JPH108906A - Rotor for gas expander - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a cover plate protecting a fitting part between a blade root part of a moving blade and a blade groove part of a rotor disk, from dislocating, or generating vibration due to wearing of a lock screw, in a rotor for a gas expander collecting energy from combustion exhaust gas containing hard dust. SOLUTION: Cover plates 1, 2 closing the upstream/downstream of a fitting part 019 between a blade root part and a blade groove part 012 are formed by heads 7, 8 providing lock screws 5, 6 fixed to a rotor disk 018 inside thereof and shaft units 15, 16 pressing up a lower end of the cover plates 1, 2 fixed in a tip end part penetrating a peripheral part of the rotor disk, thereby the cover plates 1, 2 can be fixed in a condition where the lock screw is not contacted with combustion exhaust gas F.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a fluid catalytic cracking for refining gasoline from crude oil.
energy from the flow of high-temperature, high-pressure combustion exhaust gas, including dust such as hard catalyst, generated in a plant such as a tic cracking (hereinafter referred to as FCC) plant.
The present invention relates to a gas expander that drives a compressor or the like of a plant, and particularly to a gas expander that protects a fitting portion of a blade root portion and a blade groove portion of a moving blade from an attack of solid matter in combustion exhaust gas. About the rotor.

[0002]

2. Description of the Related Art As one of the catalytic cracking methods for petroleum, high octane gasoline is synthesized from light oil and heavy oil by using a hard solid and a catalyst mainly composed of synthetic zeolite, silica, alumina and the like. There is an FCC. In this FCC plant, the feedstock is fed into the reactor together with the solid catalyst mainly composed of regenerated products to make it in a fluidized state, to cause a decomposition reaction, and the spent catalyst is sent to the regeneration tower together with air. Then, the carbonaceous material deposited on the solid catalyst is incinerated, removed, regenerated, and reused in the reactor.

[0003] In addition, the carbonaceous material deposited on the catalyst surface is incinerated in a regeneration tower, and is heated at 710 ° C and a temperature of about 2.7 kg / cm ² .
The combustion exhaust gas containing the hard catalyst dust at the pressure condition is sent to a gas expander after a solid catalyst of 20 μm or more, that is, a large-diameter solid material is removed by a third separator, and energy is recovered. The power is generated and the compressor is driven to supply necessary air to the regeneration tower. FIG. 3 is a view showing a side surface of a rotor blade of a gas expander rotor used in such an FCC plant and a cross section of a rotor disk in which a blade root portion of the rotor blade is fitted to an outer peripheral edge.

[0004] As shown in the figure, a moving blade 011 operating in an exhaust gas passage 010 through which a combustion exhaust gas F sent from a third separator flows has a blade root portion 01 formed at a base end thereof.
The lower end of the blade 2 is formed on the outer circumference of the rotor disk 018 in the flow direction of the combustion exhaust gas F, and has a clearance 017 between the blade bottom 020 and the blade groove 020 having a height substantially the same as that of the blade root 012. And are fitted and attached, and are arranged at equal pitches in the circumferential direction along the outer periphery of the rotor disk 018.

[0005] Such a rotor blade 011, especially an airfoil portion 013.
Is made of a special hard-wearing material because it operates in the flow of the combustion exhaust gas F mixed with the solid catalyst dust.
By adopting a wear-resistant coating on the surface and increasing the thickness of the profile, the effect of dust attack on the operation is reduced.

Further, the blade root portion 012 and the blade groove portion 019 are
It is necessary to fit the rotor blades 011 accurately on the outer peripheral edge of the rotor disk 018 and firmly support the rotor blades 011 rotating at high speed. For this reason, wear of the fitting part due to dust attack is required. Need to be prevented. Therefore, the cover plate 014 that separates the fitting portion from the flue gas F
Are attached to the upstream and downstream sides of the fitting portion between the blade root portion 012 and the blade groove portion 019 to prevent the combustion exhaust gas F from entering the fitting portion. This cover plate 014
Is a set screw 015 which is disposed opposite to the flow of the flue gas F and has a head protruding in the direction of the flow.
With this, it is fixed to the rotor disk 018.

Further, a groove 016 for inserting a shear pin between the adjacent moving blades 011 is provided on a platform 21 between the blade root portion 012 and the airfoil portion 013 of the moving blade 011, Wing groove 01
9 A seal arm 0 provided with a step portion is provided on the upstream side on the inner peripheral side.
22 project from the side surface of the rotor disk 018 toward the upstream side. A plurality of labyrinth fins are provided on the upper surface (outer peripheral surface) of the stepped portion of the seal arm 211 in the flow direction of the flue gas F to seal the flue gas F,
The outflow of the combustion exhaust gas F from the exhaust gas passage 01 is prevented.

However, in the conventional gas expander rotor as described above, the blade root portion 01
2, and a cover plate 014 for isolating the blade groove portion 019 on the outer periphery of the rotor disk 018 from the flow of the combustion exhaust gas F and protecting a fitting portion between the two is provided with a set screw whose head is directed in the direction of flow. 018, the set screw 015 whose head projects in the direction of flow due to the flow of the combustion exhaust gas F containing the catalyst, which is a solid powder.
Is eroded due to solid particle collision, and the cover plate 014 cannot be fixed, which may lead to an accident.

