REACTOR WITH SHAFT COOLING

Abstract

Reactor for recovery or recycling of hydrocarbon products from hydrocarbon-containing material by decomposing and gasifying the material in a reactor housing, comprising a gas/particle separator device arranged to separate solid particles accompanying the gas and to return these particles directly to the reactor housing in the opposite direction to axially flowing gasified hydrocarbon products, and/or comprising a rotor shaft with axially running channels which are in flow communication with a coolant, and/or comprising a radial play formed between the periphery of a rotor and the inside of the reactor housing and amounting to at least 3 cm and at most 6 cm.

Claims

1. (canceled)

2. (canceled)

3. (canceled)

4. (canceled)

5. (canceled)

6. (canceled)

7. (canceled)

8. A reactor for recovering or recycling of hydrocarbon products from hydrocarbon-containing materials, comprising a cylindrical reactor housing extending axially between a rear, first end wall and a front, second end wall, a rotor rotatably arranged in the reactor housing and driven in rotation by means of a motor and a rotor shaft coaxially aligned with the reactor housing, the rotor shaft extending through the rear end wall into the reactor housing to which process material is fed radially or axially via an inlet to the reactor housing, gasified hydrocarbon products are discharged axially via a reactor gas outlet opening out centrally in the front end wall, and residual solid process material is discharged via a residual material outlet opening out peripherally in the reactor housing, wherein characterized in that at least a portion of the rotor shaft between the motor and the rotor is formed with channels running in the longitudinal direction of the rotor shaft, said channels being in flow communication with a coolant.

9. A reactor according to claim 8, comprising inflow and return flow channels running in parallel in the rotor shaft, the channels being individually in flow communication with a coolant supply and a coolant drainage arranged in a swivel that is rotatably mounted on the rotor shaft.

10. A reactor according to claim 9, wherein the swivel is supported on a free end of the rotor shaft protruding from a gearbox, and the cooling channels in the rotor shaft extend from said free end to the region of insertion of the rotor shaft through the rear end wall of the reactor housing.

11. A reactor according to claim 10, wherein the cooling channels of the rotor shaft are extended for cooling of a region of the rotor shaft which is sealed against the environment at the area of insertion of the rotor shaft through the rear end wall of the reactor housing.

12. A reactor according to claim 8, wherein the cooling channels of the rotor shaft extend for cooling of a length of the rotor shaft which is rotatably journaled and supported in a reactor stand.

13. A reactor for recovery or recycling of hydrocarbon products from hydrocarbon-containing materials, comprising a cylindrical reactor housing extending axially between a rear, first end wall and a front, second end wall, a rotor rotatably arranged in the reactor housing and driven in rotation by means of a motor and a rotor shaft coaxially aligned with the reactor housing, the rotor shaft extending through the rear end wall into the reactor housing to which process material is fed radially or axially via an inlet to the reactor housing, gasified hydrocarbon products are discharged axially via a reactor gas outlet opening out centrally in the front end wall, and residual solid process material is discharged via a residual outlet opening out peripherally in the reactor housing, wherein between the periphery of the rotor and the inside of the reactor housing there is formed a radial play of 2 to 8 cm.

14. A reactor according to claim 13, wherein the rotor has rotor arms extending radially from the rotor shaft, hammers pivotally journaled in the outer ends of the rotor arms which can pivot during rotation of the rotor between a retracted position towards the rotor arm and a substantially radially outwardly extended position away from the rotor arm, wherein the length of the rotor arm is dimensioned so that in the extended position of the hammer a radial distance of 3-6 cm remains between the hammer and the inside of the reactor housing.

15. A reactor according to claim 14, wherein the rotor comprises rotor arms distributed one after the other in a helical formation along the rotor shaft, resulting in a surrounding agitated layer of non-fluidized finely ground material between the rotor and the inside of the reactor housing.

