The invention relates to the field of large hydraulic pumps for use in renewable energy turbine generators, such as wind turbine generators (WTGs), and to methods and apparatus for maintaining hydraulic pumps of that type.
Issues concerning the present invention will now be described with reference to hydraulic pumps coupled to the blades of a WTG, however similar issues apply in respect of large hydraulic pumps for use in other renewable energy turbine generators.
WTGs are known which include large hydraulic pumps mounted in a nacelle high above the ground. In a WTG of that type, the hydraulic pump is coupled to the turbine blades through a drive shaft (and optionally a gear box) and is connected through a hydraulic circuit to at least one hydraulic motor which in turn drives an electricity generator.
The pumps are difficult to maintain, firstly because they are large and heavy, and so require heavy lifting apparatus, such as cranes to move the pump, or component parts thereof, and secondly because they are far from the ground. Maintenance is especially difficult for offshore WTGs which stand in water and can only be accessed by boat or helicopter.
PCT/GB2011/050355 (Artemis Intelligent Power Limited) discloses a large, maintainable pump suitable for use in a WTG in which an outward ring is formed from demountable blocks which are individually removable in a radial direction, enabling components of an inward ring, such as ring cam segments, to be accessed or removed for maintenance. Nevertheless, it can still be difficult to remove some of the demountable blocks located in different orientations.
Accordingly, the invention addresses the technical problem of maintaining large hydraulic pumps in situ within WTGs and other renewable energy extraction devices.
According to a first aspect of the invention there is provided a method of removing a demountable part from a hydraulic pump in a renewable energy turbine generator,
wherein the hydraulic pump comprises:
an inward ring comprising a cam having a cam surface;
an outward ring comprising one or more demountable parts, at least some of the de-mountable parts comprising cylinders, with pistons slidably mounted in the cylinders and in engagement with the cam surface;
first and second axially spaced structural members disposed on opposite sides of the cam;
a housing which is removable (e.g. axially slidable or disassemblable) to reveal internal components (for example, the cylinders and cam) for maintenance and repair; and
a drive shaft coupled to the inward ring;
the method characterised by rotating the outward ring about the drive shaft (which typically remains fixed in position) until the demountable part reaches a selected position, and then removing the demountable part.
Thus, at least the outward ring (and in some embodiments also the inward ring) is rotated until the demountable part is at a position selected to facilitate removal of the demountable part. Preferably, the drive shaft remains fixed in position during rotation and the removal of the demountable part.
The invention therefore enables convenient maintenance of large hydraulic pumps in renewable energy turbine generators. The hydraulic pump may, for example, have a mass of greater than 10 tons, or greater than 50 tons. The hydraulic pump may be mounted greater than 50 m, or greater than 100 m above the ground. The hydraulic pump may be mounted in the nacelle of a wind turbine generator, for example, an offshore wind turbine generator.
The demountable part may comprise one or more cylinders or valves. However, the demountable part may be a component, such as a valve. Typically, the outward ring comprises a plurality of demountable parts arranged around the axis of the outward ring and the outward ring is rotated until at least one selected demountable part of the plurality of demountable parts reaches a selected position.
The cam may be a multi-lobed ring cam. The demountable part may, for example, be a demountable block. The outward ring may comprise a plurality of demountable blocks arranged around the axis of the outward ring. In some embodiments, the inward ring comprises a plurality of inward demountable parts (e.g. segments of a ring cam) and the outward ring comprises a plurality of demountable blocks and the method comprises removing one or more of the inward demountable parts after removing one or more of the demountable blocks of the outward ring (outward demountable parts) which cover the respective inward demountable part.
After the removal of one or more demountable parts (e.g. demountable blocks comprising cylinders), the method may comprise rotating the inward ring (after decoupling the inward ring from the turbine blades, for example by decoupling the drive shaft from the inward ring, gears (if present) or the turbine blades) to reveal parts of the inward ring through the gap left by the removed demountable parts. The revealed parts of the inward ring may be said inward demountable parts, such as segments of a ring cam.
Preferably, the outward ring of the hydraulic pump is generally rotationally symmetric. Preferably, the inward ring of the hydraulic pump is generally rotationally symmetric. Preferably, the hydraulic pump is generally rotationally symmetric.
