WO2016091584A1 - Heating device for the inductive heating of an oil sand deposit and/or an oil shale deposit and/or a bitumen deposit and/or a heavy oil reservoir - Google Patents

Abstract

The invention relates to a heating device (1) for the inductive heating of an oil sand deposit and/or an oil shale deposit and/or a bitumen deposit and/or a heavy oil reservoir, comprising a conductor means (2), which at least sectionally can be introduced into the oil sand deposit and/or the oil shale deposit. The conductor means (2) has an inner conductor (3) and an outer conductor (4) that is arranged coaxially to the inner conductor (3), wherein the inner conductor (3) and the outer conductor (4) are capacitively coupled. The invention further comprises an alternating current generator (6) for providing an alternating current, which is electrically connected to the conductor means (2), wherein in an interspace (5) between the inner conductor (3) and the outer conductor (4), a dielectric fluid is introduced, and the inner conductor (3) and the outer conductor (4) are substantially capacitively coupled via the dielectric fluid.

Description

description

Heating device for inductive heating of an oil sands deposit and / or an oil shale deposit and / or a

Bitumen deposit and / or a heavy oil deposit

The present invention relates to a heating device for inductive heating of an oil sands deposit and / or an oil shale deposit with a conductor device which at least partially in the oil sands deposit and / or the oil shale deposit is introduced, the Leiterein ^¬ direction arranged an inner conductor and a coaxial with the inner conductor External conductor and wherein the inner conductor and the outer conductor are capacitively coupled, and with an AC generator for providing an alternating current, which is electrically connected to the conductor means. The invention also relates to an arrangement for conveying heavy oil and / or bitumen from an oil sands deposit and / or an oil shale deposit and / or a bitumen deposit and / or a heavy oil deposit with ei ^¬ ner such a heater.

In the present case, the interest is directed to the extraction of heavy oils or bitumen from a reservoir of an oil sands deposit and / or oil shale deposit and / or a

Bitumen deposit and / or a heavy oil deposit. A widely used method in this context is the so-called ^¬ SAGD method (SAGD - Steam Assisted Gravity Draina ^¬ ge). In this case, water vapor to which a solvent may be added, under high pressure by a within the

Reservoirs horizontally extending pipe pressed. Here, the heavy oil or bitumen from the oil sands of oil shale or heavy oil deposits ^¬ dissolves. By a corresponding delivery pipe, which is introduced into the reservoir, the heavy oil or bitumen can be removed.

The SAGD method can also use appropriate heating devices with which the reservoir can be placed. can be heated and thus the flowability of the bitumen and / or the oil can be significantly increased. For this purpose, corresponding bores are introduced into the reservoir, in wel ^¬ che turn a trained as a conductor loop conductor device of the heating device is introduced. The conductor device is electrically connected to an alternator, which serves to energize the conductor device. The alternating current-carrying conductor device generates an alternating electromagnetic field in the reservoir, through which eddy currents are generated in the reservoir.

To provide the desired heating power densities of typically 1 to 10 kilowatts per meter length of the waveguide means to Errei ^¬ chen, it is necessary - depending on the conductivity of the reservoir - current strengths of several 100 amps at a frequency of typically 20 to 200 kilohertz memorize. To compensate for the inductive voltage drop along the conductor device usually capacitors are interposed, where ^¬ arises by a series resonant circuit. This Serienreso ^¬ nanzkreis is operated at its resonant frequency and it provides at its terminals is a purely resistive load. Without this series capacitors, the inductive voltage drop ^¬ would sum up along the length of the guide device. Since the circuit means may comprise for example a length of eini ^¬ or hundreds of meters, the inductive voltage drop can add up to some 10 to 100 kilovolts. Such inductive voltage drops include ^¬ be züglich of insulation from the surrounding soil in the reservoir barely manageable. Furthermore, a compensation of the reactive power would have to be done on or in the alternator.

