The present disclosure relates to assemblies for generating electrical power from a fluid flow. Specifically it relates to assemblies comprising turbine generators and installation methods for installation of such assemblies in fluid conduits.
Turbine generators are used to generate electrical energy from mechanical energy. A hydro or water turbine generator converts the energy from a moving flow of water in to electrical energy. For example, a hydroelectric turbine may be positioned downstream from a large dam in a river. Such hydroelectric power generation is normally used to provide energy for communities, such as fed in to a communal power grid. The purpose of such systems is to use as much energy as possible from the flow of water and convert it to electrical energy.
However, smaller hydroelectrical power generation systems may instead be used to provide power to systems which are otherwise difficult to provide with reliable power. For example, measuring of flow velocity, water quality etc. of the water present in communal water systems requires installing devices within pipes deep under the ground in cities or towns. Providing power to such devices requires expensive rerouting of mains electrical cables or the like. Batteries may also be used to power such systems but batteries have a finite lifetime and thus would need to be replaced which leads to increased costs.
A renewable power source provided in the vicinity of the sensor systems themselves would thus be ideal. The size and geometry of such a hydroelectric turbine generator is heavily constrained by the application area. Such existing pipes have only a limited flow, therein only limited energy can be generated from the flow. Techniques and designs for increasing the energy available within the available geometry are thus necessary. Furthermore, the flow should not be significantly disrupted by the turbine generator as this would disrupt the water system.
U.S. Pat. No. 9,982,652 B2 (Hydrospin Monitoring Solutions Ltd) describes a system and method of insertion and extraction of a turbine device to a fluid-containing body. The system is designed for repeated insertion and removal of the turbine from the fluid-containing body post initial installation and does not provide a solution for initial installation of a fluid conduit comprising a fluid.
Existing methods of installation of turbine generators in existing fluid conduits involve removing a portion of the fluid conduit and installation of the turbine within a new section of fluid conduit. However, such installation processes require the flow of water to be stopped such that the fluid conduit can be cut and the portion removed. This process is costly, time-consuming and may not be available in critical systems such as communal water systems. Improved methods of installation and assemblies for installation in existing fluid conduits under pressure are required.
Accordingly, the present invention preferably seeks to mitigate, alleviate or eliminate one or more of the above-identified deficiencies in the art and disadvantages singly or in any combination and solves at least the above mentioned problems by providing an assembly for generating electrical power from a fluid flow being installable to a fluid conduit comprising a fluid, the assembly comprising a turbine for generating power from the fluid flow, the turbine provided within a turbine body, the turbine and turbine housing being provided with a rotor and stator assembly such that rotation of the turbine generates an electric power. The assembly comprises a connecting member having a proximal portion attached to a distal portion of the turbine body and a distal portion comprising a cap, a separate enclosure for housing the turbine and turbine body, the enclosure slidably receiving the connecting member through a distal portion, the cap of the connecting member being securable to the enclosure. The enclosure is connectable to a valve member, the valve member and the enclosure for provision external to the fluid conduit comprising the fluid.
A method of installing an assembly is also provided.
Further advantageous embodiments are disclosed in the appended and dependent patent claims.
These and other aspects, features and advantages of which the invention is capable will be apparent and elucidated from the following description of embodiments of the present invention, reference being made to the accompanying drawings, in which
The turbine 100 and the turbine housing 200 comprise a rotor and stator assembly for generating electrical energy from the flow of fluid past the turbine 100. Generally the turbine 100 comprises the rotor and the turbine housing 200 comprises the stator. The rotor and stator may be constructed as described in WO2019070177 A1 (Aqua Robur Technologies AB). The rotation of the rotor with respect to the stator generates an electrical current in the stator. The electrical power generated by the rotation of the rotor with respect to the stator is used to power external devices attached to the assembly 1, and may power devices provided to the assembly 1.
As stated above, the enclosure 600 is connectable to a valve member 500 for optional sealing/opening of a fluid path from the fluid conduit 2. In some instances the assembly 1 may comprise the valve member 500. The valve member 500 is provided with a closable aperture 501 for receiving the turbine housing 200 and connecting member 300.
