The present invention relates to an apparatus for determining the identity, location or level of one or more material phases or the location of an interface between two material phases within a vessel such as an oil separator unit.
The measurement of levels of fill, particularly of fluids including liquids, gases and multi-phase materials such as emulsions and slurries, has been carried out for many years using nucleonic level gauges, by measuring the amount of radiation emitted by a radiation-source which is detected at one or more levels within the vessel. The radiation is attenuated as is passes through materials, the amounts of attenuation being related to the density of the materials between a source and a detector. By comparing the attenuation of radiation detected at different levels of the vessel, it is possible to estimate the height of materials contained in the vessel.
A density profiler based on these principles has been described in WO2000/022387. The device comprises a linear array of sources of ionising radiation which emit radiation towards detectors disposed in one or more linear arrays. When the source array and detector array(s) are positioned so that they traverse the interfaces between two or more fluids in a vessel, the interfaces of the fluids may be identified from the differences in radiation received by each detector in the array. These devices has been successfully deployed for use in storage tanks and oil separators.
It may be undesirable to use a device which embodies a source of ionising radiation. In some parts of the world nucleonic technology may not be a viable option. Alternative detector arrangements with similar functionality that do not require a source of ionising radiation have accordingly been proposed.
Radar level gauge systems are known for measuring fluid levels in vessels. In particular, guided wave radar level sensor probes are known in which transmitted electromagnetic signals are guided towards and into the vessel by a wave guide, typically arranged vertically from top to bottom of the vessel. The electromagnetic signals are reflected at a fluid surface and received back at the level gauge system by a receiver. The time from emission to reception of the signals is used to determine the level in the vessel.
However, traditional guided wave radar solutions have limitations. For example, while guided wave solutions can detect a clean oil-water interface, they cannot detect an oil-water interface if there is an emulsion in the way. Furthermore, microwaves don't transmit through water and so don't probe effectively beyond a water interface.
It is an aim of the invention to provide a non-nucleonic measurement instrument for measuring levels of materials, especially of fluids, and optionally for measuring/calculating a level profile of a multi-layer fluid column, that mitigates some or all of the foregoing disadvantages of current guided wave radar solutions and/or offers an alternative functionality and/or enhanced accuracy.
The present specification provides an apparatus for determining the identity, location or level of one or more material phases or the location of an interface between two material phases within a vessel, the apparatus comprising:
The enclosure can be in the form of an elongate dip pipe with a plurality of windows provided along the dip pipe. The windows can be directly embedded in the wall of the dip pipe. Alternatively, the windows can be mounted into an elongate window mounting and the elongate window mounting is embedded in the wall of the dip pipe. The enclosure provides a sealed environment in which the electromagnetic signal can be directed to any level of a multi-layered fluid column. As such, the apparatus doesn't have the limitations of traditional guided wave radar solutions in which the electromagnetic radiation is directed down through a fluid column such that reliable detection of lower layers in the multi-layer fluid column is impeded by upper layers in the fluid column.
In one configuration, the apparatus comprises an array of the transmitters and receivers disposed within the elongate dip pipe such that each window has an associated transmitter and receiver.
In an alternative configuration, the apparatus comprises an elongate electromagnetic radiation guide coupled to the transmitter to guide the electromagnetic transmission signal from the transmitter to the plurality of windows along the dip pipe. In this case, the elongate electromagnetic radiation guide can also be configured to guide the electromagnetic return signal back from the plurality of windows to the detector.
The apparatus as described herein must seal the interior of the apparatus from the surrounding material phases in the vessel in which it is disposed. As such, the windows provided in the apparatus enclosure wall must be configured to withstand elevated temperatures and pressures which are experienced in certain vessels which require monitoring using the apparatus. For certain applications, the windows may be configured to have a pressure rating of at least 2000 kPa (20 bar), 3000 kPa (30 bar), 4000 kPa (40 bar), or 5000 kPa (50 bar) and/or a temperature rating of at least 200° C., 250° C., or 300° C. The windows may be configured to have a pressure rating up to 10,000 kPa (100 bar) and a temperature rating up to 500° C. for example.
