Patent Description:
Different types of downhole plugs are known. Their purpose is typically to seal off a downhole bore (for example a casing or a production tubing) during a well operation. Some downhole plugs are retrievable, i.e. after a period of time, a retrieving tool are used to retrieve the plug to topside again. Other downhole plugs are permanent plugs.

One group of plugs are often referred to as high expansion plugs. Here, the expansion rate, defined as the ratio between the outer diameter in the set state and the outer diameter in the run state, is relatively higher than for other groups of plugs. These plugs are designed to pass a relatively narrow restriction in the well and then expand to seal off the well bore below the narrow restriction.

One such plug is shown in <CIT>. Here, the sealing device comprises a sealing element and supporting devices on its upper and lower sides. Each supporting device comprises a number of first supporting arms and a number of second supporting arms having their first ends pivotably connected to a supporting ring provided around the mandrel and where their second ends are pivotably connected to each other. This principle is used in the commercially available High Expansion Retrievable Bridge plug (HEX plug), sold and marketed by Interwell.

One of the HEX plugs is made for use in a <NUM>" <NUM> pounds/feet well pipe, where the specification for such pipes allows the inner diameter of the pipe to vary in a range between ca <NUM> - <NUM>, i.e. a variation in the distance between the outside of the supporting arms of the plug in its set state to the inner surface of the well pipe up to <NUM>.

A further development of the above HEX plug is described in <CIT>. This principle is used in the commercially available High Temperature High Expansion bridge plug (THEX). The THEX plug handles the above variations in the inner diameter of the well pipe.

One of the variants of the THEX plug has an outer diameter Drun in the run state of <NUM> and a maximum outer diameter Dsetmax in the set state of <NUM>. Hence, the expansion ration is here <NUM>/<NUM> = <NUM>.

One object of the invention is to provide a tool which is insertable through a relatively narrow restriction in a well and which is radially expandable in a relatively wider section of the well below the narrow restriction.

In plugging and abandonment (P&A) operations, permanent plugs are initially set in the well. Then, molten bismuth may be supplied above the permanent plug. Bismuth has expanding properties, i.e. the volume of the metal is larger when solidified than when molten. Hence, solidified bismuth serves as an additional barrier above the permanent plug. Typically, a relatively large amount of bismuth is required, which in turn require a relatively large heater in the well to melt the bismuth at the desired location in the well. According to the report "European Commission, Study on the EU's list of Critical Raw Materials - Final Report (<NUM>)", bismuth is considered to be a critical raw material. Hence, one purpose of the present invention is to be able to reduce the amount of bismuth when providing a bismuth-type of barrier in a well.

<CIT> describes downhole method comprises expanding a patch member. The patch member may be employed in a method of sealing a wall of a bore. The sealing method may comprise: providing the patch member with a sealing material on an exterior surface; running the patch member into the bore in a smaller diameter first configuration; heating the sealing material to render the sealing material flowable; reconfiguring the patch member to a larger diameter second configuration; and hardening the sealing material to provide a seal between the exterior surface of the patch member and an inner surface of the bore.

<CIT>describes a method and apparatus includes providing an element formed of a superplastic material to perform a predetermined downhole task. In another arrangement, a method and apparatus includes a flowable element and a deformable element that can be expanded by flowing the flowable element.

<CIT> describes an apparatus, casing and method is disclosed for heating a material used for sealing faults within the cement used for sealing an oil or gas well. The apparatus comprises a heating tool, a hollow core within the tool for carrying meltable material and for allowing the material to liquefy upon heating by the heating tool, a piston within the heating tool for applying pressure to the material following the liquefying of the material within the tool and for forcing the liquefied material from the tool through perforations and into adjacent well cement <NUM> and formation. When the material cools and solidifies any faults in the cement/formation become sealed. The casing may have a meltable material of a predetermined thickness over a predetermined length of the casing.

<CIT> describes a method of sealing a region of a sand screen of an Open Hole Gravel Pack without the need to perforate the sand screen and a tool for use in such. The tool being a eutectic/ bismuth based alloy well plugging/sealing tool having a tubular heater body with an internal cavity capable of receiving a chemical heat source. The tool is provided with a quantity of eutectic/bismuth based alloy around an outer surface of the heater body such that it can be heated by the chemical heat source. In addition the tool has an insulating sleeve provided around an outer surface of the alloy, wherein the sleeve is configured to provide a focused egress for the alloy as it is melted by the chemical heat source.

