheral coaxial jet nozzle group 52, the flame 41 is formed at a position separated from the outlets of the air holes 32b and 32c. Therefore, since the flame 41 is formed at a position where the fuel and air are sufficiently mixed, the flame temperature is made uniform, and the outer coaxial jet nozzle group 52 realizes low NOx combustion.

  Thus, sufficient combustion stability is ensured in the inner peripheral coaxial jet nozzle group 51 and low NOx combustion is realized in the outer peripheral coaxial jet nozzle group 52, so that both combustion stability and low NOx combustion can be achieved.

  Next, the gas turbine combustor of Example 4 will be described with reference to FIG.

  The configuration of the gas turbine combustor according to the present embodiment is the same as the configuration of the gas turbine combustor according to the first embodiment. Therefore, the description of the configuration common to both is omitted and only the configuration that is different is omitted. This will be described below.

  In the present embodiment, seven burners 6 shown in the first embodiment are combined to constitute one combustion device.

  FIG. 13 is an enlarged schematic cross-sectional view of the peripheral portion of the fuel nozzle 31 and the air hole 32, and FIG. 14 is a front view of the air hole plate 33 viewed from the combustion chamber 50.

  As shown in FIG. 13, one burner is disposed at the center, and six burners are disposed on the outer peripheral side of the burner. Two fuel systems are connected to each burner 6. Further, all the burners 6 employ the burner structure shown in FIG.

  As shown in FIG. 13, by dividing the fuel system into an inner coaxial jet nozzle group 51 and an outer coaxial jet nozzle group 52 of each burner 6, the number of burners to be burned can be controlled according to the gas turbine load. Therefore, it is possible to stably burn by changing the flow rates of the F1 fuel 201 and the F2 fuel 202 of each burner from the start condition of the gas turbine to the 100% load condition. Further, the fuel system may be divided for each burner. In this case, although the total number of fuel systems is increased, the operability of partial load conditions is improved, and the gas turbine can be stably operated over the entire load range.

  Moreover, it can also be set as one combustion apparatus combining the structure of the burner 6 shown in Examples 1-3.

  Thus, the configuration of this embodiment can achieve both combustion stability and low NOx combustion.

  The combustor 2 according to each embodiment described above is supplied with fuel and air, and mixes and combusts them, and is located upstream in the main flow direction of the combustion chamber 50 and has a plurality of air holes 32. An air hole plate 33 and a fuel nozzle 31 that is located upstream of the air hole plate 33 and supplies fuel to the air hole 32 are provided. The air hole plate 33 forms an upstream side wall of the combustion chamber 50 and has a plurality of air holes 32 concentrically. The air holes 32 are formed so as to be inclined with respect to the central axis of the air hole plate 33, and have a structure that promotes the generation of a circulating flow 40 that flows from the downstream side to the upstream side of the flame.

  In the combustor 2 of each embodiment, the center of the surface of the air hole plate 33 on the combustion chamber side (downstream side) is located closer to the combustion chamber side (downstream side) than the outlet of the outermost air hole 32c. Yes. Furthermore, the distance from the central axis of the air hole plate at an arbitrary point (for example, 43a in FIG. 8) on the surface of the air hole plate 33 on the combustion chamber side is a point on the upstream side of the combustion chamber from this arbitrary point ( For example, it is less than the distance from the central axis of the air hole plate shown in FIG. By adopting such a structure, the distance between the air hole provided on the outer peripheral side of the air hole plate 33 and the flame formed on the downstream side of the center part of the air hole plate 33 can be increased. As a result, it is possible to promote the mixing of fuel and air that passes through the air holes on the outer peripheral side, and to reduce the amount of NOx generated.

  Further, in the combustor 2 of each embodiment, the inner peripheral side of the air hole plate 33, that is, the vicinity of the center of the side wall surface of the combustion chamber 50 is a plane perpendicular to the air hole plate central axis direction. Therefore, the stagnation regions 42a and 42b are formed on the inner peripheral side wall surface.

  A part of the fuel / air mixture ejected from the air holes 32a flows into the stagnation region. Then, since the air-fuel mixture is supplied to a region where the flow velocity is sufficiently slow, a stable flame can be formed by supplying heat from the combustion gas to the stagnation region by the circulation flow 40. Although the flame 41 is held on the downstream side of the inner peripheral side wall surface, a stable flame is formed in the stagnation region, so that the flame holding ability of the entire flame 41 can be enhanced.