The valve member 500 is connectable to a saddle clamp 400 which is securable around a fluid conduit 2. The saddle clamp 400 may secure the assembly 1 to the fluid conduit 2. The valve member 500 is necessarily and always located external or outside of the fluid conduit 2 to allow hot-tapping.
The turbine housing 200 has a longitudinal axis L, a transversal axis T and a lateral axis A. The longitudinal axis L, and therein the length of the turbine housing 200 and turbine 100 is aligned with the direction of fluid flow when the turbine 100 and turbine housing 200 is installed in a fluid conduit 2.
The turbine housing 200 has an outer wall 201 which defines its external geometry. A bottom portion 202 of the housing 200 has an external substantially cylindrical geometry along the longitudinal axis L of the turbine housing 200. The external cylindrical geometry of the bottom portion 202 is defined by the outer wall 201 of the turbine housing 200. The cylindrical geometry improves fluid flow past the turbine housing 200. The bottom portion 202 may be referred to as the proximal portion 202 of the turbine housing 200 as it is the portion proximal the flow of fluid through the fluid conduit 2.
The turbine housing 200 encloses the turbine 100. The inner geometry of the housing 200, enclosing the turbine 100, may have a substantially cylindrical geometry. That is, the turbine 100 rotates within a cylindrical region. The housing 200 has first 203 and second 204 flow ends. Flow ends 203, 204 refer to the ends of the housing 200 where fluid enters or leaves the housing 200. The flow ends 203, 204 are aligned with the turbine 100. Fluid flowing through the housing 200 and the turbine 100 has a substantially linear flow path. The housing 200 has a length, wherein the length of the housing refers to the distance from the first flow end 203 to the second flow end 204. As shown in
The outermost wall of the turbine housing 200 may be substantially cylindrical along the transversal axis T, that is it may have a circular cross-section. The outer wall 201 of the bottom portion 202 may have a circular cross-section along the transversal axis T of the housing 200. The outer diameter of the cross-section of the turbine housing 200 along the transversal axis may be less than about 50 mm.
This substantially cylindrical cross-section along the transversal axis allows the turbine housing 200 and therein the turbine 100 to be positioned within a pipe with a circular cross-section perpendicular to the flow of fluid. This is especially ideal where the turbine 100 and turbine housing 200 is to be mounted to an existing pipe or pipe section. An existing section of pipe may be difficult to access and a turbine housing 200 having a circular cross-section can be efficiently installed in to a bore, that is a circular hole, in to the existing pipe. Due to its cylindrical geometry along the transverse axis T, the turbine assembly 1 is receivable in a cylindrical bore. This also enables the turbine housing 200 to be more easily receivable through an aperture 501 in a valve member 500. Generally valve members used with fluid conduits have circular cross-sections and by providing a turbine housing 200 with a cylindrical geometry along its transversal axis T the turbine may efficient fit through the valve member 500. The cylindrical form along the transversal axis T also improves fluid flow around the turbine housing 200 within the fluid conduit 2.
The turbine housing 200 is connected to the connecting member 300 at the distal portion 205 of the housing 200. The distal portion 205 of the turbine housing 200 connects to the proximal portion 301 of the connecting member 300. The connecting member 300 may be a shaft formed element extending perpendicular to the longitudinal axis, L and the lateral axis A, of the turbine housing 200.
The distance between the proximal end 301 and the distal end 302 of the connecting member 300 is the length of the connecting member 300. The connecting member 300 has a length adapted such that the turbine may be positioned within a fluid conduit 2 and such that the distal end 302 remains at a position above each of the saddle clamp 400, the valve member 500 and the enclosure for the turbine housing 600 when the assembly is installed at a fluid conduit 2. The term above used herein refers to the distal end 302 being at a position distal to each of the: enclosure 600, valve 500 and saddle clamp 400 respectively, to the fluid conduit 2.
