DE4416037C1 - Pressurised gasification reactor sealed by disc fabricated by conjoined pipe rings - Google Patents

Abstract

A pressurised gasification reactor has an opening which is sealed by an assembly which also holds the burner located within a cylindrical reactor. The reactor has a central passage to which the burner is fitted and fixed by a flange. A cooling disc (30) blocks off the reaction chamber end of the assembly. The novelty is that the cooling disc (30) is built up from a series of conjoined pipe rings (27) which are connected to an inner cooling cylinder ring (7) and an external cooling cylinder ring (6), and that the cooling water inlet (21) and the cooling water outlet (22) pass through the assembly flange (1). The combustion dust inlet (15) is integrated in the burner support. The circular chamber (19) between the internal and external ring chamber mantle (8) is filled with fire-resistant material by means of flange (1) inlets (17) which may be closed off.

Description

The invention relates to a device for closure a driveway and for burner attachment for Pressure gasification reactors.

The device can be used wherever the reactor access opening in pressure gasification reactors must be closed and cooled and one Burner attachment for holding a burner, for example with flame monitoring, must be available and there is a supply of fuel dust.

The previously known versions of Torch mounting devices describe brackets for combined burners with coal dust burner, Pilot burners and flame monitoring devices. These Burner mounting devices are pure Holding and guiding function for the burner, whereby the No problem of supplying fuel dust with these burners is feasible. A burner mounting device is described for example in DD 2 69 065. Through the as the outer cooling wall, the cooling pipes are pulled up at these burners with the risk of slagging Jamming, which can be countered by spring elements can. Another solution to these deadlocks too is avoided in DD 1 51 585 by the presence of Meets predetermined breaking points.

Based on the shortcomings of the prior art the invention has for its object a device for Burner attachment and to lock one Access opening of pressure gasification reactors develop the safe operation of  Pressure gasification reactors in every operating situation, one simplified design of the associated burner allows and a supply of fuel dust in allowed the reactor.

This task is carried out by the characteristic part of the first claim solved.

The subordinate claims give favorable Variants of the invention again. The solution according to the invention provides that a Cooling disc the reaction space end of the device to close the access opening that closes off interconnected pipe rings is constructed. These interconnected pipe rings are on an inner one Cooling cylinder ring and an outer cooling cylinder ring connected, the cooling water inlet and outlet is guided through the device flange, and the Annulus between the outer and inner annulus jacket over closable filling openings in the device flange is preferably filled with refractory material, whereby a fuel dust supply in the Burner fastening device is integrated. It is advantageous between the annular gap and the Attach a pressure compensation line to the annulus. These Pipe can be arranged on the nozzle. The device according to the invention is in the cylindrical Opening on the head, which also serves as an access opening of the reactor used, the reaction chamber facing circular area as cooling surface made of ring tubes, preferably with pens. This The area of the device forms a when in use Part of the reactor cooling wall. To accommodate the burner is located centrally in the device cylindrical guide extending from the device flange to the Cooling tube circuit area limited by a cooling tube jacket is. In the area of the cooling pipe circular area is the cylindrical bushing expands and forms  burner used an annular chamber. In this ring chamber opens tangentially with a certain slope of the Fuel dust channel. The annulus between the outside and inner cylindrical cooling ring is lockable Openings in the device flange preferably with Refractory material filled out. In this room you can but also a suitable gas. The cooling tube rings are elastic by means of sheet metal brackets with rod anchors Device flange connected. The outer cooling jacket with a cylindrical smooth design ensures a unhindered assembly and disassembly of the Fastening device. In addition to this advantage are the device according to the invention predetermined breaking points and Spring elements are no longer necessary. Through integration the dust supply in the burner fastening device can the construction of the burner in the burner length, the diameter and the total mass significantly reduced become. Further advantages of the invention Device are a good supply of the fuel dust to the Burner mouth and good overall cooling of the device, also with regard to the burner.

The device according to the invention is described below of 5 figures and an embodiment. The figures show:

Fig. 1 section AA through the device according to the invention from Fig. 2,

Fig. 2 shows a section B-B through the inventive device of FIG. 1,

Fig. 3 section CC of the inventive apparatus of Fig. 2,

Fig. 4 is a section DD of the inventive apparatus of Fig. 2,

Fig. 5 detail Z from Fig. 2 in different sectional views.