Typically, the drive shaft is coupled through bearings to the outward ring and the first and second axially spaced structural members (e.g. end plates).
It may be that the outward ring has an axis extending through the drive shaft and the selected position is above the height of the axis.
In some embodiments, the selected position may be at the top of the outward ring.
The method may comprise the steps of fixing the angular position of the inward ring and actuating the pump to rotate the outward ring relative to the inward ring until the demountable part reaches the selected position.
It may be that the drive shaft is rotated and then locked into position (for example, by way of a pin extending through the inward ring), the outward ring is decoupled from the chassis of the renewable energy turbine generator, and the outward ring is then rotated relative to the inward ring.
Once the outward ring is in the desired rotational position, in order to obtain access to the desired part of the inward ring, the torque arm may be left connected so the outward ring is stationary. The driveshaft may then be rotated (while the driveshaft is fixed to the inward ring). Rotation may continue until the respective part of the inward ring reaches a desired position (i.e. directly in line with a removed portion(s) of outward ring.
The outward ring may therefore be driven by a motor (e.g. a positioning worm drive) acting on the outward ring or, where the outward ring is fixed to the inward ring, acting on the drive shaft.
In some embodiment, the hydraulic pump may be operated to rotate the outward ring relative to the inward ring. Typically, operating the pump to rotate the outward ring relative to the inward ring comprises supplying pressurised fluid to at least some of the said cylinders to cause the piston cylinders to carry out motoring cycles and thereby drive the outward ring to rotate relative to the inward ring. In this case, hydraulic fluid is retained within the hydraulic pump whilst the outward ring is rotated relative to the inward ring.
The hydraulic pump may comprise one or more torque reaction devices (e.g. one or more torque arms) which detachably connect the pump to a support (e.g. a chassis, base, or the nacelle of a wind turbine generator) to prevent rotation of the pump during normal operation, and the method comprises detaching the one or more torque reaction devices to enable the pump to be rotated relative to the support.
The one or more torque reaction devices may be detachable by sliding (of the pump or of the torque reaction devices), typically after the removal of connectors, such as bolts. It may be that the torque reaction devices require to move by less than 10 mm for the pump ring to be rotatable. The one or more torque reaction devices may be disassembled, at least in part to detach the pump from the support.
The method of moving the demountable part until it reaches the desired position may in part be determined by the nacelle arrangement and the configuration of the one or more torque reaction devices. For example in respect of
However, typically hydraulic fluid is drained from the hydraulic pump before the outward ring is rotated relative to the inward ring.
It may be that the hydraulic pump comprises electrical connecters for coupling electrical devices within the hydraulic pump (e.g. electronically controlled valves which regulate the flow of hydraulic fluid between a hydraulic line and a cylinder) to external electrical connections and the method comprises decoupling the electrical connecters before the outward ring is rotated.
It may be that the hydraulic pump comprises hydraulic connecters for coupling hydraulic lines within the hydraulic pump (e.g. hydraulic lines supplying hydraulic fluid to or receiving hydraulic liquid from the cylinders) to external hydraulic lines, and the method comprises decoupling the hydraulic connecters before the outward ring is rotated. The hydraulic connectors may comprise seals.
It may be that the one or more torque reaction devices comprises at least one electrical cable through which electrical signals are provided to or received from the hydraulic pump, by way of a said electrical connector. It may be that all electrical connections to the hydraulic pump are made through electrical cables within the one or more torque reaction devices. The method may comprise detaching a said electrical cable from a said electrical connector. It may be that the one or more torque reaction devices comprises at least one hydraulic line through which hydraulic fluid is supplied to or received from the hydraulic pump by way of the said hydraulic connectors. It may be that all hydraulic connections to the hydraulic pump are made through hydraulic lines which extend through the one or more torque reaction devices. The method may comprise detaching a said hydraulic line from a said hydraulic connector. These features have the advantage of simplifying the procedure of coupling the hydraulic pump to and decoupling the hydraulic pump from the chassis of the renewable energy turbine generator, as the same structures provide torque reaction and either or both electrical and hydraulic connections.
It may be that the electrical connecters and the hydraulic connecters are all located on the same side (i.e. axially opposed faces) of the pump. This facilitates decoupling. The one or more torque reaction devices may also be located on the same side of the pump. It may be that the method comprises further detaching one or more detachable sensors from the hydraulic pump before rotating the outward ring.