A set screw 015 projects from the surface of the cover plate 014 in contact with the flue gas F to disturb the flow of the flue gas F flowing on the surface. The frequency of collision with the cover plate 014 is increased, the erosion of the surface of the cover plate 014 is promoted, and the life of the cover plate 014 is shortened.

[0010]

SUMMARY OF THE INVENTION According to the present invention, a set screw for fixing a cover plate to an outer peripheral portion of a rotor disk is provided on an inner side of a seal arm in order to solve the above-mentioned problems of the conventional gas expander rotor. Provided on the side of the rotor disk, and isolated from the flow of combustion exhaust gas, preventing erosion due to collision of particles contained in the flow of combustion exhaust gas, and securely fixing the cover plate,
An object of the present invention is to provide a rotor for a gas expander in which the surface of a cover plate in contact with combustion exhaust gas is smoothed, erosion by the combustion exhaust gas is reduced, and the life of the gas expander can be extended.

[0011]

For this reason, the gas expander rotor of the present invention has the following means. A blade root portion of a moving blade that generates power by rotating in a flow of combustion exhaust gas mixed with hard dust such as a solid catalyst, and the moving blade is arranged on the outer periphery of the rotor disk by fitting with the blade root portion. A cover plate that closes the front and rear in the flow direction with the blade groove provided on the outer periphery of the rotor disk and protects the fitting portion of the blade root and the blade groove from erosion of combustion exhaust gas is fixed to the outer periphery of the rotor disk. A screw is provided inside the seal arm, which protrudes from the outer periphery of the rotor disk in the flow direction of the flue gas to seal the flow of the flue gas. I was isolated.

The set screw provided inside the seal arm of the rotor disk is arranged in the radial direction of the rotor disk, pushes up the cover plate from below, presses the upper end of the cover plate against the platform, and sets the screw. It is preferable to adopt a structure that can be fixed.

In the rotor for a gas expander of the present invention,
By the above-described means, the set screw fixing the cover plate that prevents the blade root portion and the blade groove portion from being worn by the combustion exhaust gas by the flow of the combustion exhaust gas containing dust such as the catalyst, which is a solid powder, Since it is arranged in a non-contact state with the exhaust gas, it is not eroded by the hard solid matter in the combustion exhaust gas, the cover plate is securely fixed to the rotor disk, and the cover plate may come off. It is possible to reliably eliminate the possibility of an accident occurring.

Further, the cover plate is fixed to the surface of the cover plate so as to face the flow direction of the flue gas. Since the head of the set screw is eliminated, the cover plate is disposed to face the flow of the flue gas. The cover plate surface becomes smooth, the flow of the combustion exhaust gas flowing on the cover plate surface becomes smooth, and the frequency of collision of hard solids in the combustion exhaust gas with the cover plate surface can be reduced.
This makes it possible to provide a cover plate having a long life with respect to erosion caused by abrasion with dust in the combustion exhaust gas.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a gas expander rotor according to the present invention will be described below with reference to the drawings.
FIG. 1 shows a first embodiment of a gas expander rotor according to the present invention.
It is a figure showing a form. In FIG. 1, the same members as those shown in FIG. 3 are denoted by the same reference numerals, and description thereof will be omitted.

The front cover plate 1 and the rear cover plate 2 disposed upstream and downstream of the blade root portion 012 of the rotor blade 011 and the blade groove portion 019 on the outer periphery of the rotor disk 018 are shown in perspective views. FIG. 2 (a), FIG.
(B), each having a projection 3 at the upper end,
The rotor disk is inserted into the recesses 14 provided on the lower surface of the platform 21 of the rotor blade 011, and the lower end thereof is pressed by the tips of set screws 4, 5 which advance and retreat the outer peripheral portion of the rotor disk 018 in the radial direction. 01
8 are sequentially attached to the front end side and the rear end side of the blade root 012 of the rotor blade 011 disposed on the outer periphery of the rotor 8.

The front cover plate 1 as a cover plate, which is disposed at the front end of the blade root portion 012 perpendicularly to the flow direction of the combustion exhaust gas F, serves as a fitting portion of the blade root portion 012 and the blade groove portion 019. While sealing the upstream side,
A rear cover plate 5 as a cover plate disposed on the rear end side of the blade root portion 012 hermetically seals the downstream side of the fitting portion except for a steam passage 4 to be described later.
The combustion exhaust gas F flowing through the blade root portion 012 and the blade groove portion 019
To prevent the intrusion into the fitting portion.

Further, two setscrews 4 and 5 are arranged symmetrically in the circumferential direction for each of the front cover plate 1 and the rear cover plate 2, and as described above, the outer peripheral portion of the rotor disk 018 is radially arranged. In particular, the screw heads 7, 8 which have been arranged opposite to the flow of the flue gas F,
8 protrudes upstream from the outer peripheral side surface, and the exhaust gas passage 01
0, a seal arm 021 for sealing between
And the shafts 15 and 16 which advance and retreat through screw holes formed in the outer peripheral portion of the rotor disk 018 so as to prevent contact with the combustion exhaust gas F.