The turbine housing 200 may be permanently fixed to the connecting member 300. The connecting member 300 may be bonded to the turbine housing 200 with a bonding medium. The bonding medium may provide a solid retaining means for electrical cabling exiting the turbine housing 200.
The distal end 302 of the connecting member 300 is provided with a cap 303 for connecting the connecting member 300 to the enclosure 600. The cap 303 may comprise a thread such that it can be screwed to the enclosure 600. In such an arrangement the enclosure 600 comprises a corresponding thread. The cap 303 may comprise an electrical connector for connection to electrical cabling from the turbine 100 and to any devices requiring power from the turbine 100.
The turbine housing 200, and connecting member 300, may be rotatable with respect to a portion of the cap 303. The cap 303 may comprise a first portion comprising a threaded portion for connection to the enclosure 600, the cap may comprise a second portion rotatably fixed to the connecting member 300 and rotatable with respect to the first portion of the cap 303. In such an arrangement the alignment of the turbine housing 200 and the turbine 100 may be adjusted by turning the second portion of the cap 303 with respect to the first portion. This allows the turbine to be efficiently aligned within the fluid conduit 2 without needing to adjust the connection of the cap 303 to the enclosure 600.
The enclosure 600 is specifically adapted for enclosing the turbine housing 200 and sealing against the connecting member 300 such that fluid may not flow past the enclosure 600. The enclosure 600 has a proximal portion 601 connectable to the valve member 500. Fluid may flow through the proximal portion in to the enclosure 600 if the valve member 500 is open and there is fluid in the fluid conduit 2. The enclosure is provided with a sealing interface 603 at its distal portion 602 such that fluid may not flow past the enclosure 600. The sealing interface 603 may seal against the connecting member 300. The sealing interface 603 enables the connecting member 300 to slide past the interface 603. The sealing interface 603 may be an o-ring provided in a annular slot on an inner wall 604 of the enclosure 600. The distal portion 602 of the enclosure has a diameter less than the greatest diameter of the turbine housing 200. That is, the turbine housing 200 may not be fully withdrawn from the enclosure via the distal portion 602. The proximal portion 601 of the enclosure has a diameter greater than the greatest diameter of the turbine housing 200. The proximal portion 601 of the enclosure 600 may be substantially cylindrical and have an open proximal end. The distal portion 602 may have a substantially cylindrical form and have an open distal end. The proximal 601 and distal 602 portions of the enclosure may be co-axial. To form the proximal and distal regions of the enclosure 600 the outer wall 604 of the enclosure 600 may be provided with a step 605 from the proximal portion 601 having a diameter greater than the diameter of the turbine housing 200 to the distal portion 602 having a diameter less than the diameter of the turbine housing 200. The step 605 may be present in the internal wall 606 of the enclosure 600. The step 605 may form an abutment which restricts the upward movement of the turbine housing 200 out of the enclosure 600.
The outer wall 604 of the enclosure 600 may furthermore be provided with a threaded portion 607 such that the enclosure may be screwed to the valve member 500. The valve member 500 has a corresponding thread to form a fluidically tight seal.
The enclosure 600 is provided external to, that is outside of, the fluid conduit 2. The enclosure 600 fills with fluid during installation when the valve member 500 is opened. The enclosure 600 and the valve member 500 never provided within the fluid conduit 600. This enables a smaller bore hole to be drilled to the fluid conduit 2 during installation. As the hole need only accommodate the turbine housing 200 and not the enclosure 600.
The valve member 500 is connectable to the saddle clamp 400 and the enclosure 600. The valve member 500 is provided with an aperture 501 through which the turbine housing 200 may pass during installation. The valve member 500 may be closed such that fluid present on the fluid conduit 2 side of the valve member 500 may not pass the aperture 501. The valve member 500 may be a variety of known valve types such as a ball valve. The valve member 500 may be a commercially available, generic, valve member with a threaded proximal portion 502 and a threaded distal portion 502. Such valve members are widely available and generally used for connecting two fluid conduits together. Such commercially available valve members 500 may be used for connecting a saddle clamp surrounding a fluid conduit to a second fluid conduit. That is, for branching or tapping a fluid conduit.