It may be that the outward ring comprises a plurality of connecting formations (e.g. apertures) and the method comprises connecting a crane to a said connecting formation and causing the crane to pull on the connecting formation to thereby rotate the outward ring.
The plurality of demountable parts may be demounted from different angles.
It may be that the demountable part is removed using a lifting device which exerts a lifting force which is the majority of the lifting force required to remove the demountable part and wherein a human operative provides the balance of the force required to remove the demountable part.
The demountable part may be removed using a lifting device which exerts a lifting force on the demountable part through a resilient member.
It may be that the demountable part is removed using a lifting device comprising a tensile stress bearing member and a demountable part retaining portion supported by the tensile stress bearing member, the tensile stress bearing member extending vertically from directly above the centre of mass of the demountable part retaining portion and a selected demountable part attached to the demountable part retaining portion.
The lifting device may further comprise an arm which extends from the tensile stress bearing member to a demountable part retaining portion and the demountable part retaining portion extends downward and horizontally from the tensile stress bearing member.
The invention also extends to a method of removing and replacing a demountable part from a hydraulic pump in a renewable energy turbine generator further comprising the step of fitting a demountable part (either the same part or a replacement part) using a lifting device which exerts a lifting force on the demountable part through a resilient member.
The provision of a resilient member is useful during both removal and replacement of a demountable part as it enables a small amount of manual adjustment of displacement by an operative, which is useful for manual movement or manipulation during the final stages of fitting or initial stages of removal. The resilient member may comprise a spring. A spring is advantageous in that the extent to which it is deformed (in a typical configuration the spring will lengthen as the applied force is increased) provides a simple visual gauge of the amount of force which is being applied.
It may be that the demountable part is removed using a handling device comprising a supported arm extending between a demountable part retaining portion at a first end and a counterweight at the opposite second end. The supported arm may be raised and lowered by a crane. The supported arm may be supported by a rigid support member. The supported arm may be supported by a sling. The rigid support member or sling may comprise a resilient member. The rigid support member or sling may extend from the supported arm to a connector. An arm adjusting member, such as a line including a winch, may extend from the connector to the second end of the arm.
The method may comprise the further step of replacing the removed demountable part, or introducing an alternative demountable part, to the position from which the demountable part was removed, before the fluid working machine is further operated.
The renewable energy turbine generator may be a wind turbine generator which provides energy to the hydraulic pump during normal operation through the drive shaft, driven by a plurality of turbine blades.
According to a second aspect of the present invention there is provided a renewable energy turbine generator comprising a hydraulic pump and a turbine,
the hydraulic pump comprising:
an inward ring comprising a cam having a cam surface;
an outward ring comprising one or more demountable parts, at least some of the demountable parts comprising cylinders, with pistons slidably mounted in the cylinders and in engagement with the cam surface;
first and second axially spaced structural members disposed on opposite sides of the cam;
a housing which is removable (e.g. axially slidable or disassemblable) to reveal internal components (for example, the cylinders and cam) for maintenance and repair; and
a drive shaft coupled to the inward ring;
characterised by means for rotating the outward ring about the drive shaft (which typically remains fixed in position) until the demountable part reaches a selected position, and then removing the demountable part.
It may be that the means for rotating the outward ring, until a selected demountable part reaches a select position, comprise means for fixing the angular position of the inward ring, and a controller for actuating the fluid working machine to rotate the outward ring relative to the inward ring until a selected demountable part reaches a selected position while the angular position of the inward ring is fixed.
The invention also extends to a lifting mechanism for lifting a demountable part from the outward ring of the hydraulic pump of a renewable energy turbine generator according to the second aspect of the invention to thereby remove the demountable part, the lifting mechanism including an elongate tensile stress bearing member, at least part of the length of which is resilient.
Preferably, the lifting mechanism includes an elongate tensile stress bearing member and an arm which extends from the tensile stress bearing member to a demountable part retaining portion, wherein the demountable part retaining portion extends downward and horizontally from the elongate tensile stress bearing member.
An example embodiment of the invention will now be described with reference to the maintenance of a pump located within the nacelle of a WTG. However, the methods and apparatus of the invention may be applied to large pumps within other types of renewable energy extraction devices.
