A METHOD OF PERFORMING AN OPERATION ON A VESSEL ASSEMBLY, AS WELL AS A VESSEL ASSEMBLY

Abstract

A method of performing an operation such as a maintenance operation on a vessel assembly, said vessel assembly having a vessel, such as a crystallizing vessel, a rotor, said rotor including an upright, rotatable shaft, said shaft having a top shaft section extending above a top wall of the vessel, to perform maintenance. The top shaft section includes a first member chosen from a male member and a female member for engaging a device. The device has a top end, and a bottom end. The bottom end includes a complementary second member for the first member. According to the method, the device is connected to the top shaft section of the shaft, the rotor is lifted by lifting the shaft at its top end section using the device, following which the operation is performed.

Claims

1. A method of performing an operation on a vessel assembly, said vessel assembly comprising a vessel, such as a crystallizing vessel, said vessel comprising a top wall, a bottom wall and an upright wall extending from the bottom wall to the top wall, said top wall, bottom wall and upright wall defining a lumen, a superstructure on top of the vessel, said superstructure comprising a bearing, said bearing comprising an upper race member, a lower race member and roller bodies between said upper race member and said lower race member, said lower race member being attached to the superstructure, and a locking nut for locking the bearing, said locking nut comprising an inner thread, a rotor, said rotor comprising an upright, rotatable shaft, said shaft comprising i) a top shaft section extending above the top wall and ii) a bottom shaft section in said lumen, said top shaft section being provided with said upper race member, allowing the rotor to rotate along a shaft axis of the upright, rotatable shaft in line with the axis of rotation of the bearing, and comprising an outer thread for engaging the inner thread of the locking nut to lock the upper race member at a desired location on the top shaft section; and a plurality of rotor elements-0-40) attached to said bottom shaft section; wherein the rotor is stopped and the operation is performed; characterized in that the top shaft section comprises at a location above the upper race member a first member chosen from a male member and a female member for engaging a device, said device having a top end, and a bottom end, said bottom end comprising a complementary second member for engaging the top shaft section, said complementary second member being chosen from a female member and a male member; wherein the device is connected to the top shaft section of the shaft, the rotor is lifted by lifting the shaft at its top end section using the device, and the locking nut is rotated upwardly along the top shaft section of the rotor, following which the operation is performed.

2. The method according to claim 1, wherein the rotor comprises an element independently chosen from a recess and a protrusion located below the lower race member; wherein after rotating the locking nut over at least part of the thread upwards, the rotor is lowered and stabilized at a given height using said element.

3. The method according to claim 2, wherein the vessel comprises a seal sealing against the top shaft section, said seal being located above the element.

4. The method according to claim 2, wherein the element is a tapered body tapering away from top end of the top shaft section, said tapered body having a central axis coinciding with the central axis of the shaft, and the vessel comprises a seat for receiving said body, said seat having a central through-opening for the rotatable shaft.

5. The method according to claim 4, wherein when in contact, the seat and the tapered body are in an uninterrupted contact in the rotational direction of the rotor.

6. The method according to claim 1, wherein the device is lifted hydraulically.

7. The method according to claim 1, wherein the superstructure provides a mount for a motor, said motor being a motor for rotating the rotor, wherein before the device is connected to the top shaft section the motor is removed, and the device is attached to the shaft and a hydraulic actuator for lifting the rotor hydraulically is mounted to the superstructure.

8. The method according to claim 1, wherein after removal of the motor from the mount, a support is mounted to the mount and the device is attached to the shaft using the support

9. The method according to claim 1, wherein the first member of the top shaft section and the complementary member of the device are threaded members.

10. A vessel assembly, said vessel assembly comprising a vessel, such as a crystallizing vessel, said vessel comprising a top wall, a bottom wall and an upright wall extending from the bottom wall to the top wall, said top wall, bottom wall and upright wall defining a lumen, a superstructure on top of the vessel, said superstructure comprising a bearing, said bearing comprising an upper race member, a lower race member and roller bodies between said upper race member and said lower race member, said lower race member being attached to the superstructure, and a locking nut for locking the bearing, said locking nut comprising an inner thread, a rotor, said rotor comprising an upright, rotatable shaft, said shaft comprising i) a top shaft section extending above the top wall and ii) a bottom shaft section in said lumen, said top shaft section being provided with said upper race member, allowing the rotor to rotate along a shaft axis of the upright, rotatable shaft in line with the axis of rotation of the bearing, and comprising an outer thread for engaging the inner thread of the locking nut to lock the upper race member at a desired location on the top shaft section; and a plurality of rotor elements attached to said bottom shaft section; characterized in that the rotor comprises an element located below the lower race member, wherein the element is a tapered body tapering away from the top end of the top shaft section, said tapered body having a central axis coinciding with the central axis of the shaft, and the vessel comprises a seat for receiving said body, said seat having a central through-opening for the rotatable shaft.

11. The vessel assembly according to claim 10, wherein when in contact, the seat and the tapered body are in an uninterrupted contact over the circumference of the tapered body.

Description

[0054] The present invention will now be illustrated with reference to the drawing where

[0055] FIG. 1A and FIG. 1B show a side view and a cross-sectional view of a crystallizer;

[0056] Fig. C shows a cross-sectional detail of a superstructure of the crystallizer of FIG. 1B;

[0057] FIG. 2 shows a perspective cross-sectional view of part of a superstructure of the crystallizer of FIG. 1C;

[0058] FIG. 3A to FIG. 3I show cross-sectional views of a top of a vessel, demonstrating a method of performing an operation; and

[0059] FIG. 4 shows a cross-sectional view of an alternative vessel assembly.