The set screws 4 and 5 are screwed in.
Extruded members 9 and 10 interposed between the front end and the lower ends of front cover plate 1 and rear cover plate 2.
Is pushed upward to push up the lower ends of the front cover plate 1 and the rear cover plate 2 to press the projections 3 on the upper ends of the cover plates 1 and 2 against the concave portions 14 formed on the lower surface of the platform 21. , To be fixed. Further, the screw heads 7 and 8 are provided with detents 11 and 12, respectively, to prevent loosening of the set screws 5 and 6 and prevent the front and rear cover plates 1 and 2 from vibrating.

A steam hole 13 is formed in the vicinity of the outer peripheral portion of the rotor disk 018 where the set screw 5 advances and retreats.
The gas passes through labyrinth fins (not shown) provided on the stairs of the seal arm 21 and blows out into the exhaust gas passage 010 to prevent the combustion exhaust gas F from entering, and is covered by the front cover plate 1 and the rear cover plate 2. The gas passes through the fitting portion between the wrapped blade root portion 012 and the blade groove portion 019 to blow out from the above-described steam passage 4 provided in the rear side governor plate 2 to the exhaust gas passage 010.

Since the rotor for a gas expander according to the present embodiment is configured as described above, it operates in the flow of the combustion exhaust gas F into which the solid catalyst dust is mixed, so that a special hard-wearing IN is used. Made of -738LC material etc.
By adopting abrasion resistant chrome carbide D-gun coating on the surface and thickening the profile, it fits more compared to the airfoil 013 manufactured in consideration of the effect of dust attack. And moving blade 01
1 is precisely arranged on the outer periphery of the rotor disk 018, and the rotor blades 011 rotating at high speed must be firmly supported to prevent the occurrence of vibration and the like.
The fitting portion 19 can prevent attack by dust in the combustion exhaust gas F with the front cover plate 1 and the rear cover plate 2 securely fixed to the rotor disk 018.

Further, since the set screws 5 and 6 are not worn by dust erosion, it is possible to reliably prevent an accidental accident in which the front cover plate 1 and the rear cover plate 2 come off, and to prevent the front cover plate 1 and the rear cover from being accidentally removed. The protrusions of the setscrews 5 and 6 from the surface of the plate 2 are eliminated, and the surface becomes smooth, so that the flow of the flue gas F flowing along these surfaces becomes smooth, and the surface of the hard solid matter in the flue gas F This significantly reduces the frequency of collision, reduces erosion and wear, and extends the life of the front cover plate 1 and the rear cover plate 2.

In the above-described embodiment, the rotor for the gas expander for recovering energy from the flue gas generated in the PCC plant has been described. However, the present invention is not limited to such an embodiment. But not
For example, the present invention can be applied to a turbine that recovers energy from high-temperature and high-pressure combustion gas containing a large amount of dust such as blast furnace gas.

[0024]

As described above, according to the gas expander rotor of the present invention, according to the constitution set forth in the claims, (1) the fitting portion between the blade root portion and the blade groove portion is hardened. A set screw that secures the cover plate to the rotor disk, which protects against the intrusion of flue gas mixed with solid matter, prevents the infringement of the flue gas and prevents accidental occurrence without impairing the fixation of the cover plate. It can be reliably prevented. (2) The protrusion of the set screw on the surface of the cover plate facing the flow of the combustion exhaust gas can be eliminated, and the cover plate having a long service life against the erosion of the combustion exhaust gas can be used. Can be further improved.

[Brief description of the drawings]

FIG. 1 is a side view of a rotor blade and a sectional view of a rotor disk, showing a first embodiment of a rotor for a gas expander of the present invention.

FIG. 2 is a perspective view showing a cover plate shown in FIG. 1; FIG. 2 (a) is a front cover plate, FIG. 2 (b) is a rear cover plate,

FIG. 3 is a side view of a rotor blade of a conventional rotor for a gas expander, and a cross-sectional view of a rotor disk.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Front cover plate 2 Rear cover plate 3 Projection part 4 Steam passage 5 Set screw 6 Set screw 7 Screw head 8 Screw head 9 Extruded material 10 Extruded material 11 Detent 12 Detent 13 Steam hole 14 Depression 15 Stop screw shaft 16 Set screw shaft body 010 Exhaust gas passage 011 Blades 012 Blade root 13 Airfoil 014 Cover plate 015 Set screw 016 Groove 017 Gap 018 Rotor disk 019 Blade groove 020 Groove bottom 022 Platform 022 Seal arm

Claims (1)

[Claims] 1. A rotor for a gas expander for recovering energy from a flow of flue gas into which hard dust is mixed, wherein a blade root of a moving blade that rotates with the flue gas and a rotor that fits the blade root. A set screw for fixing a cover plate that protects against the erosion of the combustion exhaust gas by blocking the front and rear of a blade groove portion provided on an outer peripheral portion of the disk to an outer peripheral portion of the rotor disk seals the combustion exhaust gas. A rotor for a gas expander, which is provided inside a seal arm provided on an outer peripheral portion of a disk.