Various methods are known ^¬ be to compensate the inductive voltage drop along the conductor means from the prior art. For example, concentrated capacitances can be used to compensate for the line inductances. Furthermore, conductor devices are known which have capacitively coupled filament groups, which are arranged in the longitudinal direction. Here, the individual filament conductor a ^¬ with an appropriate plastic such as a fluoropolymer or PEEK, isolated from each other. The problem of the capacitively compensated inductors with plastic-based insulating materials or dielectrics is that they can be operated only in a limited operating temperature range. For example, the voltage and Teilentladungsfestig ^¬ speed significantly reduced when temperatures of about 150 ° C are reached or exceeded. While in heavy oil reservoirs, a temperature increase of, for example, below 50 ° C from reaching reaching ^¬ to accelerate the promotion considerably, in bitumen (oil sands) reservoirs are usually higher temperatures, such as temperatures greater than

100 ° C necessary. In hybrid methods, such as a

SAGD methods, which are supported by the inductive heating, must also be expected that steam from the injector reaches the conductor device, so that temperatures above 200 ° C can be present at the conductor device.

Furthermore, conductor devices are known from the prior art, which have an inner conductor and an outer conductor arranged coaxially with the inner conductor. Distributed between the inner conductor and the outer conductor may be a plurality of capacitors to capacitively couple the inner conductor and the outer conductor. Such a guide device is be ^¬ wrote, for example, in DE 10 2007 040 605 B3. However, the use of the capacitors entails an increased workload and an increased use of materials.

It is an object of the present invention to provide a solution as a more reliable and cost Heizvor ^¬ direction for Olsand deposits and / or Ölschieferlagerstät- and / or bitumen deposits and / or heavy oil deposits can be provided. This object is achieved by a heating device and by an arrangement with the features according to the respective independent claims. Advantageous developments of the present invention are the subject of the dependent claims.

A heating device according to the invention serves for the inductive heating of oil sand deposit and / or a Ölschieferla ^¬ gerstätte and / or a bitumen deposit and / or a heavy oil reservoir. The heating device comprises a printed circuit ^¬ device which is a ^¬ can be brought at least partially into the Ölsandla ^¬ gerstätte and / or oil shale deposit, and / or the bitumen reservoir and / or the heavy oil reservoir. The conductor device has an inner conductor and an outer conductor arranged coaxially with the inner conductor, wherein the inner conductor and the outer conductor are capacitively coupled. In addition, the heater includes an alternator for providing an alternating current which is electrically connected to the conductor means. In a space between the inner conductor and the outer conductor, a dielectric fluid is introduced. In this case, the inner conductor and the outer conductor are capacitively, in particular exclusively, capacitively coupled via the dielectric fluid.

The heater may be used in a SAGD process to heat a corresponding reservoir in an oil sands deposit and / or an oil shale deposit and / or a bitumen deposit and / or a heavy oil deposit. The heating device has a conductor device, which is designed in particular as a conductor loop. The conductor loop may for example have a length of several hundred meters. The heater also has an alternator which is electrically connected to the conductor device. In particular, the alternator or alternating voltage generator can be electrically connected to a first and a second end of the conductor device. Thus, in the conductor loop a AC are impressed. This has the consequence that are embossed into the reservoir eddy currents which heat the Re ^¬ servoir turn. In the present case, the conductor device is designed as a coaxial conductor. That is, it has an inner conductor and an outer conductor surrounding the inner conductor. In a space between the inner conductor and the outer conductor, a dielectric fluid is at least partially introduced. In this case, the intermediate space between the inner conductor and the outer conductor is formed in particular hermetically sealed, so that the dielectric fluid can not escape from the conductor device and that no substances can penetrate into the intermediate space between the inner conductor and the outer conductor.