  In the present embodiment, the center of the side surface of the air hole plate 33 on the side of the combustion chamber 50 is configured to enhance the flame holding of the flame 41, so that misfire can be suppressed and high reliability can be achieved.

  A fifth embodiment is shown in FIGS. FIG. 16 is an enlarged schematic cross-sectional view of the peripheral portion of the fuel nozzle 31 and the air hole 32, and FIG. 17 is a front view of the air hole plate 33 as viewed from the combustion chamber 50.

  In the present embodiment, the outlet position of the air hole 32 is located on the wall surface of the connecting portion that connects the inner peripheral wall surface and the outer peripheral wall surface of the air hole plate 33. The radial distance from the burner central axis to the connection portion wall surface is such that the connection portion wall surface is inclined with respect to the upstream surface of the air plate so that the downstream side is closer to the combustion chamber upstream side. Therefore, the separation of the premixed airflow at the connection portion wall surface is suppressed, and the premixed airflow is less likely to stagnate.

  On the other hand, all of the air holes 32 in the present embodiment are arranged to be inclined with respect to the burner central axis. Therefore, a strong swirl flow is formed in the combustion chamber 50 and a large circulating flow 40 is generated. Since the circulating flow 40 is formed at a position protruding into the combustion chamber 50, a flow 44 toward the circulating flow 40 is generated in the vicinity of the air plate wall surface due to entrainment by the circulating flow 40 as shown in FIG. 16. The flow 44 prevents the high-temperature combustion gas at the center from flowing out toward the first row of air holes 32a.

  From the above, heat is not supplied around the first row air holes 32a, and the stagnation region is not easily generated. Therefore, the adhesion of the flame is suppressed, and the flame 41 is spread from the inner peripheral combustion chamber wall surface of the top of the air hole plate. Will be formed.

  In this embodiment, the air holes 32 are not provided on the downstream surface of the air hole plate 33. That is, the innermost air hole is provided in the connection surface connecting the inner peripheral plane and the outer peripheral plane. Therefore, also for the first row coaxial jet nozzle, mixing of fuel and air is promoted by taking a sudden expansion at the outlet of the air hole 32 and a distance from the outlet of the air hole 32 to the flame 41, and is discharged from the burner. NOx can be greatly reduced.

  This example is also excellent in terms of combustion stability. By enlarging the inclination angle of the air holes, the swirl flow is strengthened, and the area of the top of the air hole plate is widened, whereby a large circulating flow 40 can be formed and a stable flame 41 can be formed. Because. Further, as a further combustion stability improvement measure, a further stagnation promoting structure such as a depression of the top of the air hole plate as shown in FIG. 18 may be adopted. This is because the promotion of itchiness in this part leads to strengthening of flame holding. If the area of the stagnation 42 is widened, the stability of the flame 41 can be improved.

  In the combustor 2 of this embodiment, all the air holes 32 are provided on the connection surface that connects the inner peripheral plane and the outer peripheral plane. Combined with the effect of the flow 44 generated by the entrainment of the circulating flow 40, such a configuration can suppress the occurrence of a stagnation region around the outlet of each air hole 32. Therefore, the possibility of flame holding in unnecessary portions can be kept low.

  Further, the air hole plate 33 of this embodiment is not provided with air holes on the inner peripheral plane. This can be said to be a configuration that promotes stagnation, and it can be said that this portion is configured to enhance flame holding.

  In this embodiment, in order to simplify the fuel system and reduce the cost, the three fuel nozzle groups supply fuel from the same fuel system. However, in this embodiment, a plurality of fuel systems may be provided as in the first embodiment.

In the fifth embodiment, as shown in FIG. 19, the inclination angle of the connecting portion wall surface connecting the inner peripheral wall surface and the outer peripheral wall surface may be changed in the middle to make the inclination angle θ ₂ larger than θ ₁ . By adopting such a shape, the burner axial direction component of the velocity vector of the flow 44 generated by the entrainment by the circulating flow 40 near the top of the air hole plate 33 while minimizing the thickness of the air hole plate 33 is obtained. Can be bigger. Then, the effect of suppressing the combustion gas in the circulation flow 40 from flowing out toward the first row air holes is further enhanced. In addition, the same effect can be obtained even if the connecting portion wall surface is formed in an arc shape.

