Title of Invention

ARRANGEMENT FOR THE ADMISSION OF COOLING AIR TO A ROTATING COMPONENT, IN PARTICULAR FOR A MOVING BLADE IN A ROTARY MACHINE

Abstract An arrangement for the admission of cooling air to the internal walls of a component rotating about a rotation axis (2) , in particular a moving blade (1) in a rotary machine, is described, having a component root (3) which can be fastened to a rotor unit in a rotationally fixed manner and adjoining which in one piece in a radially extending manner is a component airfoil (4) in which at least one cooling passage region (Kl) extending radially longitudinally with respect to the rotation axis (2) is provided which, in the region of the component root (3), opens out via an opening (7) into a cooling-air supply passage (5) passing at least . partly through the component root (3) longitudinally relative to the rotation axis (2). The invention is characterized by the fact that a distribution plate (8) is provided in the region of the cooling-air supply passage (5) in such a way that the distribution plate (8) forms a fluid-tight connection with an opening margin (71), surrounding the opening (7) of the cooling passage region (Kl), at least during the rotation of the component about the rotation axis (2) , and in that the distribution plate (8) provides at least one through-opening (81) in the region of the opening (7) of the at least one cooling passage region (Kl) , through which through-opening (81) cooling air passes from the axial cooling-air supply passage (5) into the radial cooling passage region (Kl). (Fig. 1)
Full Text

Arrangement for the admission of cooling air to a rotating component, in particular for a moving blade in
a rotary machine
Prior art
Rotary machines, for example turbo or compressor stages of gas or steam turbine plants, for the specific expansion or compression of gases or gas mixtures, generally have fixed guide blades and moving blades rotating about a rotation axis, said blades usually being exposed to high process temperatures and therefore having to withstand high thermal loads. In addition to the thermal load, the moving blades in particular, rotating about the rotation axis, are additionally subjected to high mechanical loads caused by the centrifugal forces.
In the attempt to improve the efficiency of such heat engines, measures are usually taken which result in the rotating components being subjected to ever increasing thermal and mechanical loads on account of increasing process temperatures and increased rotary speeds. However, these attempts are subject to physical load limits on account of the materials used, from which in particular the rotating plant components are produced. Nonetheless, in order to be able to optimize the efficiency even further, ways of effectively cooling the plant components exposed to heat and subjected to centrifugal force are looked for. To this end, a number of proposals with which cooling air is admitted to moving blades in rotary machines are already known. Typically, a moving blade of such a design, in order to fasten it to the rotor, has a moving blade root which is structured like a fir tree stem, and the moving blade airfoil radially adjoins this moving blade root. For cooling purposes, a multiplicity of radially oriented cooling passages preferably pass through the moving blade root, these cooling passages, for the

effective cooling of the moving blade, extending along the inner walls through the entire moving blade airfoil. Cooling-air feed passages provided on the rotor serve to feed cooling air, which is fed into the cooling passages passing radially through the moving blade root. Such a cooling-air supply system therefore requires a rotor which has a multiplicity of radially oriented cooling-air passages and whose individual cooling passages, by appropriate positioning of the individual moving blades, have to be brought exactly into alignment with the radial cooling passages provided in the moving blade root. Even the slightest maladjustments between moving blade root and rotor unit may permanently impair effective cooling of the moving blade, thereby considerably reducing the service life of the moving blade.
As an alternative to radially supplying a moving blade with cooling air via a rotor-side cooling-air supply system, it has been proposed to effect the cooling-air supply via a cooling-air supply passage passed axially through the moving blade root. In this case, the cooling-air feed flow passes into the axially oriented cooling-air supply passage inside the moving blade root, branching off from which are individual cooling-air passages projecting radially into the moving blade root. Since moving blades are generally produced by a casting process, the ucore technique" is used for forming such cavities inside a cast part, this core technique in particular enabling the cooling-air supply passage passing axially through the moving blade root and the individual cooling passages passing radially at least partly through the inside of the moving blade airfoil to be produced. However, it has been found that flow baffles have to be provided inside the axially oriented cooling-air supply passage for optimized distribution of the cooling-air feed flow, these flow Ivf^les being intended to deflect the axially directed cooling-air feed flow into the radially extending