In particular, the dielectric fluid is formed to have high withstand voltage. Thus, the use of several capacitors, which are connected between the inner conductor and the outer conductor, can be dispensed with. Thus, costs can be reduced during production. It is also advantageous that the required capaci ^¬ tätsbelag can be much lower than in the previously considered cable and pipe inductors, which is the prerequisite for achieving a high dielectric strength at reasonable dimensions. In addition, the dielectric strength ensures the dielectric strength over the entire length of the conductor device.

The fluid is preferably a gas, which in particular comprises nitrogen and / or sulfur hexafluoride. The gas which serves as a dielectric, can hold nitrogen, sulfur hexafluoride or a mixture of nitrogen and sulfur hexafluoride to ^¬. Alternatively, climate neutral gas mixtures may be used as the fluid.

Is preferably a gas or gas mixture comprising at least egg ^¬ NEN substance from the substance group of siloxanes. The gas or gas mixture particularly preferably comprises molecular nitrogen fabric and at least one further gas component from the group of siloxanes.

According to the combination or mixing of, for example, molecular nitrogen and siloxanes into a gas, a gas results which has a very high dielectric strength. It is advantageous that molecular nitrogen is chemically reakti ^¬ onsarm. Advantageously, siloxanes are not known greenhouse gases (climate-neutral) and as far as is known, the majority of siloxanes are harmless to humans. It is advantageous that siloxanes are inexpensive to produce.

When a gas is used as the dielectric fluid, this has the advantage that it is usually suitable for high temperatures, for example temperatures greater than 300 ° C. On the other hand, dielectrics or insulating pathways, as used for example in cable inductors, can hardly be operated permanently above 200 ° C. Another advantage of a gaseous dielectric is that even in the case of a breakdown between the outer conductor and the inner conductor no destruction of the conductor device takes place. In addition, the gaseous ^¬ The lektrikum can be easily replaced if necessary.

In a further embodiment, the fluid is a liquid, in particular a silicone oil. The dielectric fluid may also be a synthetic oil. The use of a silicone oil or a synthetic oil has the advantage fact is that this can also be used at high temperatures, for example at tempera tures ^¬ than 300 ° C, as a dielectric. In addition, the use of a liquid as a dielectric the advantage that the liquid builds up a hydrostatic pressure, due to their specifi ^¬'s weight, which corresponds approximately to that of the surrounding soil. This means that the outer conductor can be supported by the internal pressure of the liquid. Thus, the wall thickness of the outer conductor could be reduced to the level that is required for the current carrying capacity. is required. However, the outer conductor would not have such a wall thickness with which the complete mechanical pressure of the soil can be absorbed. Even with a liquid as a dielectric, there is the advantage that this can be easily replaced.

Furthermore, it is advantageous if the heating device has at least one support element for supporting the inner conductor against ^¬ over the outer conductor. For example, a plurality of support elements may be arranged between the inner conductor and the outer conductor. These support elements can be distributed uniformly in particular along the circumferential direction of the outer conductor or of the inner conductor. Thus it can be guaranteed that the inner conductor is centered with respect to the outer conductor. In this way it can be prevented that a flashover between the Au ^¬ ßenleiter and the inner conductor occurs. In addition, the at least one support element can contribute to the fact that the weight of the inner conductor can be reliably supported, irrespective of the installation position in the reservoir.

In a further embodiment, the heating device has a pump device for conveying and / or replacing the fluid. With the pump device, the fluid can thus be moved in the space between the inner conductor and the outer conductor. In this way, the fluid can be circulated in accordance with the interim ^¬ c region. By the movement of the fluid and cooling of the inner conductor can be secured ^¬ guaranteed.