<CIT> describes a method, system and plug for providing a cross-sectional seal in a well comprising a pipe body and an annulus, the method comprising: lowering a pipe expansion device into the pipe body to a selected location; with the pipe expansion device, expanding a section of the pipe body until contact with a wellbore wall, thus forming an expanded pipe section closing the annulus; lowering a fusible solid material into the expanded pipe section; lowering a heating tool into the expanded pipe section; activating the heating tool and melting the fusible solid material and allowing a molten mass thereof to fill a cross-sectional portion of the expanded pipe section; and deactivating the heating tool and allowing the molten mass to solidify and form the cross-sectional seal.

<CIT> describes a downhole tool deployment assembly for use in particular in oil/gas wells. The assembly comprises a heater with a tubular heater body having an internal cavity configured to receive a heat source. The assembly also has a tubular heat conducting member configured to surround the tubular heater body leaving an annular clearance, wherein the tubular heat conducting member does not extend along the entire length of the tubular heater body. In addition, a collar is mounted adjacent to the region of the assembly where the tubular heat conducting member ends. The collar is configured to prevent access to the annular clearance between the tubular heat conducting member and the tubular heater body. A eutectic/bismuth based alloy covers the collar and at least a portion of the tubular heater body and the tubular heat conducting member such that the alloy holds the heater and the tubular heat conducting member together until the alloy is melted.

Another object of the present invention is to provide an alternative P&A barrier in the well.

The present invention relates to a downhole well tool for permanently sealing a downhole well, wherein the downhole well tool comprises:.

characterized in that the downhole well tool comprises:.

wherein the well tool is configured to be in the following states:.

In one aspect, the downhole well tool is a millable permanent downhole well tool, which is easy to remove by a milling operation, as no parts of the well tool can be rotated relative to other parts of the well tool. In one aspect, the millable permanent downhole well tool is a millable permanent plug.

In one aspect, the downhole well tool is a high expansion well tool which typically is lowered in the run state through a restriction in the well, and thereafter expanded to its set state. If the restriction is not removed, a so-called under-reamer may be used to remove the set downhole well tool.

In one aspect, the expandable sealing element comprises an elastomeric material reinforced with a fiber element structure.

The fiber element structure may comprise several fibers. The fibers may be connected to each other. The fibers may be held relative to other fibers by means of the elastomeric material of the sealing element. In one aspect, the material of the elastomeric material and the fibre element structure is heat resistant with respect to the heat from the molten metal. The fibers may be aramid fibers, carbon fibers etc..

In one aspect, the fiber element structure is determining the shape of the expandable sealing element in the intermediate state.

In one aspect, the fiber element structure is flexible. In one aspect, the expandable sealing element with its fiber element structure is folded outside of the housing in the run state.

In one aspect, the fibre element structure is applied with a sealing agent. In one aspect, the sealing agent is a polymer.

In one aspect, the expandable sealing element comprises a cylindrical contact surface in the intermediate and set states.

The cylindrical contact surface is brought into sealing contact with the inner surface of the well. Hence, the cylindrical contact surface is preventing longitudinal fluid flow in the annulus between the outside of the housing and the inside of the well.

In one aspect, the cylindrical contact surface is further preventing longitudinal movement between the well tool and the well.

In one aspect, the outer diameter of the cylindrical contact surface of the expandable sealing element in a free set state is <NUM> - <NUM>% larger than the average inner diameter of the well.

The term "free set state" is referring to a state in which the well tool is not restricted, for example by the well, when set.

In one aspect, the well tool comprises a centralizer connected to the housing.

The centralizer is radially expanded into contact with the well at the desired location before or in the intermediate state, to orient the expandable sealing element with respect to the well. The centralizer may also reduce the pressure needed for expanding the sealing element in the intermediate state.

In one aspect, the centralizer comprises slips for anchoring of the well tool to the well. Hence, the centralizer is preventing longitudinal movement between the well tool and the well.

In one aspect, the heater is an electric heater.