cooling passages inside the moving blade root. However, for production reasons, the flow baffles which are to be provided for this purpose and which both change the direction of and distribute the cooling-air feed flow axially directed into the blade root are subject to production-related structural shape tolerances, which reduce the accuracy with which the cooling-air flow can be directed and distributed to the individual cooling passages extending radially along the moving blade airfoil.
The invention is intended to provide a remedy here, so that the object of the invention is to optimize the cooling-air distribution to the individual radially oriented cooling passages inside a moving blade. The measures to be taken for this purpose are also not to result in any costly production or assembly steps and are to have robust properties which are able to cope with the high demands with regard to thermal and also mechanical loads within such components rotating about a rotation axis.
Summary of the invention
The solution achieving the object of the invention is specified in claim 1. Advantageous developments are the subject matter of the subclaims and of the description with reference to the exemplary embodiments.
According to the invention, an arrangement for the admission of cooling air to the internal walls of a component rotating about a rotation axis, in particular a moving blade in a rotary machine, such as a gas turbine plant for example, having a component root which can be fastened to a rotor unit in a rotationally fixed manner and adjoining which in one piece in a radially extending manner is a component airfoil in which at least one radially extending coolircr passage region is provided which, in the region of the

component root, opens out via a respective opening into a cooling-air supply passage passing at least partly through the component root longitudinally relative to the rotation axis, is developed in such a way that a distribution plate is provided in the region of the cooling-air supply passage in such a way that the distribution plate forms a fluid-tight connection with an opening margin, surrounding the opening of the cooling passage region, at least during the rotation of the component about the rotation axis. Furthermore, the distribution plate provides at least one through-opening in the region of the opening of the at least one cooling passage region, through which through-opening cooling air passes from the axial cooling-air supply passage into the radial cooling passage region.
In order to depict and describe the idea of the invention in a simpler manner, the further explanations relate to the case of a moving blade which is fitted along a rotor unit of a gas or steam turbine plant and can be inserted into a turbo stage or compressor stage. Of course, this reference is not to restrict the general idea of the invention, which also relates to alternative plant components which are subjected to comparable loads.
The distribution plate, which is preferably produced from a temperature-resistant flat material, provides through-openings along its extent in each case in such a way as to correspond to the radially extending cooling passage regions, the through-openings each having opening diameters which can predetermine the volumetric flow of cooling air which passes into the individual cooling passage regions. The distribution plate therefore enables volumetric proportions of cooling air, which are calculated beforehand and are adapted to the respective rotating moving blade, to be distributed to the individual radially moving blade airfoil extending cooling passage regions. On account

of the production tolerances unavoidably associated with the casting process, such an exact distribution of the cooling-air flow is not possible solely by using flow baffles produced by casting.
In order to keep the assembly cost for incorporating the distribution plate along the cooling supply passage extending axially through the component root as low as possible, and in order to exactly position the distribution plate relative to the at least one radially extending cooling passage region, at least two axially spaced-apart shoulder elements are provided inside the cooling-air supply passage, and these shoulder elements is located radially opposite the opening margin of the opening of the at least one cooling passage region and at a slight distance from this opening margin and defines together with the latter a push-in slot, in which the distribution plate preferably fits snugly in a flush manner by being pushed axially into the cooling-air supply passage. At this point, it may be noted that preferably a plurality of cooling passage regions passing radially through the moving blade root are provided, these cooling passage regions being arranged in such a way as to be separated from one another by intermediate walls. Via a respective opening margin which is oriented so as to face the cooling-air supply passage extending in the moving blade root and encloses the opening of the respective radially extending cooling passage region, the intermediate walls open out in the region of said cooling-air supply passage. With this opening margin, it is necessary to provide a fluid-tight connection relative to the distribution plate, at least in the rotation state, in order to completely rule out possible leakage flows between distribution plate and opening margin.
mo this end, the distribution plate advantageously rests loosely between the shoulder elements and the at