The valve member 500 and the saddle clamp 400 may be comprised in the assembly 1 or may be separate and not part of the assembly 1. Ideally, the valve member 500 and the saddle clamp 400 are standard components and not specifically adapted for use with the turbine housing 200, enclosure 200, or connecting member 300 of the assembly 1. This reduces installation costs as the parts are generally accessible to plumbers or installers.
The turbine 100 and turbine housing 200 are rotatable with respect to the enclosure 600, the valve member 500 and or the fluid conduit 2. The turbine 100 and turbine housing 200 are rotatable around the axis defined by the connecting member 300. The turbine 100 and turbine housing 200 are rotatable in an axis orthogonal to the axis of the fluid conduit 2. Rotation enables the turbine 100 to be adjusted post installation to ensure that it is directly in-line with fluid flow in the conduit 2 and therefore the highest power generation is achievable. The turbine 100 and turbine housing 200 may be rotatable up to 360° such that the turbine 100 and turbine housing 200 such that the direction of fluid flow in the conduit 2 need not be constant. As the connecting member is connected to the turbine housing 200, the connecting member 300 rotates with turbine housing 200 and turbine 100. The connecting member 300 rotates therein with respect to the enclosure 600.
A process for installing a turbine for generating electrical power in to a fluid conduit comprising a fluid flow will now be described.
The process comprises arranging such as affixing a saddle clamp 400 to the fluid conduit 2. Thereafter a valve member 500 is connected to the distal portion of a saddle clamp 400. A drilling device is securely connected to the distal portion of the valve member 500. The valve is open such that the drilling tool of the drilling device can move past the valve and contact the wall of the fluid conduit 2. A bore/aperture is thereafter drilled in the wall of the fluid conduit 2. After the drilling of the aperture is complete the drilling tool may be retracted past the valve member 500. The valve member 500 may thereafter be closed such that fluid does not through from the valve member 500. The drilling device may be removed from the valve 500. The assembly 1 may thereafter be connected to the valve 500. The assembly 1 is connected to the valve 500 via the enclosure 600. The valve 500 may be opened such that fluid flows in to the enclosure 600 of the assembly 1. The turbine 100 and turbine housing 200 may be inserted past the open valve 500 through the aperture in the fluid conduit 2. To insert the turbine 100 and turbine housing 200 the connecting member 300 is slid downwards through the enclosure 600. The turbine 100 and turbine housing 200 are thereafter present within the flow of fluid in the fluid conduit 2 and may generate electrical power. The cap 303 of the connecting member 300 is connected and sealed to the enclosure 600. The angle of the turbine 100 with respect to the flow of fluid thought he conduit may be adjusted my rotating a portion of the cap 303 fixed to the connecting member 300, and therein the turbine housing 200, with respect to a second portion of the cap 303 connected and non-rotatable with respect to the enclosure 600.
The term hot-tapping refers to the installation of new conduits or devices to an existing fluid conduit pressurized with a fluid flow. The process detailed above is a hot-tapping process for the installation of a device for generating electrical power from a fluid flow.
Although, the present invention has been described above with reference to specific embodiments, it is not intended to be limited to the specific form set forth herein. Rather, the invention is limited only by the accompanying claims.
In the claims, the term “comprises/comprising” does not exclude the presence of other elements or steps. Additionally, although individual features may be included in different claims, these may possibly advantageously be combined, and the inclusion in different claims does not imply that a combination of features is not feasible and/or advantageous. In addition, singular references do not exclude a plurality. The terms “a”, “an”, “first”, “second” etc do not preclude a plurality. Reference signs in the claims are provided merely as a clarifying example and shall not be construed as limiting the scope of the claims in any way.
Number | Date | Country | Kind |
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1950692-2 | Jun 2019 | SE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/SE2020/050581 | 6/9/2020 | WO |