  A sixth embodiment is shown in FIGS. FIG. 20 is an enlarged schematic cross-sectional view of the peripheral portion of the fuel nozzle 31 and the air hole 32, and FIG. 21 is a front view of the air hole plate 33 viewed from the combustion chamber 50. In this embodiment, the air hole plate 33 has the same shape as that of the fifth embodiment, but a pilot nozzle 60 serving as a fuel supply means is disposed at the burner center (the center of the air hole plate 33). ing. By ejecting a small amount of fuel directly from the pilot nozzle 60 to the stagnation 42 at the top of the air hole plate, the fuel diffuses and burns at the flame holding point of the flame 41 and is stable even if the average combustion gas temperature of the flame 41 is low. Can be burned. In addition, since a sufficient effect can be obtained even with a small amount of fuel supplied from the pilot, combustion stability can be improved while suppressing an increase in NOx emission.

  A front view from the combustion chamber of a gas turbine combustor in which seven burners of the sixth embodiment are arranged is shown in FIG. FIG. 23 shows an operation example of the gas turbine combustor when the pilot nozzle is not used. Gas turbines need to operate stably over a wide range of fuel-air ratio conditions from startup to rated load conditions. Therefore, the number of burners that supply fuel is controlled in accordance with the fuel flow rate condition.

  In FIG. 23, transition of the burner local fuel-air ratio of the operation example 70 is shown. In FIG. 23 (and FIG. 24 described later), ● represents a burner that supplies fuel, and ○ represents a burner that does not supply fuel. In the operation example 70, operation is performed in mode 1 that supplies fuel only to the central burner under the condition that the total fuel flow rate is small. Next, it switches to mode2 which supplies a fuel to three burners according to the increase in the fuel flow volume by the raise of load. Then, as the fuel flow rate is further increased, mode 3 is sequentially switched to supply fuel to five burners, and mode 4 is supplied to all seven burners. Thus, the number of burners that supply fuel is increased.

  Immediately after the fuel system is switched, the fuel-air ratio in the burner is lowered. However, if the fuel-air ratio falls below the lower limit condition 71, the flame becomes unstable and in some cases misfire occurs. Therefore, it is necessary to operate the burner local fuel-air ratio at the lower limit condition 71 or more. In gas turbines, the load range used for power generation needs to be a range that does not include fuel switching where the local fuel-air ratio of the burner fluctuates abruptly. Therefore, the switching load condition from mode 3 to mode 4 is lowered, and the operating load range To improve the operability of the gas turbine.

  Therefore, in this embodiment, the pilot nozzle 60 as fuel supply means is provided in the center of the burner, and when increasing the number of burners to supply fuel, the fuel is ejected from the pilot nozzle 60 (mode 4 ′). . The double circle ● in FIG. 4 indicates that fuel is also supplied from the pilot nozzle 60.

  Thus, by switching to mode 4 from mode 3 to mode 4, the lower limit of the fuel-air ratio becomes inoperable due to the occurrence of flame misfire or a large amount of unburned fuel as shown in FIG. The value can be lowered from the lower limit condition 71 to the lower limit condition 72. Therefore, compared with the fuel system switching conditions from mode 3 to mode 4 shown in FIG. 23, in FIG. 24, fuel is supplied from mode 3 to the next mode, that is, all the burners and fuel is supplied from the pilot nozzles at a lower load condition. The mode can be switched to mode 4 ′.

  The switching of the fuel system from mode 4 ′ to mode 4 can be continuously performed in a state where all the burners are lit without the fuel flow rate of each system changing rapidly. Therefore, mode 4 ′ to mode 4 can be set as the operational load range, and the operational load range can be expanded. Further, since all of the modes 4 are premixed combustion, the NOx emission amount can be greatly reduced, and both the reduction of the NOx emission amount and the improvement of the combustion stability can be achieved.

  A seventh embodiment is shown in FIGS. FIG. 25 is an enlarged schematic cross-sectional view of the peripheral portion of the fuel nozzle 31 and the air hole 32, and FIG. 26 is a front view of the air hole plate 33 as viewed from the combustion chamber 50.