.least one opening margin, so that the distribution plate is pressed radially outward against the opening margin by the centrifugal forces produced by the rotation and forms the desired fluid-tight connection with said opening margin, as a result of which any axially directed leakage flows between distribution plate and the opening margin are effectively prevented.
Due to the fluid-tight connection, produced automatically by the rotation, between the distribution plate and the opening margin of the opening of the at least one radially extending cooling passage region, it is not necessary to provide tolerance-free gap sizes for the push-in slot which is defined between the shoulder elements and the at least one opening margin, a requirement which cannot be met anyway by conventional casting processes.
In order to meet the requirement for ensuring a fluid-tight connection between the distribution plate and the corresponding opening margins, at least during rotation, it is necessary to produce the distribution plate from such a material and with such a material thickness that the bending moment of the distribution plate is exceeded due to the centrifugal forces produced by the rotation and acting on the distribution plate, and the distribution plate is able to correctly conform to the casting geometry of the opening margins. In addition, in a further preferred embodiment, this conformity action is assisted by the distribution plate having locally limited material weak points, for example in the form of mechanical notches or cracks. Such material weak points can also be produced by specifically changing the structure in the distribution plate. Such points of reduced strength are arranged in a distributed manner along the distribution plate, preferably in regions close to the opening margins where it is ^^cessary to produce a fluid-tight connection.

,It may also be advantageous in some cases to fixedly join the distribution plate to the inner structure of the moving blade root in the region of the cooling-air supply passage at least at the ends - at one end or at both ends - by a brazed or welded j oint. The j oint locations required for this are easily accessible axially through the cooling-air supply passage for assembly purposes, so that the assembly cost necessary for this is not substantially increased.
Since the cooling-air supply extending axially completely through the moving blade root is designed to be open on both sides with regard to the moving blade root, as will be explained in more detail below with reference to an exemplary embodiment, it is necessary to close the axial opening in a fluid-tight manner.
A very simple embodiment provides for an end closure of the cooling-air supply passage to be created by appropriately bending over an end region of the distribution plate, it being necessary to weld or braze the distribution plate to the inner wall of the cooling-air supply passage at least in the region of its plate section bent over at the end. However, fixing in this respect could have an adverse effect on the required fluid-tight connection, produced at least in the rotation state, between the distribution plate and the at least one opening margin, so that a further preferred embodiment, instead of fixedly joining the distribution plate in the region of the bent-over distribution plate section, provides a separate closing plate which axially closes off the cooling-air supply passage in a fluid-tight manner on one side. It is suitable for this purpose for the closing plate, adapted to the cross-sectional contour of the cooling-air supply passage, to be joined to the moving blade root in a fluid-tight manner via brazed or welded joints.

Brief description of the invention
The invention is explained by way of example below, without restricting the general idea of the invention, with the aid of exemplary embodiments and with reference to the drawing, in which:
fig. 1 shows a cross section through a moving blade of a gas turbine plant,
fig. 2 shows a detailed cross-sectional illustration through the root region of a moving blade,
fig. 3 shows a detailed illustration of a closing plate which axially closes off the cooling-air supply passage in a gas-tight manner,
figs 4a-d show views of distribution plates of alternative design, and
fig. 5 shows an alternative distribution plate inside a moving blade root.
Ways of implementing the invention, industrial applicability
Shown in figure 1 is the cross section through a moving blade 1, which is rotatable about a rotation axis 2 of a rotor unit integrated in a gas turbine arrangement. The moving blade 1 has a moving blade root 3, which can be frictionally connected to the rotor unit (not shown in any more detail) via an appropriately designed joining contour (fir-tree structure - not shown). Radially adjoining the moving blade root 3 is the moving blade airfoil 4, in the interior of which cooling passage regions Kl to K4 are provided. Extending in the region of the moving blade root 3 is a cooling-air supply passage 5 which is oriented -^i.ally, i.e. parallel to the rotation axis 2, and passes first