In a further embodiment, the alternator is electrically connected to the outer conductor at a first end of the conductor device and to the inner conductor at a second end of the conductor device. In this embodiment, neither the outer conductor nor the inner conductor has an interruption. Thus, in this case, the complete Lei ^¬ tereinrichtung a resonance length. Furthermore, there is no interruption of the conductor device in the ground here. In a further embodiment, the alternator is electrically connected to the inner conductor at a first end of the conductor device and to the inner conductor at a second end of the conductor device, wherein the inner conductor has at least two partial inner conductors which are galvanically isolated. In this case, the inner conductor has at least one interruption. If, for example, the inner conductor consists of two galvanically isolated partial inner conductors, two resonance lengths are formed. The advantage here is that the capacities are reduced. The outer conductor is used for electric field control and as a container for the dielectric. He also serves to carry the current in alternation with the inner conductor. That is, the sum of the currents of inner and outer conductors form the total current, the inner conductor carries no electricity at the points of interruption and the outer conductor must carry each the entire current.

In a further embodiment, the outer conductor has at least two partial outer conductors, which are galvanically isolated. It can also be provided that the outer conductor has an interruption. Again, the capacitances along the conductor means can be reduced. It is also advantageous when the heating device has an electrically insulating sheath member surrounding the Au ^¬ ßenleiter at least regionally. In particular, the enveloping member surrounds the area of the outer conductor, which is brought in a ^¬ the Olsandlagerstätte and / or oil shale deposit, and / or the bitumen reservoir and / or the heavy oil reservoir. The enveloping element serves to electrically insulate the outer conductor from the surrounding earth, that is, the oil sands and the oil shale. The sheath means may be formed, for example, as a plastic sheath. Furthermore, the enveloping element may consist of several layers. For example, the sheath element may comprise at least one layer of mica paper. Furthermore, the sheath element can be made of concrete, pearlite or foam glass. The Hüllelement can also serve to protect the outer conductor from corrosion. This is particularly useful because the reservoir can provide a chemically aggressive environment.

An arrangement according to the invention for conveying heavy oil and / or bitumen from an oil sands deposit and / or a shale deposit and / or a bitumen deposit

and / or a heavy oil deposit comprises a heating device according to the invention. In addition, the arrangement comprises a delivery pipe for conveying the heavy oil liquefied by the heating device and / or bitumen. The arrangement can also have a corresponding tube through which water vapor, which may be mixed with a solvent, can be introduced into the reservoir.

The advantages and developments described above in connection with the heating device according to the invention apply correspondingly to the arrangement according to the invention.

Further features of the invention will become apparent from the claims, the figures and the description of the figures. The description above mentioned features and feature combination Nati ^¬ ones, as well as mentioned below in the figure description and / or alone shown in the figures features and combinations of features can be used not only in the respectively specified combination but also in other combinations or in isolation without departing from the scope of the invention.

The invention will now be described with reference to preferred Ausführungsbei ^¬ play and with reference to the accompanying drawings. 1 shows a heating device for the inductive heating of oil sand deposits and / or oil shale deposits and / or bitumen deposits and / or heavy oil deposits, wherein the heating device comprises a conductor having a device with an outer conductor and an inner conductor;

2 shows the heater according to FIG 1 in another

 Embodiment, wherein the inner conductor has an interruption;

3 shows the heating device according to FIG. 1, wherein the inner conductor and the outer conductor have interruptions; and

4 shows the conductor device in a sectional side view. 1 shows a schematic representation of a heating device 1 for inductive heating of an oil sands deposit

and / or an oil shale deposit, and / or a bitumen ^¬ menlagerstätte and / or a heavy oil reservoir. The heating ^¬ device 1 can for an arrangement for the promotion of

Heavy oil and / or bitumen from these oil sands deposits and / or oil shale deposits and / or bitumen deposit and / or heavy oil deposit serve. In these arrangements, usually by the SAGD method by means of a corresponding pipe, which in a reservoir of the oil sands deposit and / or the oil shale deposit and / or

Bitumen deposit and / or the heavy oil reservoir is turned ^¬ introduced, water vapor introduced ^¬ together with the solvent introduced. This causes the heavy oil or bitumen to dissolve out of the sand or the rock and thus can be transported away by means of a corresponding conveyor tube. By ^{¬ means of} the heater 1, the reservoir can be additionally heated.

