Gas flow diverter

Abstract

A gas flow diverter receives large volumes of hot gases from a gas turbine into a chamber in which is a pivotally mounted blade adapted to close either the outlet port to a heat recovery steam generator or the outlet port to the stack. Each port is surrounded by an open channel, the two side walls of each of which are provided with an exposed seal arranged one beyond the other. One or both surfaces of the blade is insulated, the insulated surface(s) being covered with steel cladding and the uncovered surface being a stainless steel membrane adapted to resist corrosion from the hot gases. The steel cladding is connected through insulation to the underlying structure in a manner permitting but confining the expansion of the cladding. The blade's border is provided with first and second marginal ledges adapted, respectively, when the blade is in a closed position to engage a different one of the two exposed seals bordering an outlet port, thus establishing the channel as a closed passageway surrounding the closed port which may be further sealed against leakage by discharging sealing air into it. The blade is shifted between its two operative positions by means of a reversible drive including toggle joints connected to the blade by a unit which is shiftable in response to forces exerted by the expanding or contracting toggle joints. During blade movement the sealing air is cut off and its passageway into the chamber closed against the escape of hot gases.

Description

Claims

1. In a gas flow diverter for diverting hot gases from an inlet port to either of first and second mutually spaced outlet ports of a chamber by a blade pivotally mounted to swing between two positions within the chamber in each of which one outlet port is closed by the blade and the other is opened, said blade being connected to a pivot shaft rotatably mounted within said chamber and being linked by toggle joints to an actuator shaft spaced from and parallel to said pivot shaft, the improvement comprising

a marginal frame about said blade, both sides of which comprise first ledges, and a central projection, both sides of which comprise second ledges,

a U-shaped sealing frame surrounding each outlet port, and comprising first and second side walls, with said first side wall longer than said second side wall, each of said sealing frames secured to the chamber wall and having an open end that opens into the chamber; and

leaf spring sealing members mounted on said side walls;

the sealing members of said first and second side walls being constructed and arranged to enter into sealing engagement with said first and second ledges, respectively, on the appropriate side of said blade marginal frame when said blade is in one of said two positions and said actuator shaft being operable to adjust the position of said blade between said first and second positions.

2. The diverter of claim 1 further comprising means for delivering sealing air into a closed space formed within either of said sealing frames when such sealing frame is engaged by said blade.

3. The diverter of claim 2 further comprising means to isolate the interior of the chamber from the means for delivering sealing air during movement of said blade between its two positions.

4. The diverter of claim 1 including a layer of insulation secured to and lining each interior surface of said chamber and wherein said blade further comprises at least one strengthening member to which its marginal frame is connected, a layer of insulation covering at least that side of said blade remote from the connections to said actuator shaft, cladding overlying said layer of insulation, and means for retaining said layer of insulation in place, said retaining means being constructed and arranged to permit thermal expansion of the cladding.

5. The diverter of claim 4 including a layer of insulation on the other side of said blade positioned on each side of each strengthening member.

6. The diverter of claim 4 or claim 5 wherein said retaining means comprises a series of pins anchoring the insulation to the underlying blade structure and extending through the cladding and insulation through oversized openings to permit such thermal expansion.

7. The diverter of claim 4 including pivotal connecting means connecting each of said toggle joints to a respective strengthening member.

8. The diverter of claim 7 wherein said strengthening members are at least two in number and are spaced from each other and from the blade ends.

9. The diverter of claim 8 wherein each of said pivotal connecting means comprises a base plate connected to a corresponding strengthening member, a second plate pivotally connected to the said base plate, a toggle joint link pivotally connected to said second plate, and resilient means connected between said plates, thereby to enable said second plate to move relative to said base plate in response to thermal expansion forces exerted thereon by the toggle joint connected thereto.

10. The diverter of claim 7 wherein said strengthening members are at least two in number and extend the length of the blade.

11. The diverter of claim 4 wherein said blade further comprises a stainless steel membrane defining the area of the chamber outlet ports and at least one strengthening member for said membrane, said layer of insulation covering only that side of said blade remote from the connections to said actuator shaft.

12. The diverter of claim 11 wherein said marginal frame is formed of two parts comprising a secondary channel frame member both sides of which comprise the first sealing ledges and a central member connected to said secondary frame having surfaces defining said second ledges, said members being connected to each other by retaining means permitting thermal expansion of the blade relative to said members.