,of all through the entire axial width of the blade root 3. Provided in the interior of the cooling-air supply passage 5 are "shoulder elements" 6 which, by the casting process with which the entire moving blade 1 can be produced, are fashioned from the casting material from which the rest of the moving blade is made. The shoulder elements 6 have top surface sections 61, which are radially opposite and at a slight distance from "opening margins" 71. The opening margins 71 surround openings 7 facing the cooling-air supply passage 5, and radially adjoining these openings 7 are the cooling passage regions Kl and K2, which are each defined by cooling passage wall regions 72. Like the cooling-air supply passage 5, the cooling passage regions Kl to K4 provided in the interior of the moving blade airfoil can also be produced by the casting process by providing a suitably modeled displacement core, which serves as a spacer for the respective cavities and is inserted in the casting mold during the casting process.
A distribution plate 8 in which appropriately pos i t ioned and dimens ioned through-openings 81 are incorporated is provided in order to direct, but in particular in order to proportion, the cooling-air flow passing through the cooling passage regions Kl, K2, K3 and K4. The through-openings 81 are correspondingly provided in the orifice region of the openings 7.
In the exemplary embodiment shown according to figure 1, it is necessary for the cooling-air feed flow supplied axially via the cooling-air supply passage 5 to be fed specifically into the cooling passage regions Kl and K2. The through-openings 81 provided in the orifice region of the cooling passage region Kl permit a cooling-air flow radially through the cooling passage Kl, which provides an outlet opening A at the top flank of the moving blade airfoil 4, through which outlet opening A the cooling air escapes into the hot-gas

passage H. In contrast, the cooling air entering the cooling passage region K2 via the through-openings 81 is for the most part diverted by appropriate flow baffles 9 into the cooling passage region K3, adjoining which in the direction of flow (see flow arrows) is the cooling passage region K4. In the connecting region between the cooling passage regions K3 and K4, the distribution plate 8 provides for the cooling-air flow flowing downward in the cooling passage region K3 to be deflected entirely into the cooling passage region K4 extending radially upward. For this purpose, it is necessary for the distribution plate 8 to conform to the corresponding opening margins 71 and the marginal contour 10 in a gas- or fluid-tight manner. At the same time, it is necessary to make sure that no leakage flows at all occur between the distribution plate 8 and the opening margins 71. In order to ensure this, it is necessary to dimension the distribution plate 8 and select its material in such a way that it is pressed firmly against the corresponding opening margins 71 and the marginal contour 10 in a fluid-tight and flush manner by the centrifugal forces caused by the rotation about the rotation axis 2. In this case, the distribution plate 8 lies loosely in the inlet slot 11 defined between the surface sections 61 of the shoulder elements 6 and the opening margins 71 and the marginal contour 10 (see figure 2).
A closing plate 12 which is fixedly joined to the moving blade root 3 by a welded or brazed joint provides for an axial, gas-tight closure of the cooling-air supply passage 5 on one side.
Figure 2 shows a detailed illustration of the distribution plate 8 inserted into the axially extending cooling-air supply passage 5. As already mentioned, the shoulder elements 6 present in the interior of the cooling-air supply passage 5 and also the individual cooling passage regions Kl to K4, i.e.

