NO336314B1 - Apparatus and method for removing magnetic material from a fluid stream - Google Patents

Description

DEVICE AND METHOD FOR REMOVAL OF MAGNETIC MATERIAL FROM A FLUID FLOW

The invention relates to a device and a method for removing magnetic material from a fluid flow. More specifically, the invention relates to the removal of magnetic material from a drilling fluid stream, where the magnetic material is removed by means of a plurality of magnetic rods which are in alternating contact with the drilling fluid, and where the magnetic material is removed from the magnetic rods by means of a scraper, a non- magnetic sheath or by deactivating electromagnets.

During the drilling of petroleum wells, circulating drilling fluid is used, among other things, to bring cuttings and other materials to the surface. In some operations, magnetic material will be added to the drilling fluid. Magnetic material in the form of steel shavings can, for example, be added to the drilling fluid during operations where holes are milled in a casing.

It is common to allow the drilling fluid that returns to the surface to flow through an open part of a so-called return run. In the return run, permanent magnets are usually arranged, preferably in the form of magnetic rods, to collect magnetic material such as steel shavings, iron shavings and iron pieces.

Depending on the supply of magnetic material, the magnetic rods must be cleaned at different time intervals. Usually the magnets are cleaned manually by pulling the magnets out of the return run by an operator who inspects the degree of saturation of the magnets. When the magnets are deemed to be saturated with magnetic material, the magnets are cleaned manually.

The drilling fluid often contains chemicals and gases that contribute to making the area near the magnetic rods unsuitable for living for personnel working in the area. There is therefore a need for a device that can carry out the cleaning operation automatically.

Automatic cleaning devices are known, see for example US 5190159, where magnet posts are pulled horizontally through a cleaning ring. An unfortunate feature of many known automatic cleaning devices is that they are relatively space-consuming. It has therefore been difficult to arrange them in or at existing return runs.

US 2011/203976 A1 describes a magnetic separation apparatus for separating magnetic materials from non-magnetic materials in a liquid stream. The apparatus can consist of several sets of magnets placed across the liquid flow. Magnetic material sticks to the rods. To clean the magnetic rods, they are pulled out of the liquid flow through the chamber wall and the magnetic material is removed using a scraper.

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology.

The purpose is achieved according to the invention by the features indicated in the description below and in the subsequent patent claims.

In a first aspect, the invention relates to a device for removing magnetic material from a fluid flow, where the device comprises at least one first and at least one second magnetic rod and where the magnetic rods in an active position are surrounded by the fluid flow, and where the magnetic rods in a passive position is not surrounded by the fluid flow, and where the device further comprises at least a first stand, a second stand and a holding device, and where the first stand comprises at least one first magnetic rod, and where the second stand comprises at least one second magnetic rod, and where the first rack and the second rack are arranged to respectively displace the at least one first magnetic rod and the at least one second magnetic rod between the active position and the passive position and where the holding device is arranged to engage with the magnetic rods when the magnetic rods are in its passive position.

The longitudinal direction of the holding device can also coincide with the direction of flow of the fluid stream.

The racks may comprise a lifting actuator arranged to displace the racks in a direction away from the fluid flow, and the lifting actuator may be arranged to be able to move the racks in the longitudinal direction of the magnet rods. The stands can further comprise a rotary actuator designed to turn the stands in a direction towards the holding device.

The racks may be provided with a non-magnetic sheath arranged around the magnetic rods, and the sheath may comprise a tube of a non-magnetic material.

The at least one first stand and at least one second stand can be provided with at least one first and one second scraper designed to be able to remove magnetic material from the at least one first magnetic rod and the at least one second magnetic rod.

The at least one first scraper and the at least one second scraper can be constituted by a ring arranged to enclose the at least one first magnetic rod and the at least one second magnetic rod.

The fluid flow can be a continuous fluid flow.

The fluid flow can be a flow of a drilling fluid.

The magnetic bars can be made up of permanent magnets. The magnetic rods can also be made of electromagnets.

In a second aspect, the invention relates to a method for removing magnetic material from a fluid flow using a device comprising at least one first magnetic rod and at least one second magnetic rod and where the magnetic rods in their active position are surrounded by the fluid flow and where the magnetic rods in their passive position are not surrounded by the fluid flow, and where the method comprises the steps: - arranging the at least one first magnetic rod in a first rack and the at least one second magnetic rod in a second rack; - displacing the first rack and the second rack so that the magnetic rods assume an active position; - to alternately displace the first rack and the second rack so that the magnetic bars take up an active and a passive position, respectively; and - to bring the magnet rods in their passive position into engagement with a holding device.

The stand can be supplied with a scraper or a non-magnetic cover.

The method may further include displacing the stand in a direction so that magnetic material is scraped off the magnetic rods by means of the scraper.

