DE4446395C2 - Swing flap for hot gas pipelines - Google Patents

Description

The invention relates to a rotary flap valve for hot gas pipelines according to the preamble of the An saying 1.

A flap according to the preamble of the claim 1 is known for example from DE-A-30 22 862. The flap consists of a for storing the Flap and for the transmission of the flap torque ends, provided with at least one shaft element central part and one the two wings of the flap forming closure plate.

The central part contains an elongated bowl, which is designed as a torsionally rigid molded body and just like the closure plate almost over the extends the entire length of the flap. The closure plate is also bowl-shaped in its central area mig trained and supplemented with this bowl-shaped Area the central part to a closed high len molded body.

Such control and butterfly valves, with their zen tral axis arranged transversely in a pipeline are arranged, but have the disadvantage that they esp especially with large spans and at high gas pressures A loss of cross-section even when open cause up to 30%.

From DE-C-41 36 907 is another rotary wing flap according to the preamble of claim 1 Lich, which has a plate-shaped closure part,  which is stiffened in a lattice shape and an axis of rotation having.

From DE-AS 15 00 005 is also a throttle valve known to reduce drag a stiffening in the form of a spatial framework having.

The invention is therefore based on the object Control and butterfly valve according to the preamble of the An Proverb 1 indicate the one with the flap open causes minor cross-sectional loss and at which it not to be deformed in the event of sudden temperature changes the closure plate and thus to leaks is coming.

This object is inventively characterized by nenden part of claim 1 solved by the carrier part as an open and in an opening point of the flap Spatial framework through which hot gas can flow forms and the closure plate is slidable is coupled to the carrier part.

Further refinements of the invention are the subject of subclaims.

The formation of the support part as a spatial framework reduces the cross-sectional area that cannot be flowed through the flap in its open position considerably. In Ver the cross can be the same as the well-known shell construction cut loss from 30% to 6%.

Flaps arranged in hot gas pipelines below conditions in the operation of a high and possibly very  rapidly changing temperature loads. Both large dimensions of such flaps come here due to excessive thermal expansion. This leads to ver Formations and tension in the support or wing part, so possibly after a sudden tempera door operation did not increase briefly is possible.

According to the invention, the closure plate is therefore gleitver slidably coupled to the carrier part.

Further embodiments of the invention are based on the Description of an embodiment and the drawing tion explained in more detail.

Show in the drawing

Fig. 1 is a plan view of the rotary wing flap,

Fig. 2 is a side view of the rotary wing flap,

Fig. 3 is an end view of the rotary wing flap,

Fig. 4 is a first, partially sectioned detailed view of the connection of the closure plate and carrier part and

Fig. 5 shows a second, partially sectioned Detailan view of this connection.

In Figs. 1 to 3 according to the invention is a Drehflü gelklappe for hot gas pipes shown. It consists essentially of a carrier part 1 , a closure plate attached to this and at least one on the carrier part, which is used to support the flap and to form a central pivot axis 3 a shaft element 3.

The carrier part 1 is formed as an open and in an opening position of the flap hot gas through which spatial truss. This truss is formed by a plurality of round bars, which are divided into a number of parallel bars 4 a arranged parallel to the pivot axis 3 a and zigzag-shaped round bars 4 b. Here, each two adjacent longitudinal bars 4 a b a zigzagging rod 4 coupled to each other, that the zig-zag extending rod 4b alternately at the inflection points with the one and the other longitudinal bar is rigidly connected (see Fig. 4). The connection of the longitudinal rod 4 a and the zigzag-shaped duri fenden round rod 4 b is advantageously carried out by welding.

The truss as illustrated in Fig. 3 in a section transverse to the longitudinal axis 3 a formed as an isosceles trapezoid. The longitudinal bars 4 a are each arranged in the four corners of this trapezoid. Furthermore, two additional longitudinal bars are arranged on the - on average - long baseline as a vertical projection of the two longitudinal bars of the short baseline. In this way, there are six areas on the outside of the truss between two longitudinal bars, between which the zigzag round bars 4 b are arranged. In addition, the two longitudinal bars of the - on average - short base line with the respectively perpendicular longitudinal bars on the long base line are connected to one another via again round zigzag round bars 4 b. In this way he gives himself an extremely stable support part, which is characterized by a minimal amount of material. Compared to a comparable valve in a shell construction, the material requirement is reduced by around 40 to 50%. As a result, the weight of the flap according to the invention is reduced accordingly, which has a positive effect on the acceleration times when closing and opening the flaps. Since particularly high-quality materials are used for the carrier part, the material savings also result in a corresponding reduction in costs.