the cooling passage wall regions 72 with the corresponding opening margins 71, are jointly produced by the casting process. The opening margins 71 enclose with the surface sections 61 of the shoulder elements 6 a push-in slot 11, along which the distribution plate 8, which is formed with a plane surface in the initial state, can be pushed in axially. After the distribution plate 8 in the form shown in figure 2 has been pushed into position inside the cooling-air supply passage 5, the end regions of the distribution plate 8 are bent over in the manner indicated in figure 2 in order to largely fix the distribution plate 8 axially and radially inside the push-in slot 11. Otherwise, the distribution plate 8 still rests loosely on the surface sections 61 of the shoulder elements 6. In order to axially close off the cooling-air supply passage 5 on one side in a fluid-tight manner, a closing plate 12 is inserted into the cooling-air supply passage 5 at the left-hand inlet opening in figure 2 and is welded or brazed to the moving blade root 3 in marginal regions. Due to the gas-tight closure of the cooling-air supply passage 5 on one side, the cooling-air feed flow S entering the cooling-air supply passage 5 from the right-hand side is subjected to a baffle effect forming inside the cooling-air supply passage 5, as a result of which the cooling-air feed flow S is driven through the through-openings 81 provided in the distribution plate 8. The size and arrangement of the individual through-openings 81 define the volumetric flow of the cool ing-air flow entering the respective cooling passage regions Kl and K2. Due to the intimate fluid-tight connection, forming during the rotation, between the distribution plate 8 and the marginal regions 71 which surround the respective openings 7 of the cooling passage regions Kl and K2, any leakage flows which could form between the distribution plate 8 and the marginal regions 71 are prevented. This ensures that the cooling-air ^low is directed free of losses solely

along the cooling passage regions Kl to K4 provided in the interior of the moving blade airfoil.
Figure 3 shows a further detailed illustration of the closing plate 12 welded to the axial end region of the cooling-air supply passage 5 in a fluid-tight manner. The closing plate 12 sits in a recess 13 of corresponding matching contour inside the moving blade root 3 and is welded to the latter in a fluid-tight manner. It can also be seen from figure 3 that the distribution plate 8 rests loosely on the shoulder element 6 inside the push-in slot 11. It is only by means of the rotation and the resulting centrifugal forces that the distribution plate 8 is lifted radially and thus comes into contact with the marginal contour 10, with which it forms a correspondingly fluid-tight connection. This avoids a situation where cooling air can pass back into the cooling-air supply passage 5 from the cooling passage region K4 at this point.
Figures 4a-d show two different respective embodiments for a distribution plate 8. Figures 4a and b show a plan view and side view of a first distribution plate 8, the geometrical dimensions of which are adapted to the push-in slot 11 described above. The distribution plate 8 is produced from a heat-resistant flat material and, for fitting purposes, is first of all of plane design on one side (see figure 4a) . Furthermore, the distribution plate 8 has through-openings 81, the arrangement, shape and size of which determines the cooling-air volume which is delivered through the cooling passage regions Kl to K4,
For fitting purposes, it is necessary for the distribution plate 8 of plane design on one side to be pushed in axially between the opening margins 71 and the surface sections 61 of the shoulder elements 6 and for it to be appropriately Kr^t over in the manner described above at an end section 82 or 83 after it has

'been completely inserted into the cooling-air supply passage 5. In this respect, see the side view in figure 4b. As already mentioned at the beginning, the dimensions of the distribution plate 8 and the material are selected in such a way that at least local deflections can occur on the distribution plate 8 in the region of the opening margins 71, so that the distribution plate 8 can form a fluid-tight connection with the opening margins 71. In order to improve the bendability of the distribution plate 8, in particular in regions which are opposite the opening margins 71, local material weak points in the form of notches 15 serve are provided along the distribution plate 8 according to the exemplary embodiment in figures 4c and d. Due to the deliberate provision of the locally limited notches 15, the bending stiffness of the distribution plate 8 can be reduced at least locally, in order to optimize local conformity of the distribution plate 8 to the opening margins 71. Likewise, the exemplary embodiment in figures 4c and 4d provides through-openings 81 of different dimensions in each case for the cooling-air feed into the cooling passage sections Kl and K2. Thus substantially less cooling air is admitted to the cooling passage region Kl than to the cooling passage region K2.
The measures described above serve the preferred loose mounting of the distribution plate 8 inside the cooling-air supply passage 5, the distribution plate 8 being spatially fixed merely inside the push-in slot 11 on the one hand by the shoulder elements 6 and on the other hand by the opening margins 71 or respectively the marginal contour 10. In this way, welding operations which are complicated in terms of assembly can be completely avoided, but may be locally provided if required.
Figure 5 shows a partial cross section through t^e root region 3 of a moving blade 1 which is designed in

'accordance with the above explanations. Provided along the cooling-air supply passage 5 is only a single cooling passage region Kl, into which cooling air is to be specifically branched off from the cooling-air supply passage 5. This is effected via appropriately provided through-openings in the axially inserted distribution plate 8, which has notches 14, improving the bendability, at suitable points along the distribution plate 8.