Alternatively, the heater may be a chemical heater, for example a heater heated by means of a exothermic oxidation-reduction reaction, for example a thermite reaction.

In one aspect, the heater is provided adjacent to or within the first compartment.

In one aspect, the metal body comprises a metal or metal alloy whose volume is larger when solidified than when molten.

In one aspect, the metal body comprises a metal having or metal alloy having a melting temperature lower than the melting temperature of the housing metal.

In one aspect, the metal body comprises a bismuth or a bismuth alloy. A relatively small amount of bismuth-metal may be used.

In one aspect, the upper housing section is releasably connected to the lower housing section by a releasable securing element.

In one aspect, the securing element is a meltable securing element meltable by an auxiliary heater.

In one aspect, the securing element is a shear element, such as a shear pin.

Hence, the lower housing section and the expandable sealing element filled with solidified metal may in the set state be considered as a downhole permanent plug, while the upper housing section may be considered as a setting tool for the downhole permanent plug. The setting tool or at least parts of the setting tool may be reused.

In one aspect, the downhole well tool comprises a piston slidingly and sealingly engaged within the first compartment for displacing the molten metal from the first compartment to the second compartment in the intermediate state.

Alternatively, the molten metal will flow from the first compartment to the second compartment due to gravity.

In one aspect, the piston separates the first compartment into a first sub-compartment in which the metal body is provided and a second sub-compartment in which a pressurized gas is provided.

Hence, when the metal body is melted, the pressurized gas will move the piston, thereby causing the molten metal to flow into the second compartment via the fluid line.

In one aspect, the expandable sealing element comprises a first end sleeve and a second end sleeve, wherein the cylindrical contact surface is located longitudinally between the first end sleeve and a second end sleeve.

In one aspect, the expandable sealing element comprises a first intermediate section between the first end sleeve and cylindrical contact surface, wherein the first intermediate section is cone-shaped in the intermediate and set states.

In one aspect, the expandable sealing element comprises a second intermediate section between the second end sleeve and cylindrical contact surface, wherein the second intermediate section is cone-shaped in the intermediate and set states.

In one aspect, the setting system comprises:.

wherein the releasable securing element is released in the intermediate state.

According to the above, the spring will displace the second sleeve holder relative to the lower housing section towards the first sleeve holder, thereby causing or at least contributing to radial expansion of the expandable sealing element into contact with the well. This will make it easier for the molten metal to flow into the sealing element, either by gravity or by means of the piston.

In one aspect, a distance between the first end sleeve and the second end sleeve is longer in the run state than in the set state.

In one aspect, the releasable securing element is a meltable securing element, and wherein the setting system comprises an auxiliary heater for melting the meltable locking element.

In one aspect, the housing comprises a spring support for supporting the spring.

In one aspect the spring is biased between the spring support and the second sleeve holder. In one aspect, the spring support is forming a lower end of the housing.

In one aspect, the upper housing section and/or lower housing section comprises a wire channel for guiding an electric wire to the auxiliary heater and/or the heater.

In one aspect, the setting system comprises a battery unit provided in the upper housing section for supplying electric power to the auxiliary heater and/or the heater.

Alternatively, electric power may be transferred from topside via an e-line or other electric power supply line.

According to the above, it is achieved a tool which is in insertable through a relatively narrow restriction in a well and which is radially expandable in a relatively wider section of the well below the narrow restriction.

The term "upper", "above", "lower", "below" etc. are used herein as terms relative to the well. Parts referred to as "upper" or "above" are relatively closer to the top of the well than the parts referred to as "lower" or "below", which are relatively closer to the bottom of the well, irrespective of the well being a horizontal well, a vertical well or an inclining well.

The present invention also relates to a method for setting a downhole well tool as described above in a downhole well, wherein the method comprises the steps of:.

wherein the method comprises the steps of:.

In one aspect, wherein the downhole well tool comprises a piston slidingly and sealingly engaged within the first compartment for displacing the molten metal from the first compartment to the second compartment in the intermediate state and the the piston separates the first compartment into a first sub-compartment in which the metal body is provided and a second sub-compartment in which a pressurized gas is provided, the step of supplying molten metal is comprising the steps of:.