Conveniently, it will be the diameter of the longitudinal bars 4 a select greater than the diameter of the zigzag-shaped extending round rods 4 b. For example, one could use the longitudinal bars with a diameter of 25 mm and the zigzag-shaped round bars with a diameter of 15 mm.

On the two short end faces of the carrier part, two holding plates 5 are provided for holding a hub arranged in the center, which receives a stub shaft 3 b. Of course, it is also possible within the scope of the invention to provide a continuous shaft instead of the two stub shafts 3 b, but this worsens the effect of an enlargement of the free cross section of the pipeline when the flap is open.

In the context of the invention, however, any other type of construction of the truss is also conceivable, so in particular the sectional shape transverse to the pivot axis 3 a is not limited to an isosceles trapezoid.

The closure plate 2 is formed by a flat metal plate, which has a thickness of 6 mm, for example. When closing, this closure plate comes into contact with corresponding sealing elements on the circumference of the pipelines. So that there is no deformation of the sealing plate 2 and thus leaks in the event of sudden temperature changes, the following connection of the carrier part and the sealing plate is provided in the exemplary embodiment shown:

The trapezoidal framework with its larger base area is connected to the closing plate 2 (see FIG. 3). For this purpose, four parallel rows of hooks 7 are provided on the closure plate 2 , which forms ge, for example, by simply folded flat iron. These hooks are aligned so that they ben a relative movement of the carrier part 1 and Ver closure plate in the plane of the closure plate 2 , but reliably prevent relative displacement or loosening of the connection in a different direction. The hooks 7 together with the closing plate 2 are each open at one side of U. During the assembly can therefore in a simple manner, the supporting part 1 on the closure plate 2 deposited and then pushed into the hook 7, so that they the corresponding Grip over the longitudinal bars 4 a of the carrier part 1 .

In order to prevent unintentional loosening in the opposite direction, a locking pin 8 is passed through a part provided in the middle of the closure plate 2 first bore 9 and on the other hand through an aligned with this bore second bore 10 on the Trä gerteil (see Fig. 5). The securing bolt 8 is then fixed in a suitable manner, for example by welding to the closure plate 2 . The individual hooks 7 now ensure that the closure plate 2 can expand starting from the first bore 9 due to temperature changes. The second bore 10 on the carrier part 1 is provided, for example, in a flat iron 11 welded between two longitudinal bars 4 a.

In order to prevent "turning" of the closure plate around its central point in the event of a one-sided temperature stress, a flat iron 12 is provided between the holding plates 5 , which has a slot 13 running in the direction of the pivot axis 3 a, into which one with the Locking plate 2 engages connected bolt 14 . Advantageously, a slot of this type is also provided in the region of the opposite shaft end 3 b. The exchange of on the closure plate 2 provided sealing elements or the sealing plate 2 itself can be performed in this construction by a simple unhooking of the closure plate after the securing bolts have been solved 8 and 10. FIG.

As can be seen in particular in FIG. 2, the cross section of a hot gas pipeline with an open flap according to the invention is constricted only by about 4 to 6%. The flap according to the invention is therefore particularly suitable for gas lines of gas turbines. The particularly simple replacement of a closure plate also makes it possible to use it in the case of more aggressive gases, such as those which arise in particular in the case of flue gas desulfurization or denitrification.

Claims (7)

1. Swing flap for hot gas piping, included

• a) a carrier part ( 1 ),
• b) a closure plate ( 2 ) attached to the carrier part
• c) and at least one on the carrier part ( 1 ) tes, for supporting the flap and for forming a central pivot axis ( 3 a) serving len element ( 3 ),

characterized in that

• a) the support part ( 1 ) is designed as an open and in an opening position of the flap of the hot gas flow-through bar, spatial framework, and
• b) the closure plate ( 2 ) is slidably coupled to the carrier part ( 1 ).

2. Flap according to claim 1, characterized in that the framework is formed from a plurality of round bars ( 4 a, 4 b). 3. Flap according to claim 2, characterized in that part of the round rods as longitudinal rods ( 4 a) are arranged parallel to the pivot axis ( 3 a). 4. Flap according to claim 3, characterized in that in each case two adjacent longitudinal bars ( 4 a) via a zigzag-shaped round rod ( 4 b) are coupled to one another in such a way that the round rod ( 4 b) running in zigzag each alternately at the break points with one and the other longitudinal rod ( 4 b) is firmly connected. 5. Flap according to claim 2, characterized in that the truss is trapezoidal in a section transverse to the pivot axis ( 3 a). 6. Flap according to claim 3 and 5, characterized net that at least in the corner points of the trapeze Longitudinal bars are arranged. 7. Flap according to claim 1, characterized in that the closure plate ( 2 ) at a central point (bore 8 ) on the carrier part ( 1 ) is fixed.