List of designations
1 Moving blade
2 Rotation axis
3 Moving blade root
4 Blade airfoil
5 Cooling-air supply passage
6 Shoulder elements
61 Surface section
7 Opening
71 Opening margin
72 Cooling passage intermediate wall
8 Distribution plate
81 Through-opening
82, 83 End sections
9 Deflection elements
10 Marginal contour
11 Push-in slot
12 Closing plate
13 Recess
14 Notches



WHAT IS CLAIMED IS:
1. An arrangement for the admission of cooling air to
the internal walls of a component rotating about a
rotation axis (2), in particular a moving blade (1) in
a rotary machine, having a component root (3) which can
be fastened to a rotor unit in a rotationally fixed
manner and adjoining which in one piece in a radially
extending manner is a component airfoil (4) in which at
least one cooling passage region (Kl) extending
radially longitudinally with respect to the rotation
axis (2) is provided which, in the region of the
component root (3), opens out via an opening (7) into a
cooling-air supply passage (5) passing at least partly
through the component root (3) longitudinally relative
to the rotation axis (2) , and a distribution plate (8)
is provided in the region of the cooling-air supply
passage (5) in such a way that the distribution plate
(8) forms a fluid-tight connection with an opening margin (71), surrounding the opening (7) of the cooling passage region (Kl), at least during the rotation of the component about the rotation axis (2), and provides at least one through-opening (81) in the region of the opening (7) of the at least one cooling passage region
(Kl) , through which through-opening (81) cooling air passes from the axial cooling-air supply passage (5) into the radial cooling passage region (Kl), characterized in that at least two axially spaced-apart shoulder elements (6) are provided inside the cooling-air supply passage (5) , these shoulder elements (6) in each case being arranged radially opposite an opening margin (71) and enclosing with the latter a push-in slot (11) intended for the distribution plate (8).
2. The arrangement as claimed in claim 1,
characterized in that the component can be produced by
a casting process in which the cooling-air supply
p*. "nge (5) passing axially through the component root
AMENDED SHEET

'(3) and the at least one cooling passage region (Kl) oriented radially in the component airfoil (4) can be produced by means of the core technique.
3. The arrangement as claimed in claim 1 or 2,
characterized in that the opening margin (71)
surrounding the opening (7) is a surface region which
encloses the opening (7) and has a surface plane
coinciding with the opening plane.
4. The arrangement as claimed in claim 3,
characterized in that at least two cooling passage
regions (Kl, K2) are provided, the opening margins (71)
of which lie in a common surface plane, with which the
distribution plate (8) forms a fluid-tight connection
at least during the rotation of the component about the
rotation axis (2).
5. The arrangement as claimed in claim 3 or 4,
characterized in that the opening plane of the opening
(7) is oriented perpendicularly to the radial direction
predetermined by the rotation about the rotation axis
(2) .
6. The arrangement as claimed in one of claims 1 to
5, characterized in that the cooling-air supply passage
passes axially completely through the component root
(3) , and in that the distribution plate (8) can be
pushed completely into the cooling-air supply passage
(5) at least on one side.
7. The arrangement as claimed in claim 6,
characterized in that the distribution plate (8)
provides at least one bent-over end region (82, 83) in
the state inserted in the cooling-air supply passage
(5) .