With reference to
The pump comprises first and second end plates 18A and 18B and a housing 20 which can be slid axially to reveal internal components for maintenance and repair. The pump is generally rotationally symmetric about an axis extending through the drive shaft. The pump comprises an inward ring shown generally as 21, comprising a toroidal ring cam support 22 having a plurality of wave-like ring cam segments 23 demountably secured thereto in use and which together form a ring cam. The ring cam is multilobal and more than one ring cam can be mounted to the ring cam support adjacent to each other and axially spaced.
The pump further comprises an outward ring shown generally as 24, comprising the first and second end plates 18A and 18B, which are independently mounted on the drive shaft 26 through bearings 28, and a plurality of demountable cylinder blocks 30. The drive shaft extends through both the first and second end plates and the end plates function as the first and second axially spaced structural members. The outward ring is continuous.
The cylinder blocks are shown in cross-section in
The first and second end plates each comprise a circular shoulder 40A and 40B, extending around the respective end plate, close to but within the outer perimeter of the first and second end plates. Each cylinder block is demountably retained on the circular shoulder. This defines the distance between each cylinder and the ring cam and provides structural strength. Each cylinder block is mounted in place by axial bolts 42 extending through apertures in the end plates and through the cylinder block, between cylinders, and also by radial bolts 44 extending through apertures in the cylinder blocks and into the circular shoulders. Typically, an axial bolt is provided towards each circumferentially spaced end of each cylinder block and a pair of radial bolts (one for each end plate) is provided towards each circumferentially spaced end of each cylinder block.
The volume between the outer housing and the cylinder blocks functions as a low pressure manifold 46, receiving hydraulic fluid to be supplied to the pump. The fluid in the low pressure manifold has a preload pressure of a few atmospheres. This helps to force the pistons against the ring cam. Working fluid is supplied from this cavity into each working chamber through a conduit 48 and electronically controlled valve 50. A further conduit 52, functions as part of a high pressure manifold, receiving fluid via a check valve 54. The conduit extends through the cylinder block and radially inwards through ports in the cylinder block and the shoulder of the second end plate, to further conduits for outputting high pressure fluid 56. At least one of each pair of cooperating ports has a seal. The second end plate includes outflow ports (not shown) for delivering high pressure fluid to a load, such as a hydraulic motor which in turn drives an electricity generator.
In the assembled machine, the cylinder blocks not only function as housings for the piston cylinders, but also provide structural integrity. They are flush to both the first and second end plates and are axially and radially bolted into position in use, at each circumferentially spaced end. They can therefore resist forces acting between the end plates in use, for example forces arising from the weight of the pump which is supported predominantly through the mounting plate which is attached to only the first end plate, and torsional forces arising from the forces acting through the drive shaft and on the pistons, which do not extend directly radially but at a slight angle. The radial bolts also act to resist outwards forces on the cylinder blocks arising from the outwards forces of the ring cam acting on the pistons and the preload pressure in the low pressure manifold.
In a first example maintenance method according to the invention, the blades of the WTG are controlled (e.g. feathered, or braked) to come to a standstill and the drive shaft is fixed in position using a pin, as is known in the art. Next, hydraulic fluid is drained from the system, in particular from the low and high pressure manifolds, the cylinders and the crankcase (which includes the bearings, piston rollers etc.). Once the hydraulic fluid has been drained, plumbing connections to the high and low pressure manifold are removed, as are electrical connections to the pump. The housing is then slid axially to expose the demountable blocks and cylinders.
The outward ring is then decoupled from the nacelle. This can be achieved in different ways in different embodiments. For example, the pump might be moved a short distance away from the mounting plate and torque arms, after the removal of bolts fixing the pump to the mounting plate and torque arms. Alternatively, the mounting plate and torque arms might be moved a short distance from the pump. In some embodiments, the mounting plate or torque arms are jointed to the outward ring through one or more torque pins which can be removed. In still further embodiments, the mounting plate and torque arms remain attached to the outward ring but are decoupled from the nacelle.