In one aspect, wherein the expandable sealing element comprises a first end sleeve and a second end sleeve, and wherein the cylindrical contact surface is located longitudinally between the first end sleeve and a second end sleeve, the step of expanding the expandable sealing element further comprises the step of:.

Irrespective of the above, the invention is set out in independent down hole well tool claim <NUM> and independent method claim <NUM>. Optional and additional features are furthermore set out in the respective independent claims.

Embodiments of the invention will be described in detail below with reference to the enclosed drawings, wherein:.

In <FIG>, a downhole well tool <NUM> is shown to comprise a housing <NUM> having an upper housing section 11a and an upper housing section 11b. The tool <NUM> comprises a expandable sealing element <NUM> provided circumferentially outside of the lower housing section 11b. In <FIG>, the expandable sealing element <NUM> is radially retracted, and the tool <NUM> is in its radially retracted state or run state.

In <FIG>, the expandable sealing element <NUM> is radially expanded, and the tool <NUM> is in its radially expanded state or set state.

In <FIG>, the lower housing section 11b has been separated from the upper housing section 11a and the upper housing section 11a has been moved away.

According to the above, the downhole well tool <NUM> may be considered to comprise two main parts: a first part in the form of a downhole permanent plug <NUM> for permanently sealing a downhole well WE (the well WE is indicated in <FIG>), and a second part in the form of a setting tool <NUM> which is retrieved topside after the setting operation of the downhole permanent plug <NUM>. The setting tool <NUM> may then be used again to set another downhole permanent plug <NUM>.

It is now referred to <FIG>. Here, the details of the housing <NUM> are shown more in detail, with its upper housing section 11a and its lower housing section 11b. It is here also shown better how the expandable sealing element <NUM> are provided circumferentially outside of the lower housing section 11b.

In the upper end of the housing <NUM>, a wireline interface <NUM> is shown. A longitudinal direction of the housing is indicated as a dashed line I-I in <FIG>.

The tool <NUM> is defined with a first compartment <NUM> provided within housing <NUM> and a second compartment <NUM> radially inside of the expandable sealing element <NUM> and radially outside of the lower housing section 11b. It is further shown that the tool <NUM> comprises a fluid line <NUM> providing fluid communication between the first compartment <NUM> and the second compartment <NUM>. The fluid line <NUM> is at least partially integrated within the housing <NUM>.

A piston <NUM> is slidingly and sealingly engaged within the first compartment <NUM>. The piston <NUM> separates the first compartment <NUM> into a first sub-compartment 12a and a second sub-compartment 12b, wherein the second sub-compartment 12b is located below the first sub-compartment 12a. The second sub-compartment 12b is in fluid communication with the second compartment <NUM> via the fluid line <NUM>.

The upper housing section 11a is releasably connected to the lower housing section 11b by means of two releasable securing elements, a first, meltable securing element <NUM> and a shear element <NUM>. These elements will be described further in detail below.

The housing <NUM> further comprises a wire channel <NUM> for guiding one or more electric wires inside the housing <NUM>.

The lower end of the housing <NUM> further comprises a spring support 11c, which will also be described further in detail below.

The shape of the expandable sealing element <NUM> will now be described when it is in its set state as shown in <FIG>. The expandable sealing element <NUM> comprises an elastomeric material reinforced with a fiber element structure <NUM> (<FIG>). The purpose of the fiber element structure <NUM> is to reinforce the elastomeric material. In addition, the purpose of the fiber element structure <NUM> is to contribute to maintain the desired shape of the expandable sealing element <NUM> in the expanded state.

The expandable sealing element <NUM> is made of a heat resistant material, as will be apparent from the description below.

In <FIG>, it is shown that the expandable sealing element <NUM> comprises a first or upper end sleeve <NUM>, a second or lower end sleeve <NUM>, and a cylindrical contact surface <NUM> longitudinally between the first end sleeve <NUM> and a second end sleeve <NUM>. The expandable sealing element <NUM> further comprises a cone-shaped first intermediate section 24a between the first end sleeve <NUM> and cylindrical contact surface <NUM> and a cone-shaped second intermediate section 25a between the second end sleeve <NUM> and cylindrical contact surface <NUM>.