In order to increase the pressure rating of the windows they may be mounted in the wall of the enclosure via a tapered seal, in the form of a sloped or stepped wall seal, to prevent the windows from being pushed into the apparatus when subjected to pressure from the material phases within the vessel in which the apparatus is disposed. In certain configurations, the enclosure wall is metallic, the one or more windows are glass, and the one or more glass windows are mounted in the metallic wall of the enclosure via a glass-metal bond. Sight glasses, such as borosilicate sight glasses, are available which are pressure rated to high temperatures. The windows can be mounted by heating the metal surround to expand the surround, inserting the windows, and allowing the surround to cool and contract around the windows. The edge of the windows melts and bond to the metal surround via a glass-metal bond and the surround contracts on cooling to compress the window providing a tight pressure seal. This mounting method also has the advantage of avoiding the use of adhesives which could be reactive with materials within a vessel in which the apparatus is disposed in use. That is, the glass-metal bond provides a chemically inert seal.
The apparatus as described herein is used to determining the identity, location or level of one or more material phases or the location of an interface between two material phases within a vessel. A method of determining the identity, location or level of one or more material phases or the location of an interface between two material phases within a vessel is provided, the method comprising:
The invention will now be described by way of example only with reference to the accompanying drawings, in which:
In the arrangement shown in
The instruments illustrated in
One or more transmitters are arranged to transmit electromagnetic transmission signals through the windows to interact with the one or more material phases outside the windows in the vessel. Receivers are arranged to receive electromagnetic return signals from the windows and process the electromagnetic return signals to determining the identity, location or level of the one or more material phases or the location of the interface between two material phases within the vessel.
The windows are mounted in the wall of the dip pipe with a pressure rating of at least 1000 kPa (10 bar) and a temperature rating of at least 150° C. so as to prevent failure of the window and ingress of the one or more material phases into the apparatus at elevated pressures and temperatures. The apparatus as described herein must seal the interior of the apparatus from the surrounding material phases in the vessel in which it is disposed. As such, the windows provided in the apparatus enclosure wall must be configured to withstand elevated temperatures and pressures which are experienced in certain vessels which require monitoring using the apparatus. For certain applications, the windows may be configured to have a pressure rating of at least 2000 kPa (20 bar), 3000 kPa (30 bar), 4000 kPa (40 bar), or 5000 kPa (50 bar) and/or a temperature rating of at least 200° C., 250° C., or 300° C. The windows may be configured to have a pressure rating up to 10,000 kPa (100 bar) and a temperature rating up to 500° C. for example.
The dip pipe provides a sealed environment in which the electromagnetic signal can be directed to any level of a multi-layered fluid column. As such, the apparatus doesn't have the limitations of traditional guided wave radar solutions in which the electromagnetic radiation is directed down through a fluid column such that reliable detection of lower layers in the multi-layer fluid column is impeded by upper layers in the fluid column.
In order to increase the pressure rating of the windows they may be mounted in the wall of the enclosure via a tapered seal, in the form of a sloped or stepped wall seal, to prevent the windows from being pushed into the apparatus when subjected to pressure from the material phases within the vessel in which the apparatus is disposed. In certain configurations, the enclosure wall is metallic, the one or more windows are glass, and the one or more glass windows are mounted in the metallic wall of the enclosure via a glass-metal bond. Sight glasses, such as borosilicate sight glasses, are available which are pressure rated to high temperatures. The windows can be mounted by heating the metal surround to expand the surround, inserting the windows, and allowing the surround to cool and contract around the windows. The edge of the windows melts and bond to the metal surround via a glass-metal bond and the surround contracts on cooling to compress the window providing a tight pressure seal. This mounting method also has the advantage of avoiding the use of adhesives which could be reactive with materials within a vessel in which the apparatus is disposed in use. That is, the glass-metal bond provides a chemically inert seal.
The transmitter is configured to transmit a microwave signal or a radio wave signal. As such, the windows are not required to be transparent to visible light and in certain applications is can be advantageous for the windows to be coloured or opaque to visible light.
The apparatus as described herein is used to determining the identity, location or level of one or more material phases or the location of an interface between two material phases within a vessel. A method of determining the identity, location or level of one or more material phases or the location of an interface between two material phases within a vessel is provided, the method comprising:
For very high-pressure applications, the apparatus may be provided with a pressure control mechanism to alter the pressure within the enclosure and thus reduce the pressure differential across the window(s) in the enclosure.
While this invention has been particularly shown and described with reference to certain embodiments, it will be understood to those skilled in the art that various changes in form and detail may be made without departing from the scope of the invention as defined by the appended claims.
Number | Date | Country | Kind |
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1916827.7 | Nov 2019 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2020/052370 | 9/30/2020 | WO |