In the example shown in Fig. 1 Vorrichtungsflansch 1, the cooling water supply pipe 21 and the cooling water discharge 22 are integrated. The cooling water is fed to the inner cooling cylinder ring 7 via a half-pipe channel 5 . In the lower part of the cooling cylinder tube ring 7 , the cooling water is guided several times through guide plates 14 and then flows through an opening into the inner tube ring 12 . The transfer of the cooling water from pipe ring 27 to pipe ring to the outer pipe ring 13 is ensured by fittings 23 . After circumnavigation of the outer tube ring 13 , the cooling water flows into the outer cooling cylinder ring 6 and is also guided several times through guide plates 14 in the lower part. The cooling water leaves the cooling cylinder ring via the cooling water discharge line 22 and exits the device.

By means of a dust feed-through 16 in the device flange 1 , the dust feed pipe 15 leads through the annular space 19 and through a further feed-through 24 in the inner cooling cylinder ring 7 into the annular chamber 25 . The dust feed pipe 15 emerges tangentially to the burner wall with an inclination between 10 ° and 30 ° into the annular chamber 25 formed between the burner 18 and the annular chamber jacket 14 .

A pressure compensation line 32 is integrated between the annular gap 26 and the annular space 19 .

Flushing gas is passed into the annular chamber 25 through the annular gap 26 between the burner 28 and the inner cooling cylinder jacket 10 and the dissolution or swirling of the dust flow is supported by this flushing gas flow. The purge gas nozzle 3 is arranged between the burner mounting flange 2 and the device flange 1 .

A guide bushing 29 is inserted above the annular chamber 25 in the inner cooling cylinder jacket 10 to center the burner 18 .

The annular space 19 is filled with precious corundum through the closable filling openings 17 . The cooling disc 30 with pins 31 is sputtered with an SiC compound. The tubular rings 27 are connected several times by means of sheet metal brackets 20 to the device flange 1 via anchors 28 .

Reference list

1 device flange
2 mounting flange
3 purge gas nozzles
4 outer cooling cylinder jacket
5 half-pipe channel
6 outer cooling cylinder ring
7 inner cooling cylinder ring
8 outer annulus casing
9 Inner annulus casing
10 inner cooling cylinder jacket
11 annular chamber jacket
12 inner tube ring
13 outer tube ring
14 baffle
15 fuel dust supply pipe
16 dust duct
17 filling opening
18 burners
19 annulus
20 sheet metal brackets
21 Cooling water supply
22 Cooling water drainage
23 fitting
24 implementation
25 ring chamber
26 annular gap
27 pipe ring
28 anchors
29 guide bush
30 cooling disc
31 pin
32 Pressure equalization line

Claims (6)

1. Device for closing a drive-through opening and for fastening the burner for pressure gasification reactors which are inserted into a cylindrical opening of the reactor and have a central passage for receiving the burner and a flange for fastening to the reactor is characterized in that a cooling disk ( 30 ), which closes the end of the device on the reaction space side, is constructed from interconnected pipe rings ( 27 ) which are connected to an inner cooling cylinder ring ( 7 ) and an outer cooling cylinder ring ( 6 ) and the cooling water supply line ( 21 ) and cooling water discharge line ( 22 ) through the device flange ( 1 ) are guided, a fuel dust supply ( 15 ) being integrated in the burner attachment. 2. Device according to claim 1, characterized in that the fuel rod feed in the device flange ( 1 ) is integrated by means of a dust feed ( 16 ) and the fuel dust through a dust feed pipe ( 15 ) inclined tangentially into a combination at the end of the side facing the reactor chamber of the device annular chamber ( 25 ) formed with the burner ( 18 ) inserted emerges and purge gas emerges from an annular gap ( 26 ) between the burner ( 18 ) and inner cooling cylinder jacket ( 10 ) into the annular chamber ( 25 ) and combustible dust and purge gas together from the annular chamber ( 25 ) get into the reactor. 3. Device according to claims 1 and 2, characterized in that the cooling surfaces of the tubular ring ( 27 ) are provided with pins ( 31 ). 4. The device according to claim 1, characterized in that the annular space ( 19 ) between the outer and inner ring jacket ( 8 , 9 ) is filled with solid material. 5. The device according to claim 4 characterized in that Refractory material used as solid backfill material becomes. 6. Device according to claims 1 to 4, characterized in that a pressure compensation line ( 32 ) is arranged for pressure equalization between the annular gap ( 26 ) and the annular space ( 19 ).