In <FIG> (run state), the expandable sealing element <NUM> may seem to be shaped like an elongated cylinder. However, this is not the case in the present embodiment. In <FIG>, the cross section along line A-A in <FIG> is shown. The cylindrical contact surface <NUM> of the sealing element <NUM> has here been radially retracted by folding the cylindrical contact surface <NUM> outside of the lower housing section 11b.

Preferably, the fiber element structure <NUM> and the elastomeric material of the sealing element <NUM> is molded in the expanded state shown in <FIG>. As part of the molding process, a sealing agent such as a water resistant polymer (silicon etc.) may be applied to the fiber element structure <NUM>.

The tool <NUM> further comprises a metal body <NUM> provided in the second sub-compartment 12b.

The metal may be a bismuth metal or a bismuth alloy. Bismuth is a metal whose volume is larger when solidified than when molten. In other words, the density of the metal in liquid form is larger than the density of the metal in solid form. In addition, it should be noted that bismuth has a relatively low melting temperature, the melting temperature is approximately <NUM>. The melting temperature of the metal body is therefore considerably lower than the melting temperature of the housing metal. The housing metal of the present invention is made of cast iron (melting point approximately <NUM>), cast steel (melting point approximately <NUM> - <NUM>), i.e. relatively cheaper metals compared with high grade steel metals used in the abovementioned prior art. It should be noted that also high grade steel metals may be used for the housing. In some applications, high temperature composite materials may be used for the housing.

Alternatively, the metal is another metal or metal alloy whose volume is larger when solidified than when molten and with a melting temperature of the metal body lower than the melting temperature of the mandrel metal. Other such metals are germanium (melting point <NUM>), gallium (melting point <NUM>) or alloys thereof.

One example of a bismuth alloy is the so-called lead-bismuth eutectic alloy comprising <NUM>% lead and <NUM> % bismuth, having a melting point of <NUM>. Other lead/bismuth alloys are also suitable.

Another example of bismuth alloys is tin/bismuth alloys or cupper/bismuth alloys, which will increase the melting temperature to a temperature above the melting temperature of bismuth alone. Such alloys may be preferred for example in high pressure and/or high temperature wells.

It should be noted that suitable alloys may comprise more than two metals.

The above metal body <NUM> may be a solid body inserted into the second sub-compartment 12b. Alternatively, the metal body <NUM> may poured into the second sub-compartment 12b in molten form, and subsequently allowed to solidify.

The tool <NUM> further comprises a setting system <NUM> used to set the tool <NUM> at the desired location in the well WE.

The setting system <NUM> comprises a first sleeve holder 52a for holding the first end sleeve <NUM> of the expandable sealing element <NUM> outside of the lower housing section 11b and a second sleeve holder 52b for holding the second end sleeve <NUM> of the expandable sealing element <NUM> outside of the lower housing section 11b. The first sleeve holder 52a is secured to the lower housing section 11b and can be considered to be a part of the lower housing section 11b. The second sleeve holder 52b is longitudinally displaceable relative to the lower housing section 11b. In <FIG>, it is further shown that the setting system <NUM> comprises a releasable securing element <NUM> for preventing such longitudinal displacement of the second sleeve holder 52b relative to the lower housing section 11b.

The setting system <NUM> further comprises a spring <NUM> biased to longitudinally displace the second sleeve holder 52b relative to the lower housing section 11b towards the first sleeve holder 52a. The spring <NUM> is biased between the above-mentioned spring support 11c and the second sleeve holder 52b.

In the present embodiment, the releasable securing element <NUM> is a meltable securing element. The setting system <NUM> comprises an auxiliary heater <NUM> for melting the meltable locking element <NUM>.

In <FIG>, it is shown that the setting system <NUM> comprising a main heater <NUM> which purpose is to melt the metal body <NUM>. The main heater <NUM> may be located adjacent to the second sub-compartment 12b as indicated in <FIG>, or may be located within the second sub-compartment 12b.

The setting system <NUM> further comprises an auxiliary heater <NUM> located adjacent to the meltable securing element <NUM>.

The setting system <NUM> further comprises a control circuit 56a and a battery unit 56b provided in the upper housing section 11a for controlling and supplying electric energy to the main heater <NUM>, the auxiliary heater <NUM> and the auxiliary heater <NUM> via electric wires provided within the wire channel <NUM>.