The method may further include displacing the stand in a direction so that a non-magnetic sheath is displaced in the longitudinal direction of the magnetic rods, and so that the magnetic material is released from the non-magnetic sheath.

The method can further comprise allowing the magnetic rods to be made up of electromagnets, and where the electromagnets are deactivated when the magnetic rods are in their passive position.

According to the method, the fluid flow can be a drilling fluid flow.

In what follows, an example of a preferred method and embodiment is described which is illustrated in the accompanying drawings, where: Fig. 1 shows a magnetic rod cleaner according to the invention with a return flow for drilling fluid; Fig. 2 shows the magnetic rod cleaner after a set of magnetic rods has been placed in it

cleaning position;

Fig. 3 shows the magnetic rod cleaner during cleaning of a set of magnetic rods; and

Fig. 4A-B shows a section of a magnetic rod during cleaning of the magnetic rod in a larger one

yardstick.

In the description of the drawings, mention of certain details has been omitted. These details are not essential to emphasize the novelty of the invention. These details may be important for the production of the device, but the mention of these has been omitted to make the description simpler and the invention clearer.

Similar or equivalent elements will be indicated with the same reference number in the figures.

Position indications such as "above", "below", "above", "below", "right-right" and "left" refer to the location shown in the figures.

In the drawings, the reference number 1 denotes a magnetic rod cleaner which is placed at a return pipe 2 for drilling fluid.

The magnetic rod cleaner 1 comprises a first stand 4 which is provided with four displaceable magnetic rods 8. A non-magnetic cover 81 is attached to the stand 4 which encloses the magnetic rods 8. The magnetic rods 8 are provided with brackets 40 in their end parts.

The first stand 4 is fixedly connected to a first guide sleeve 10 which is displaceably arranged about a first pivot column 12. A first lifting actuator 14 is connected between a first pivot bracket 16 at the lower part of the first pivot column 12 and the first guide sleeve 10. The first the lifting actuator 14 is designed to be able to displace the first rack 4 in the vertical direction.

The first pivot bracket 16 is rotatably mounted against the magnetic rod cleaner's 1 foundation 18 and can be pivoted by means of a first pivot actuator 20 about the first pivot column 12. The pivot function is transferred to the first guide sleeve 10 by means of a first guide strip 22.

Correspondingly, a second stand 24 with associated magnetic rods 8 is arranged at a distance from the first magnetic stand 4 at the return run 2. The second stand 24 is attached to a second guide sleeve 26 which is displaceable and rotatable about a second pivot 28.

The second stand 24 is displaced in the vertical direction by means of a second lifting actuator 30 and rotated by means of a second turning actuator 32.

A holding device 34 is attached to the first pivot column 12 and to the second pivot column 28 at their upper end portions. The holding device 34 is provided with a groove 36 which complementarily fits the magnetic rods 8 when these are in the cleaning position.

A funnel 38 is arranged at a height level below the holding device 34.

Figure 1 shows all the magnetic rods 8 in their active position in the return run 2 where they attract and hold magnetic material that follows the return flow of drilling fluid.

At suitable intervals, magnetic material that has built up around each individual magnet rod 8 must be removed. In figure 2, the first rack 4 is lifted up from the return barrel 2 and turned under the holding device 34. The magnetic rods 8 in the first rack 4 are thereby located in the grooves 36.

Figure 3 shows the first stand 4 being displaced downwards, whereby the magnetic rods' brackets 40 have come into contact with the holding device 36. The non-magnetic sheaths 81 on the first stand 4 are displaced downwards along their respective magnetic rods 8 whereby magnetic material (not shown) loses its attraction to the magnetic rods 8 and falls down from these. The magnetic material is guided by means of the funnel 38 to a container not shown.

When the cleaning has been carried out, the first rack 4 is shifted upwards and lifts the brackets 40 up from the holding device 34, after which the first rack 4 is moved to its active position where its magnetic rods 8 are again located in the return barrel 2.

Correspondingly, the magnetic rods 8 which are located in the second stand 24 are also cleaned by being suspended in the holding device 34.

Figure 4A shows a magnetic rod 8 which is enclosed by a non-magnetic sheath 81. The non-magnetic sheath 81 is attached to the stand 24. In its upper end part, the magnetic rod 8 is provided with a bracket 40. Outside the magnetic sheath 81 is

magnetic material 5 which has been collected from the flow of drilling fluid.

In Figure 4B, the magnetic rod 8 is shown as the stand 24 with the non-magnetic sheath 81 has been displaced in the longitudinal direction of the magnetic rod 8. The bracket 40 which is attached to the magnetic rod 8 is in engagement with a holding device 34. The holding device 34 locks the magnetic rod 8 in a position so that the sheath 81 can be pulled off the magnetic rod

8. As the non-magnetic sheath 81 is displaced sufficiently in the magnetic rod's 8

longitudinal direction, the magnetic material 5 will lose contact with the magnetic field of the magnetic rod 8 and thereby fall off. In the figure, the separated magnetic material 5 is shown placed on a surface 7. The surface can, for example, be covered by the funnel 38.