The heating device 1 comprises a conductor device 2, which in the present case is designed as a conductor loop. The ^conductor-¬ device 2 has an inner conductor 3 and an outer conductor. 4 The outer conductor 4 and the inner conductor 3 may be made of aluminum, for example. The inner conductor 3 and the outer conductor 4 together form a coaxial conductor. The length of the conductor device 2 may be, for example, several hundred meters. The diameter of the outer conductor may for example be between 15 and 50 centimeters.

In a gap 5 between the inner conductor 3 and the outer conductor 4, a dielectric fluid is arranged. The dielectric fluid serves both for the electrical Isolie ^¬ tion between the inner conductor 3 and the outer conductor 4. On the other hand, the dielectric fluid for the capacitive couplers ^¬ development of the inner conductor 3 and the outer conductor serves 4. The external conductors ^¬ ter 4 or the connection between the Inner conductor 3 and the outer conductor 4 is preferably hermetically sealed. The dielectric fluid may be a gas. This gas may include, for example, nitrogen and / or sulfur hexafluoride. In an alternative embodiment, the dielectric fluid is a liquid. Such a liquid may be playing as a silicone oil or a synthetic oil in ^¬. The ^¬ lectric fluid is used solely for capacitive coupling between see the inner conductor 3 and the outer conductor 4. Thus, in particular no capacitors are connected as components between the inner conductor 3 and the outer conductor 4.

In addition, the heater 1 to an alternator 6. The alternator 6 is electrically connected to the inner conductor 3 of the conductor device 2 at a first end 7. At a second end 8 of the conductor device 2, the alternator 6 is electrically connected to the outer conductor 4. In this case, therefore, both the outer conductor 4 and the inner conductor 3 serve for current transport. In the present case, the alternating current is transmitted from the inner conductor 3 along the length of the conductor device 2 to the outer conductor 4. In this embodiment, neither the inner conductor 3 nor the outer conductor 4 have an interruption. Thus, the entire conductor device 2 or the conductor loop forms a resonance length. 2 shows a heating device 1 in a further embodiment. In this embodiment, the Innenlei ^¬ ter 3 two partial inner conductor 9, which are electrically isolated from each other. In addition, the alternator 6 is electrically connected at the first end 7 and at the second end 8 of the conductor device 2 to the inner conductor 3 and the respective inner conductor 9, respectively. There, the alternating current is transmitted along the length of the conductor device from the first partial inner conductor 9 to the outer conductor 4 and from the outer conductor 4 to the second partial inner conductor 9 again. Due to the interruption of the inner conductor 3, the requirement of the withstand voltage is applied to the capacity decreases to the extent that speaks ent ^¬ the inductive voltage drop of the conductor part.

3 shows the conductor device 2 in a further embodiment. Here, the inner conductor 3 on two interruptions. The inner conductor 3 thus has three galvanically separated partial inner conductor 9. In addition, the outer conductor 4 is galvanically isolated here. Thus, there are two galvanically separated partial outer conductor 10 before. Again, the alternator 6 is connected at the first end 7 and at the second end 8 of the conductor device 2 in each case with the inner conductor 3 and the corresponding partial inner conductor 9. Here, the alternating current is transmitted capacitively starting from the first partial inner conductor 9 to the first partial outer conductor 10, then to the second partial inner conductor 9, from there to the second partial outer conductor 10 and finally to the third partial inner conductor 9.