[0060] FIG. 1A and FIG. 1B show a side view and a cross-sectional view respectively of a vessel assembly 100, such as a crystallizer 100, said crystallizer 100 comprising a crystallizing vessel 110 comprising a top wall 111, a bottom wall 112 and an upright wall 113 extending from the bottom wall 112 to the top wall 111. The top wall 111, bottom wall 112 and upright wall 113 define a lumen 114 for containing a fluid subjected to crystallisation, such as para-xylene, a compound used for the production of PET.

[0061] The crystallizer 100 comprises a rotor 130. The rotor 130 comprises a shaft 131, with a top shaft section 131′ extending above the top wall 111 and a bottom shaft section 131″ extending in the lumen 114.

[0062] The bottom shaft section 131″ is provided with a plurality of rotor elements 140. The rotor elements 140 comprise arms 141 provided with scrapers 150. In use, the upright wall 113 will be cooled, causing a component to crystallize against the inside of the upright wall 113. There the crystallized component is scraped from the upright wall 113 and new crystals may form.

[0063] On top of the vessel 110 a superstructure 170 is provided.

[0064] As can be seen in the cross-sectional view of the superstructure FIG. 1C, the superstructure 170 is provided with motor 160 for driving the rotor 130 via a gear box 161 and a torque limiter 162 connected to to the top end of the top shaft section 131′. The torque limiter 162 is provided should the rotor 130 get stuck. A tapered roller bearing 175 is provided to allow the rotor 130 to be suspended from the superstructure 170. A seal 180 is also provided to form a barrier between the lumen 114 and the outside of the vessel 110.

[0065] The bearing 175 comprises an upper race member 177 held by the top shaft section 131′, a lower race member 178 fixed to the superstructure 170 and roller bodies 179.

[0066] Below the seal 180 the top shaft section 131′ is provided with a frusto-conically tapered element 190 and the top wall 111 is provided with a seat 195 having a complementary tapered recess 196 for receiving the tapered element 190. When in contact, the contact area of the surface defining the recess 196 and the bottom surface of the frusto-conically tapered element 190 provides for a seal, as will be explained later.

[0067] To perform an operation on the vessel assembly 100, the rotor 130 is lifted. This is done using a device 200 which is basically a rod 200. In FIG. 2 perspective cross-sectional view of part of the superstructure 170 is shown. When in use, the motor 160 is mounted to a ring of holes 271 of the superstructure. For performing an operation, the motor 160 and the torque limiter 162 have been removed.

[0068] They have been replaced by a support bar 210 that is bolted to the superstructure 170 using the same holes 271 normally used for mounting the motor 160.

[0069] The device 200 comprises a threaded male distal end 201 that is introduced into a threaded female recess 232 in the top end (shown as a cut out) of the top shaft section 131′.

[0070] The support bar 210 is provided with a hydraulic jack 230 engaging the top distal end 202 of the device 200.

[0071] FIG. 3A to FIG. 3I show cross-sectional views of a top of a vessel, demonstrating a method of performing an operation on the crystallizer 100 of FIG. 1A.

[0072] FIG. 3A shows the superstructure 170, provided with the motor 160, the gear box 161, and the torque limiter 162. As a first step, these are removed (FIG. 3B).

[0073] Now the superstructure 170 is provided with the support bar 210, the hydraulic jack 230 and the device 200 (FIG. 3C). The support bar 210 is bolted to the superstructure 170 using bolts 301.

[0074] FIG. 3D through FIG. 3I show the remainder of the steps for preparing the crystallizer 100 for the operation.

[0075] FIG. 3D corresponds to FIG. 3C. It depicts the seat 195 comprising recess 196 for receiving the tapered element 190 provided on the top shaft section 131′ and a through-hole 395 for the rotor shaft 131. In use, the outer surface of the tapered element 190 and the inner surface of the recess 196 are not in contact. The weight of the rotor 130 is born by the superstructure 170 via the bearing 175. Two ring halves 375 are sandwiched between a locking nut 320 and the bearing. The top shaft section 131′ has a circumferential groove 331 for receiving the inner edges of the ring halves 375.

[0076] After lifting the rotor 130 using the hydraulic jack 230, the locking nut 320 is rotated, moving it upwards (FIG. 3E) over 15 mm. This allows the ring halves 375 to be removed (FIG. 3F).

[0077] Now the rotor 130 can be lowered through the bearing 175 until the tapered element 190 rests in the recess 196 of the seat 195 (FIG. 3G).

[0078] This allows the the device 200, hydraulic jack 230, the support bar 210 to be removed (FIG. 3H), in case the operation requires this. For example, the bearing 175 may be removed, as well as the seal 180 for example for replacement or cleaning thereof as the operation to be performed. The circumferentially extending continuous contact area of the recess 196 and the outer surface of the tapered element 190 acts as a seal, providing a barrier between the lumen 114 and the outside environment of the vessel 110. FIG. 4 shows a cross-sectional view of an alternative vessel assembly, that is an Rotating Disc Contactor (RDC) vessel 400, wherein the rotor element 140 is a disc 440.