The run state, in which the tool <NUM> is run or lowered into the well WE, is shown in <FIG> and <FIG>. The tool <NUM> is also in this run state when transported from a manufacturing location to the well location and when handled topside. It should be noted that a compression band may be provided outside of the expandable sealing element <NUM> during transport and handling, to keep the sealing element <NUM> as shown in <FIG> and for protecting the sealing element <NUM> from damages.

As shown in <FIG>, there is a height H13 (in the longitudinal direction) between the lower side of the piston <NUM> and the lower end of the compartment <NUM>, there is a height H20 (in the longitudinal direction) of the expandable sealing element <NUM> and there is a height H53 (in the longitudinal direction) of the spring.

The first sub-compartment 12a is filled with a pressurized gas. This pressurized gas will not move the piston <NUM>, due to the metal body <NUM> in the second sub-compartment 12b.

Then, in an intermediate state, the main heater <NUM> is supplied with electric energy and the metal body will start to melt. The auxiliary heater <NUM> is also supplied with electric energy, causing the meltable securing element <NUM> to melt and thereby releasing the second sleeve holder 52b. The spring <NUM> will now displace the second sleeve holder 52b relative to the lower housing section 11b towards the first sleeve holder 52a, thereby causing or at least contributing to radial expansion of the expandable sealing element <NUM>. Preferably, the fiber element structure <NUM> will contribute to this radial expansion of the expandable sealing element <NUM>, as the fiber element structure <NUM> will try to obtain its original shape (<FIG>).

When the metal body has been melted by the heater <NUM> the piston <NUM> will be allowed to move and the gas pressure in the first sub-compartment 12a will push the piston <NUM> down, causing the molten metal to be displaced from the second sub-compartment 12b into the second compartment <NUM>, i.e. the expandable sealing element <NUM> will be filled with molten metal. The flow path for the molten metal from the second sub-compartment 12b via the fluid line <NUM> into the compartment <NUM> is indicated by a dashed arrow both in <FIG> and <FIG>. If the expandable sealing element <NUM> has not been fully expanded by the movement of the sleeve holder 52b and the properties of the fiber reinforcement structure <NUM>, the expandable sealing element <NUM> will become expanded as it becomes filled with molten metal. The expandable sealing element <NUM> will expand until it comes into contact with the inner surface of the well WE. It should be noted that the expandable sealing element <NUM> will not be damaged by the molten metal due to its heat resistant properties.

It should be noted that the housing <NUM> (and hence the compartment <NUM>) is longer than indicated in the drawings, as indicated by the break line C in <FIG> and <FIG>. Hence, the volume of the metal body <NUM> in <FIG> may appear to be smaller than the volume of the compartment <NUM> in <FIG>. It should be noted that the metal body <NUM> should have a volume sufficiently large to fill the entire compartment <NUM>'.

As shown in <FIG>, the height H20 is shorter in fig. the intermediate state than in the run state, the height H13 is shorter in the intermediate state than in the run state and the height H53 is longer in the intermediate state than in the run state.

It is now referred to <FIG> and <FIG>. Here, the molten metal has from the metal body <NUM> has been solidified within the second compartment <NUM>, as indicated by wavy lines. It should be noted that also the flow line <NUM> and parts of the second sub-compartment 12b will contain solidified metal. This is referred to as the set state.

Due to the expanding properties of the metal or metal alloy during solidification, the solidified metal will also exert a force from the outer surface of the solidified metal to the inner surface of the well, thereby forming an anchoring of the tool relative to the well.

The cylindrical contact surface <NUM> is brought into sealing contact with the inner surface of the well WE. Hence, the cylindrical contact surface <NUM> will prevent longitudinal fluid flow in the annulus between the outside of the housing <NUM> and the inside of the well WE. It is also shown that this cylindrical contact surface <NUM> has an extension in the longitudinal direction, as indicated by a height H22. Hence, the cylindrical contact surface <NUM> forms an area where friction between the cylindrical contact surface <NUM> and the well WE will prevent longitudinal movement of the tool <NUM> relative to the well WE.