  In this embodiment, four air hole rows are arranged concentrically on the air hole plate 33. The air hole rows are defined as a first row of air holes 32a, a second row of air holes 32b, a third row of air holes 32c, and a fourth row of air holes 32d from the inner peripheral side. In the present embodiment, as in the fifth embodiment, the outlet positions of the first row of air holes 32a to the third row of air holes 32c are connected to connect the inner peripheral wall surface and the outer peripheral wall surface of the air hole plate 33. Located on the wall surface. That is, the air holes 32d in the fourth row are air holes different from the air holes 32a, 32b, and 32c provided in the connection portion. Further, the connecting portion wall surface is inclined so that the radial distance from the burner central axis to the connecting portion wall surface is closer to the downstream side than the upstream side of the combustion chamber.

  On the other hand, the outlet position of the fourth row of air holes 32d is on the outer peripheral side wall surface perpendicular to the burner central axis. Therefore, a stagnation region 42d is generated around the outlet of the air hole 32d, and there is a condition in which the combustion speed of the flame and the flow speed of the premixed airflow are balanced. However, since the stagnation region 42d is separated from the flame formation position, heat is not supplied to the region where the combustion speed and the flow velocity of the premixed air flow are balanced, and the flame does not hold in the stagnation region 42d. Since the fuel and air ejected from the hole 32d have a distance until they reach the flame 41, they can be sufficiently mixed and burned.

  In the case of a burner having a large size, if all the air hole outlets are arranged on the inclined surface, the center portion of the burner becomes thick and the processing cost increases. Therefore, the thickness of the burner center portion can be suppressed by adopting the present embodiment with respect to the burner having a large size, and the processing cost can be suppressed.

  In the present embodiment, only the fuel nozzle 31d in the fourth row has a separate fuel system. By adjusting the fuel supply amount according to the combustion load of the burner, both combustion stability and NOx emission reduction can be achieved. Further, the fuel system may be unified into one system for cost reduction.

  An eighth embodiment is shown in FIGS. FIG. 27 is an enlarged schematic cross-sectional view of the peripheral portion of the fuel nozzle 31 and the air hole 32. FIG. 28 is a front view of the air hole plate 33 as viewed from the combustion chamber 50. In this embodiment, the description of the same parts as in the fifth embodiment is omitted. In this embodiment, the inclined surface of the air hole plate 33 extends to the vicinity of the burner central axis, and the air hole plate has a conical shape. Therefore, the area of the stagnation 42 at the top of the burner is very small, and the circulation flow 40 is also small.

  This embodiment is effective for a fuel containing hydrogen such as reformed gas obtained by gasifying coal. A fuel containing hydrogen has a high combustion speed and good flame stability. On the other hand, the flame is easy to approach the air hole plate because the combustion speed is high. Therefore, as shown in FIG. 27, by narrowing the circulation flow region and separating the distance from the first row of air holes 32a, flame holding around the air hole outlet is prevented, and the jet of fuel and air becomes flame. The distance to reach can be increased. Then, since mixing proceeds, NOx emission can be suppressed. Further, even if the circulation flow region is narrow, the combustion speed is fast, so that stable combustion can be achieved.

  In addition to fuel containing hydrogen, in a gas turbine or the like in which the turbine inlet temperature is increased for higher efficiency, the flame temperature rises and the combustion speed increases, so the structure as in this embodiment is effective.

  The present invention is applied not only to a gas turbine combustor for power generation, but also to a cogeneration system capable of supplying both heat and electric power, or a gas turbine combustor as an engine for driving a machine such as a pump / compressor and various other combustors. Is possible.

1 compressor 2 combustor 3 turbine 4 casing 6 burner 10 combustor liner 11 flow sleeve 12 tail cylinder inner cylinder 13 tail cylinder outer cylinder 20 generator 21 shaft 30 fuel nozzle header 31 fuel nozzle 32 air hole 33 air hole plate 35 fuel Jet 36 Air jet 40 Circulating flow 41 Flame 42 Stagnation 43 Connection portions 43a and 43b Region 44 Flow 50 Combustion chamber 51 Inner peripheral coaxial jet nozzle group 52 Outer peripheral coaxial jet nozzle group 60 Pilot nozzle 70 Operation example (burner local fuel-air ratio)
71, 72 Lower limit condition 100 Intake air 101 High pressure air 102 High temperature combustion gas 200 Fuel 201 F1 fuel 202 F2 fuel 211, 212 Fuel flow rate adjustment valve 1000 Gas turbine plant

Claims (11)