16. A method for recovering or recycling of hydrocarbon products from hydrocarbon-containing materials using a reactor for recovery or recycling of hydrocarbon products from hydrocarbon-containing materials, comprising a cylindrical reactor housing extending axially between a rear, first end wall and a front, second end wall, a rotor rotatably arranged in the reactor housing and driven in rotation by means of a motor and a rotor shaft coaxially aligned with the reactor housing, the rotor shaft extending through the rear end wall into the reactor housing to which process material is fed radially or axially via an inlet to the reactor housing, gasified hydrocarbon products are discharged axially via a reactor gas outlet opening out centrally in the front end wall, and residual solid process material is discharged via a residual outlet opening out peripherally in the reactor housing, wherein between the periphery of the rotor and the inside of the reactor housing there is formed a radial play of 2 to 8 cm, wherein said method comprise: generating and maintaining an agitated layer of non-fluidized finely ground material surrounding the reactor rotor, said layer having a radial extension of at least 2 to 8 cm between the rotor and the inside of the reactor housing.

17. A method according to claim 16, comprising providing a rotor of a helical structure having rotor arms distributed one after the other in a helical formation along a rotor shaft, and driving the rotor in rotation in order to generate and maintain, by means of rotor arm tips evenly distributed over the periphery of the rotor, a particle layer of substantially homogeneous radial depth surrounding the rotor.

18. A reactor according to claim 13, wherein between the periphery of the rotor and the inside of the reactor housing there is formed a radial play of 3 to 6 cm.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0032] Exemplary embodiments of the invention are described in more detail below with reference to the accompanying schematic drawings, of which

[0033] FIG. 1 shows a longitudinal section through a reactor,

[0034] FIG. 2 shows a broken-away cross section through a reactor housing with rotor,

[0035] FIG. 3 shows an embodiment of a rotor in perspective, and

[0036] FIG. 4 is a diagram showing size distribution of solid particles in a peripheral area of the reactor housing surrounding the rotor

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0037] A reactor 1 comprises a rotor 3 rotatably arranged in a cylindrical reactor housing 2. The rotor 3 is driven in rotation by a motor 4 via a rotor shaft 5. The motor 4 may be driven electrically, with diesel, or petrol, or with another energy source. The motor speed can be reduced by a gear 6 in a gear housing 7 to a rotor speed suitable for the reactor. A suitable rotor speed can typically be in the order of 400 to 600 revolutions per minute. By means of two bearing sets 8 and 9, respectively, the rotor shaft 5 is radially and axially mounted in a reactor stand 10. From its journaling in the reactor stand, the rotor shaft 5 extends cantilevered into the reactor housing 2 via a centrally located bushing in a first/rear end wall 11 of the reactor housing. The rotor shaft 5 and the rotor 3 are hereby coaxially aligned with the reactor housing 2.

[0038] The insertion of the rotor shaft through the end wall 11 is sealed to the surroundings by means of a sealing box 12 with seals which are in contact with the rotor shaft 5. The sealing box 12 may be of the active type to which a fluid, for example nitrogen gas or other inert medium, is fed, at a pressure higher than the prevailing pressure in the reactor housing, during operation, to counteract leakage of gasified hydrocarbon products out of the reactor housing, along the rotor shaft.

[0039] The reactor housing 2 comprises a cylindrical housing 13 which extends axially between the first/rear end wall 11 and a second/front end wall 14. The reactor housing is supported in the reactor by the first/rear end wall 11 being fixedly connected to the reactor stand 10, for example by means of a bolted joint 15.

[0040] The rotor 3 comprises a number of rotor arms 16 which are rigidly mounted on the rotor shaft and extend radially therefrom. At their outer ends, the rotor arms support an articulately arranged rotor arm tip or hammer 17. The rotor arms 16 may be distributed around the rotor shaft in groups of, for example, three, following one another in a number of mutually offset turns so that the rotor has a helical structure, see FIG. 3. This structure means that the rotor arm tips or hammers 17 are distributed evenly over the periphery of the rotor in both the axial direction and in the circumferential direction.

[0041] For reasons already explained above, the housing 13 and rotor 3 of the reactor housing 2 are dimensioned with respect to their radii so that a free space/an annular volume is formed between them and a circumferential gap D having a radial depth of at least about 3 cm and at most about 6 cm from the inside of the reactor housing. As a result, during the operation of the reactor, a substantially cylindrical layer L of solid particles is formed outside the rotor, see FIG. 2. The rotor's high tangential velocity V.sub.1, which may be in the order of 30-40 m/s, causes a strong agitation and stirring in the inner interface of the layer L. In this region an efficient mechanical decomposition and grinding/atomization of solid material down to a minimum particle size in the order of a few thousandths of a millimeter is achieved. How the particle size is distributed in the layer L is illustrated by the diagram in FIG. 4 which indicates a concentrated presence of the finest particles in the range of about 30 mm to about 60 mm. During operation, process material may be fed into the reactor housing via a radially opening inlet through the cylindrical casing of the reactor housing (not shown), or as in the exemplary embodiment via an axially opening process material inlet 18 accommodated in the front end wall 14. After processing in the reactor housing material, residual process material, i.e. non-gasified material, is discharged via a residual material outlet opening out peripherally into the reactor housing, and is transported therefrom further through a tangentially connecting transport pipe 19.