4 shows the conductor device 2 in a sectional side view. Here, the inner conductor 3 and the outer ^¬ conductor 4 can be seen, which are arranged concentrically with each other. Between the inner conductor 3 and the outer conductor 4 at least one support element 11 is provided. In the present embodiment, three support elements 11 are vorgese ^¬ hen, which are arranged distributed uniformly along the circumferential direction of the inner conductor 3 and the outer conductor 4. The Supporting elements 11 may be formed, for example, of ceramic. The support elements 11 serve to keep the inner conductor 3 concentrically within the outer conductor 4. In addition, the conductor device 2 comprises an enveloping element 12 which surrounds the outer conductor 4. The sheath member 12 is formed into ^¬ special electrically insulating and serves to isolate the outer conductor 4 electrically insulated from the earth or the Olsandlagerstätte and / or oil shale deposit, and / or the bitumen reservoir and / or the heavy oil reservoir. In addition, the enveloping element 12 can serve as corrosion protection. The enveloping element 12 may be formed, for example, from a plastic. The heating device 1, which has the conductor device 2 with dielectric fluid, is characterized in that the inductive voltage drop along the Leitereinrich ^¬ device 2 can be compensated by the dielectric fluid. In addition, the dielectric fluid can provide a high dielectric strength, which is more difficult to achieve with other capacitor designs.

Furthermore, the dielectric or the fluid, in particular Iso ^¬ liergase temperature insensitive. In this way, overall, a cost-effective heating device 1 can be provided, which moreover can be operated more reliably, since the fluid dielectric can be replaced although the conductor arrangement itself remains in the ground.

Claims

claims

1. Heating device (1) for inductive heating of a Olsandlagerstätte and / or an oil shale deposit and / or a heavy oil deposit with egg ^¬ ner ladder device (2), which at least partially into the Olsandlagerstätte and / or the oil shale deposit and / or the Bitumen deposit and / or the heavy oil deposit can be introduced, wherein the conductor device (2) has an inner conductor (3) and a coaxial with the inner conductor (3) arranged outer conductor (4), and wherein the inner conductor (3) and the outer conductor (4) capacitively coupled to an alternating current generator (6) for providing an alternating current which is electrically connected to the conductor device (2),

characterized in that

a dielectric fluid is introduced into an interspace (5) between the inner conductor (3) and the outer conductor (4) and the inner conductor (3) and the outer conductor (4) are capacitively coupled substantially via the dielectric fluid.

2. Heating device (1) according to claim 1, characterized in that the fluid is a gas, which in particular comprises nitrogen and / or sulfur hexafluoride is.

3. Heating device (1) according to claim 1 or 2, characterized in that the fluid is a gas which comprises at least one substance from the group of siloxanes.

4. Heating device (1) according to claim 1, characterized in that the fluid is a liquid, in particular a

Silicone oil, is.

5. heating device (1) according to one of the preceding claims che, characterized in that the conduit means (2) at least one support element (11) for supporting the Innenlei ^¬ ters (3) relative to the outer conductor (4).

6. Heating device (1) according to any one of the preceding claims, characterized in that the heating device (1) ei ^¬ ne pump means for conveying and / or replacing the fluid.

7. Heating device (1) according to one of the preceding claims, characterized in that the alternator (6) at a first end (7) of the conductor device (2) with the outer conductor (4) and at a second end (8) of the conductor Device (2) with the inner conductor (3) is electrically connected.

8. Heating device (1) according to one of claims 1 to 6, characterized in that the alternator (6) at a first end (7) of the conductor device (2) with the inner conductor (3) and at a second end (8) of Conductor (8) with the inner conductor (3) is electrically connected, wherein the inner conductor (3) at least two partial inner conductor

(9), which are galvanically isolated.

9. heating device (1) according to claim 8, characterized in that the outer conductor (4) at least two partial outer conductor

(10), which are galvanically isolated.

10. Heating device (1) according to one of the preceding claims, characterized in that the heating device (1) has an electrically insulating enveloping element (12) which surrounds the outer conductor (4) at least partially.

11. An arrangement for conveying heavy oil and / or bitumen from an oil sands deposit and / or an oil shale deposit and / or a bitumen deposit and / or a Schwerölla ^¬ gerstätte with a heating device (1) according to any one of the preceding claims and with a delivery pipe for conveying the by the heating device (1) liquefied heavy oil and / or bitumen.