However, it should be understood from the invention that other devices can be used to remove the magnetic material 5 from the magnetic rod 8. Such devices can include

scrapers (not shown) attached to the stand 4. A scraper can for example consist of a ring attached to the stand 4, where the ring surrounds the magnet rod 8 and where the ring has an inner diameter corresponding to the magnet rod 8's outer diameter. The magnetic rod 8 can also consist of an electromagnet (not shown), where removal of the magnetic material 5 is achieved by deactivating the electromagnet.

Claims (20)

1. Device (1) for removing magnetic material (5) from a fluid flow, where the device (1) comprises at least one first and at least one second magnetic rod (8) and where the magnetic rods (8) are in an active position surrounded by the fluid flow, and where the magnetic rods (8) in a passive position are not surrounded by the fluid flow, characterized in that the device further comprises at least a first stand (4), a second stand (24) and a holding device (34), and where the first stand (4) comprises the at least one first magnetic rod (8), and where the second stand (24) comprises the at least one second magnetic rod (8), and where the first stand (4) and the second stand (24) are arranged to respectively displace the at least one first magnetic rod (8) and the at least one second magnetic rod (8) between the active position and the passive position and where the holding device (34) is arranged to engage with the magnetic rods (8) when the magnetic rods (8) is in its passive position. 2. Device (1) according to claim 1, where the racks (4, 24) comprise a lifting actuator (14, 30) arranged to displace the racks (4, 24) in a direction away from the fluid flow. 3. Device (1) according to claim 2, where the lifting actuator (14, 30) is designed to be able to move the racks (4, 24) in the longitudinal direction of the magnetic rods (8). 4. Device (1) according to claim 1, where the longitudinal direction of the holding device (34) essentially coincides with the flow direction of the fluid flow. 5. Device (1) according to claim 1, where the stands (4, 24) comprise a rotary actuator (20, 32) arranged to turn the stands (4, 24) in a direction towards the holding device (34). 6. Device (1) according to claim 1, where the stands (4, 24) are provided with a non-magnetic cover (81) arranged to be able to enclose at least a part of the magnetic rods (8). 7. Device (1) according to claim 6, wherein the non-magnetic jacket (81) comprises a tube (81) of a non-magnetic material. 8. Use of device (1) according to claim 1, where the fluid flow is a continuous fluid flow. 9. Application of device (1) according to claim 1, where the fluid flow is a flow of a drilling fluid. 10. Device (1) according to claim 1, where at least the first and the second stand (4, 24) are provided with at least a first and a second scraper designed to be able to remove magnetic material (5) from at least the first and second magnetic rod (8). 11. Device (1) according to claim 10, where at least the first and second scraper consists of a ring designed to enclose it in at least one first and at least one second magnetic rod (8). 12. Device (1) according to claim 1, where the magnetic rods (8) consist of permanent magnets. 13. Device (1) according to claim 1, where the magnetic rods (8) consist of electromagnets. 14. Method for removing magnetic material (5) from a fluid flow using a device (1) comprising at least one first magnetic rod (8) and at least one second magnetic rod (8) and where the magnetic rods are enclosed in their active position of the fluid flow and where the magnetic rods in their passive position are not surrounded by the fluid flow, characterized in that the method includes the steps: - arranging the at least one first magnetic rod (8) in a first rack (4) and the at least one second magnetic rod in a second rack ( 24); - displacing the first rack (4) and the second rack (24) so that the magnetic rods (8) take an active position; - to alternately displace the first stand (4) and the second stand (24) so that the magnetic rods (8) occupy respectively an active and a passive position; and - to bring the magnetic rods (8) in their passive position into engagement with a holding device (34). 15. Method according to claim 14, wherein the method further comprises providing the stand (4, 24) with a scraper or a non-magnetic sheath (81). 16. Method according to claims 14 and 15, where the method further comprises displacing the stand (4, 24) in a direction so that magnetic material (5) is scraped off the magnetic rods (8) by means of the scraper. 17. Method according to claims 14 and 15, wherein the method further comprises displacing the stand (4, 24) in a direction so that a non-magnetic sheath (81) is displaced in the longitudinal direction of the magnetic rods (8), and so that the magnetic material (5) is released from the non-magnetic sheath (81). 18. Method according to claim 14, wherein the method further comprises allowing the magnetic rods (8) to be constituted by electromagnets. 19. Method according to claim 18, wherein the method further comprises deactivating the electromagnets when the magnet rods (8) are in their passive position. 20. Use of the method according to any one of claims 14-19, where the fluid flow is a drilling fluid flow.