[0042] Hydrocarbons gasified in the process are discharged in the axial direction via an axially opening reactor gas outlet 20 centrally located in the front end wall 14. This solution is facilitated by the rotor shaft 5 extending self-supportingly into the reactor housing without the need for support from the front end wall 14. The solution also implies that the rotor 3 may be extended backwards to utilize the entire length of the reactor housing up to the rear end wall 11, since the partition inside the reactor housing required in previous prior art solutions to separate a gas outlet located there from the process in the reactor housing, can now be avoided. This solution thus provides a larger efficient process volume in the reactor housing or chamber and the load on the shaft 5 and the bearings 8, 9 becomes more favorable as the load is centered closer to the suspension in the bearings 8, 9.

[0043] Connected to the front end wall is a gas/particle separator device 21 which is arranged to separate the solid particles accompanying the gas from the reactor housing and to return them directly to the reactor housing in the opposite direction to the axially outflowing gas.

[0044] The gas/particle separator device 21 consists of a cylindrical pipe 22 open towards the reactor gas outlet 20. In an opposite front end, facing away from the reactor housing, an outlet 23 for gas flowing through the tube is accommodated. The outlet 23 of the pipe opens substantially radially into the pipe wall and may via a transport line 24 be in flow connection with a downstream post-treatment device (not shown). In the pipe 22 a feed screw 25 is arranged and drivable for rotation by means of a motor, such as an electric motor 26. A drive shaft 27 extends from the motor 26 through a sealed bearing housing 28 connected to the front end of the tube 22. As indicated above, the post-treatment device may, for example, be in the form of a condensing unit, distillation unit or a combustion unit. The feed screw 25 has a helically rotated blade and is driven by the motor 26 to return solid material particles entering the tube 22 to the reactor housing. The feed screw 25 is driven at high speed, preferably in the order of 2500-3500 rpm, to effect a radial layering and separation of solid particles and gas by centrifugal action before the gas reaches the outlet 23 in the pipe wall. The transport of the gas through the pipe 22 is promoted by the relative negative pressure prevailing in the transport line 24.

[0045] A free end 29 of the feed screw 25 extends past the open end of the pipe to reach, via the reactor gas outlet 20, a distance into the reactor housing, such as 10-40 mm. The design is made possible by the rotor shaft 5 extending cantilevered into the reactor housing, operatively supported by the reactor stand 10 and journaled by the two bearing sets 8 and 9 located outside the reactor housing. In this preferred embodiment, the feed screw may throw the returned solid particles radially outwards in front of the rotor (seen in a direction from rotor 3 to motor 4). Thus, the particles are returned to the process some distance outside the rotor shaft and are prevented from returning directly with the gas stream out of the reactor housing.

[0046] From a free end 30 of the rotor shaft 5 protruding from the gear housing 7, inside the rotor shaft, a pair of longitudinally parallel channels 31 and 32 are extending, which are interconnected through a transition 33 in a front region of the rotor shaft. The channels 31 and 32 extend in the longitudinal direction up to or slightly past the part of the rotor shaft surrounded by the sealing box 12. It also follows that the cooling channels extend for cooling the rotor shaft in the part thereof which is journaled and supported in the reactor stand. At the opposite end, the channels 31 and 32 are in flow communication with a coolant which can circulate through the channels for cooling the rotor shaft. The channels 31 and 32 serve as supply and return flow channels for coolant from/to a coolant supply, respectively, and are individually in flow communication with a coolant supply 34 and a coolant drainage 35, respectively, arranged in a swivel 36 rotatably supported on the rotor shaft.

[0047] The cooling contributes to a lower temperature in the rotor shaft at the sealing box 12 and at the bearings 8, 9, which increases the service life of these components and provides a better economy and operational reliability compared with known technology.

[0048] The invention is of course not limited to the embodiments described above but can be varied within the scope of the appended claims.