It should be noted that the outer diameter OD of the expandable sealing element <NUM> in the set state (indicated in <FIG>) is considerably larger than the outer diameter OD of the of the expandable sealing element <NUM> in the run state (indicated in <FIG>). In the present embodiment, the outer diameter OD in the set state is approximately <NUM> times the outer diameter in the run state. As a comparison, the prior art HEX bridge plug has a corresponding OD in the set state is approximately <NUM> - <NUM> times the OD in the run state.

It should further be noted that the outer diameter OD of the cylindrical contact surface <NUM> of the expandable sealing element <NUM> in a free set state is <NUM> - <NUM>% larger than the average inner diameter ID of the well WE, to ensure that the expandable sealing element <NUM> is allowed to expand properly into contact with the well and to ensure that the solidified metal is allowed to exert a force from the outer surface of the solidified metal to the inner surface of the well.

It is further shown in <FIG> and <FIG> that the upper housing section 11a has been released from the lower housing section 11b by pulling the upper housing section 11a upwardly, causing the shear element <NUM> to be sheared off.

An alternative way is to supply electric energy to the auxiliary heater <NUM>, causing the releasable securing element <NUM> to melt.

In both of the above occasions, the control circuit 56a and the battery unit 56b will be retrieved to surface together with the upper housing section 11a.

In the embodiment above, the upper housing section 11a and other parts of the well tool <NUM> is retrieved topside after setting of the lower housing section 11b and the expandable sealing element <NUM>. However, it should be noted that the downhole well tool <NUM> may be a non-separatable tool, where the entire tool <NUM> will be left in the well WE.

It is now referred to <FIG>. Here it is shown a centralizer <NUM> which may be connected to the housing <NUM>. The centralizer <NUM> may have centralizing properties only, in which the purpose is to centralize the housing <NUM> relative to the well WE. Here, the centralizer may be connected to the upper housing section 11a or to the lower housing section 11b.

The centralizer <NUM> may have anchoring properties in addition to the centralizing properties, by equipping the centralizer with teeth <NUM> engaging the well WE in the intermediate and set states. Also here, the centralizer may be connected to the upper housing section 11a or to the lower housing section 11b. However, in high pressure wells, the centralizer is preferably connected to the lower housing section 11b.

It should be noted that the piston <NUM> is not necessarily an essential feature, as the molten metal may flow from the first compartment <NUM> to the second compartment <NUM> by means of gravity.

It should further be noted that electric power may be transferred from topside via an e-line or other electric power supply line. Hence, the control circuit 56a and the battery unit 56b may be located topside and is not a part of the tool <NUM>.

It should also be noted that a chemical heater may be used instead of, or in addition to, an electric heater.

It is now referred to <FIG>. Here it is shown that the well tool <NUM> comprises three sealing elements <NUM>, each sealing element <NUM> being filled with molten metal during the setting process and thereafter having allowed the molten metal to solidify.

Claim 1:
Downhole well tool (<NUM>) for permanently sealing a downhole well (WE), wherein the downhole well tool (<NUM>) comprises:
- a housing (<NUM>) having an upper housing section (11a) and a lower housing section (11b);
- a first compartment (<NUM>) provided within the housing (<NUM>);
characterized in that the downhole well tool (<NUM>) comprises:
- an expandable sealing element (<NUM>) provided circumferentially outside the lower housing section (11b), thereby forming a second compartment (<NUM>) radially inside of the expandable sealing element (<NUM>) and radially outside of the lower housing section (11b);
- a metal body (<NUM>) provided within the first compartment (<NUM>);
- a setting system (<NUM>) comprising a heater (<NUM>) for melting the metal body (<NUM>);
- a fluid line (<NUM>) providing fluid communication between the first compartment (<NUM>) and the second compartment (<NUM>);
wherein the well tool (<NUM>) is configured to be in the following states:
- a run state, in which the expandable sealing element (<NUM>) is radially retracted;
- an intermediate state, in which the metal body (<NUM>) has been melted by the heater (<NUM>) and is flowing from the first compartment (<NUM>) to the second compartment (<NUM>); thereby expanding the expandable sealing element (<NUM>) radially into contact with the well (WE);
- a set state, in which the melted metal from the metal body (<NUM>) has been solidified within the second compartment (<NUM>).