A combustion chamber for mixing and burning fuel and air;
An air hole plate forming an upstream side wall of the combustion chamber;
A plurality of air holes formed in the air hole plate so as to be inclined with respect to the central axis;
A combustor comprising a fuel nozzle for supplying fuel to each of the plurality of air holes,
The air hole plate has, on the combustion chamber side, an inner peripheral plane and an outer peripheral plane, which are planes perpendicular to the central axis direction of the air hole plate, respectively.
The inner peripheral plane is located downstream of the outer peripheral plane,
The combustor, wherein the inner peripheral plane and the outer peripheral plane are connected by a plane or a smooth surface. A combustion chamber supplied with fuel and air;
An air hole plate located upstream of the combustion chamber and having a plurality of rows of air holes concentrically;
A fuel nozzle that is located upstream of the air hole plate and injects fuel into the air holes of the air hole plate;
A combustor including the air hole plate and a burner having the fuel nozzle corresponding to each of the plurality of rows of air holes;
The distance from the air hole plate central axis at an arbitrary point on the combustion chamber side surface of the air hole plate is equal to or smaller than the distance from the air hole plate central axis at a point upstream of the arbitrary point from the air chamber. Combustor characterized by that. The combustor according to claim 1.
The combustor characterized in that the air hole on the innermost side is provided on a flat surface or a smooth surface connecting the inner peripheral side plane and the outer peripheral side plane. The combustor according to claim 1.
All the air holes are provided in the plane which connects the said inner peripheral side plane and the said outer peripheral side plane, or a smooth surface, The combustor characterized by the above-mentioned. The combustor according to claim 1.
The air hole plate has, on the combustion chamber side, an outer peripheral side plane that is a plane perpendicular to the central axis direction of the air hole plate,
The combustor characterized in that an air hole different from an air hole provided in a flat surface or a smooth surface connecting the inner peripheral side plane and the outer peripheral side plane is provided in the outer peripheral side plane. . The combustor according to claim 1 or 2,
A combustor characterized in that the center of the side surface of the combustion chamber of the air hole plate has a structure for strengthening flame holding. The combustor according to claim 1 or 2,
The combustor characterized in that the center of the combustion chamber side surface of the air hole plate is configured to promote stagnation. The combustor according to claim 1-7,
A combustor comprising fuel supply means at the center of the surface of the air hole plate on the combustion chamber side. An air hole plate having a plurality of air holes;
A plurality of fuel nozzles for supplying fuel to the air holes of the air hole plate;
Fuel supply means provided at the center of the surface of the air hole plate on the combustion chamber side;
The air hole plate and the fuel nozzle corresponding to each of the plurality of rows of air holes, and the center of the surface of the air hole plate on the combustion chamber side is more than the outlet of the air hole on the outermost peripheral side. A burner located on the combustion chamber side,
A method of operating a combustor having a plurality of the burners,
A method of operating a combustor, wherein fuel is supplied from the fuel supply means when increasing the number of burners for supplying fuel. A combustion chamber supplied with fuel and air;
An air hole plate located upstream of the combustion chamber and having a plurality of air holes;
A fuel nozzle for supplying fuel to the air holes of the air hole plate,
The center of the surface on the combustion chamber side of the air hole plate is a method of operating a combustor located on the combustion chamber side from the outlet of the air hole on the outermost peripheral side,
Creating a circulating flow downstream of the center of the air hole plate;
A method of operating a combustor, characterized by causing a flow from an outer peripheral side to an inner peripheral side on the combustion chamber side surface of the air hole plate by entrainment by the circulating flow. A combustion chamber supplied with fuel and air;
Air having a first air hole group located on the upstream side of the combustion chamber and provided concentrically on the center side, and a second air hole group provided on the outer peripheral side of the first air hole group A hole plate,
A fuel nozzle that is located upstream of the air hole plate and injects fuel into the air holes of the air hole plate;
A burner having the air hole plate and the fuel nozzle corresponding to each of the air holes;
The distance from the air hole plate central axis at an arbitrary point on the combustion chamber side surface of the air hole plate is equal to or smaller than the distance from the air hole plate central axis at a point upstream of the arbitrary point from the air chamber. A method of operating a combustor,
The flow rate of fuel per fuel nozzle supplied to the first fuel nozzle group corresponding to the first air hole group,
The method of operating a combustor, wherein the number of fuel nozzles is larger than that of the second fuel nozzle group corresponding to the second air hole group.

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