4
7, characterized in that the distribution plate (8) is
made of a flat metallic material.
9. The arrangement as claimed in one of claims 1 to
8, characterized in that the distribution plate (8)
rests loosely on the shoulder elements (6), and a
fluid-tight connection between the distribution plate
(8) and the opening margin (7) is effected by a
frictional connection which occurs due to centrifugal
forces which are caused by the rotation and which act
on the distribution plate (8).
10. The arrangement as claimed in claim 9,
characterized in that the material and material
thickness of the distribution plate (8) are selected in
such a way that the distribution plate (8) conforms in
a locally limited manner to the surface contour at
least in the region of the opening margin (71).
11. The arrangement as claimed in one of claims 1 to
10, characterized in that the distribution plate (8) is
produced from a flat or round material.
12. The arrangement as claimed in one of claims 1 to
8, characterized in that the distribution plate (8) is
fixedly joined inside the cooling-air supply passage
(5) at least in a locally limited manner, preferably by
means of a brazed or welded joint.
13. The arrangement as claimed in one of claims 1 to
12, characterized in that the distribution plate (8)
has locally limited material weak points.
14. The arrangement as claimed in claim 13,
characterized in that the material weak points are
designed in the form of mechanical notches (14) or

^cracks or by changing the structure in the distribution
4
plate (8).
15. The arrangement as claimed in one of claims 1 to
14, characterized in that the cooling-air supply
passage (5) is closed off in a fluid-tight manner by a
closing plate (12) at least on one side.
16. The arrangement as claimed in claim 15,
characterized in that the closing plate (12) is welded
or brazed to the component root (3) after the
distribution plate (8) has been inserted into the
cooling-air supply passage (5).
17. The arrangement as claimed in one of claims 1 to
16, characterized in that the component is a moving
blade of a compressor or turbine stage in a steam or
gas turbine plant.
Dated this 27 day of September 2006

Documents:

3575-abstract image.jpg

3575-CHENP-2006 AMENDED CLAIMS 06-02-2012.pdf

3575-CHENP-2006 OTHER PATENT DOCUMENT 06-02-2012.pdf

3575-CHENP-2006 AMENDED CLAIMS 07-05-2013.pdf

3575-CHENP-2006 CORRESPONDE OTHERS 04-09-2012.pdf

3575-CHENP-2006 CORRESPONDENCE OTHERS 01-05-2013.pdf

3575-CHENP-2006 CORRESPONDENCE OTHERS 07-05-2013.pdf

3575-CHENP-2006 CORRESPONDENCE OTHERS 09-12-2011.pdf

3575-CHENP-2006 EXAMINATION REPORT REPLY RECEIVED 06-02-2012.pdf

3575-CHENP-2006 FORM-3 06-02-2012.pdf

3575-CHENP-2006 FORM-3 04-09-2012.pdf

3575-CHENP-2006 POWER OF ATTORNEY 06-02-2012.pdf

3575-chenp-2006-abstract.pdf

3575-chenp-2006-claims.pdf

3575-chenp-2006-correspondnece-others.pdf

3575-chenp-2006-description(complete).pdf

3575-chenp-2006-drawings.pdf

3575-chenp-2006-form 1.pdf

3575-chenp-2006-form 26.pdf

3575-chenp-2006-form 3.pdf

3575-chenp-2006-form 5.pdf

3575-chenp-2006-pct.pdf


Patent Number 256653
Indian Patent Application Number 3575/CHENP/2006
PG Journal Number 29/2013
Publication Date 19-Jul-2013
Grant Date 12-Jul-2013
Date of Filing 27-Sep-2006
Name of Patentee ALSTOM TECHNOLOGY LTD.
Applicant Address BROWN BOVERI STRASSE 7, CH-5400 BADEN, SWITZERLAND
Inventors:
# Inventor's Name Inventor's Address
1 TSCHUOR, REMIGI KANALSTRASSE 25, CH-5410 WINDISCH, SWITZERLAND
2 NEUHOFF, HEINZ ALPENBLICKSTRASSE 68, 79761 WALDSHUT-TIENGEN, GERMANY
3 STRELKOV, LOURI 4 TH TVERSKAIY-YAMSKAYA 12, 12, RU-125047 MOSCOW, RUSSIA
PCT International Classification Number F01D 5/18
PCT International Application Number PCT/EP05/51411
PCT International Filing date 2005-03-29
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 10 2004 015 609.3 2004-03-30 Germany