The result of this procedure is that the drive shaft, and therefore the inward ring, is fixed in position but the outward ring can rotate relative to the inward ring. The next stage is that the outward ring is rotated relative to the inward ring until it reaches a desired orientation. If the outward ring is not too massive and the friction from the bearing is not too high, it might be possible for the outward ring to be rotated manually, as mass is distributed evenly around its circumference. Otherwise, the outward ring can be rotated by an auxiliary motor. In some embodiments, the end plates contain a plurality of apertures 60 distributed around their periphery and a crane 61 located above the pump can be linked to one or more apertures and pull on the end plates, thereby rotating the outward ring relative to the inward ring until a desired orientation is obtained. Alternatively, or additionally, a plurality of handholds may be provided around the periphery of the outward ring.
Thereafter, one or more demountable blocks can be removed. Firstly, the axial bolts are loosened. If need be, spreader bars are fitted between the end plates to slightly separate them and to facilitate the removal of the blocks. Spreader bars are also useful to maintain the structural integrity of the pump once several demountable blocks have been removed. Secondly, a crane is attached to a demountable block, as shown in
Once the demountable blocks, including the cylinders, have been removed, ring cam segments may be removed radially through the resulting gap in the outward ring. In the illustrated design, two adjacent demountable blocks must be removed before a ring cam segment can be removed.
Maintenance may involve replacing one or more parts, for example, replacing a ring cam segment or a demountable block, or components such as cylinders, pistons, piston rollers etc. Parts may be inspected or tested, either in situ, or after removal before they are replaced.
In order to return the machine to operation, demountable blocks (either the same blocks, or replacement blocks) are lowered into position using the crane, any spreader bars are removed, the axial bolts are replaced, and then the outer ring is recoupled to the nacelle by re-engaging the torque arms. Typically, there is only one correct orientation for the outer ring so that hydraulic fluid and electrical connections can be attached correctly. The housing is then replaced, electrical and hydraulic fluid connections are attached and hydraulic fluid is returned to the fluid manifolds (including the volume around the demountable blocks) and crankcase.
Thus, the lifting arrangement can be lowered using the crane and positioned just below a demountable block. The rotatable support is adjusted to the orientation of a demountable block at a desired location (e.g. the base of the outward ring) and the support plate is attached to the selected demountable block. The weight of the counterweight is held by the arm adjusting line enabling an operative to readily attached the support plate to the demountable block. The demountable block can then be removed downwards by operating the crane. The ratchet winch can be adjusted to alter the length of the arm adjusting line and thereby raise or lower the support plate to facilitate the removal, or subsequent replacement, of a demountable block. In some embodiments, the rigid support member is replaced with a flexible sling. In some embodiments, the crane is attached directly to the connector. The ratchet winch might be replaced with another length varying member, which may be resilient, for example a spring.
In an alternative procedure, it is possible for the outward ring to be rotated relative to the inward ring by supplying high pressure fluid to one or more cylinders of the pump, to cause the cylinders to execute one or more motoring strokes, before hydraulic fluid is drained from the pump, to thereby rotate the outward ring relative to the inward ring, after the outward ring has been decoupled from the nacelle.
It is also possible for the inward ring to be decoupled from the turbine blades. In this case, the inward ring and the outward ring could be rotated together using an auxiliary motor once the outward ring has been decoupled from the nacelle. In some embodiments, once the outward ring was rotated to a desired orientation and selected demountable blocks were removed from the outward ring, the inward ring could be rotated to enable the ring cam to be inspected and maintained without further rotation of the outward ring.
Accordingly, the invention has provided a fluid working machine which is readily maintainable in a difficult to access location, such as in the nacelle of a wind turbine tower, despite the substantial mass of machine required in applications such as large scale wind power generation.
A number of different types of variable displacement radial piston fluid working machine are known and the invention is applicable with many of these types of machine. However, the fluid working machine may be a fluid working machine which is operable to select the volume to be displaced by working chambers during individual volume cycles on each successive cycle of working chamber volume by control of the timing of the opening or closing of electronically controlled valves interposed between each cylinder and the low pressure manifold, to select whether a given cycle of working chamber volume is a pumping cycle in which there is a net displacement of working fluid from the low pressure manifold to the high pressure manifold, or an idle cycle in which there is no net displacement of working fluid from the low pressure manifold to the high pressure manifold, either because the cylinder remains in fluid communication with the low pressure manifold throughout a cycle, or because the cylinder remains sealed throughout a cycle.
Further variation and modifications may be made within the scope of the invention herein disclosed.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP11/04824 | 8/30/2011 | WO | 00 | 2/16/2012 |