NO20140581A1 - Device and method of pump for dive use - Google Patents

Abstract

A device is described by piston pump (1) for use in water, in which a pump shaft (5), via a cylinder housing (9) axially mounted on the pump shaft (5), is arranged to move a plurality of pistons (20) between a first position and a second position in respective cylinder bores (12), and each of the pistons (20) is coupled to a piston shoe (22) which is held in an inclined rotation path, the piston shoes (22) and a slide (25) rotation path being arranged between a support ring (26) and a sliding surface (28) on an inclined plate (27). Also described is a method of fitting a plunger pump (1) for use under water.

Description

DEVICE AND METHOD OF PUMP FOR SUBMERSIBLE USE

The invention relates to a device for a piston pump for use under water, where a pump shaft, via a cylinder housing which is axially fixed to the pump shaft, is arranged to move a number of pistons between a first position and a second position in respective cylinder bores, and each of the pistons is connected to a piston shoe which is held in an inclined path of rotation. The invention also relates to a procedure for adapting a piston pump for use under water.

During operations related to petroleum extraction, pumps are often used to provide a hydraulic pressure for maneuvering equipment, injecting auxiliary chemicals into production structures, etc. Such pumps can be placed on a surface installation and be connected to a well or equipment placed on the seabed via hose and/or pipe connections. For various reasons, it is desirable to place pumps for this purpose on the seabed, particularly when petroleum extraction takes place in areas with great water depths. For pumps that must work with high ambient pressure, for example the water pressure at a depth of 3,000 meters and more, great demands are placed on the durability of, for example, pistons. Piston pumps that are built for surface use can only be used in moderate water depths for underwater applications due to the fact that a high differential pressure is formed on the piston during suction, which contributes to increased resistance to return of the piston. The dynamic resistance when the pistons return during suction is determined by the water depth, restrictions at the inlet to the cylinder bores and the piston speed, which in turn depends on the pump's rotation speed.

When a pump that must work under such conditions also works with media with little or no lubrication, for example aqueous liquids, and due to high installation costs the pump must be able to demonstrate a long service life, there are a number of requirements that commonly available pumps according to known technique does not satisfy.

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology, or at least to provide a useful alternative to known technology.

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The purpose is achieved by the features indicated in the description below and in the subsequent patent claims.

The invention provides a pump that is designed to withstand large axial forces during suction of a pump medium when used at great sea depths, i.e. at high ambient pressure, and with a long life for local hydraulic power generation with a water-based hydraulic fluid on a seabed-mounted application. Alternatively, the pump is suitable for pumping other media with poor lubrication, for example when injecting liquid into a production structure.

A suction side of the pump is in fluid communication with a pressure-compensated underwater reservoir for the medium to be pumped. The pump must withstand pumping a medium with little or no ability to lubricate the moving pump parts. This requires the selection of materials with low friction and high wear resistance, so that a long service life is also achieved when pumping media with little or no lubrication, for example water-based hydraulic fluid or filtered seawater for water hydraulics. Industrial ceramic materials are therefore preferably used in the pump's vital parts, for example in bearings, valve components, cylinder housings, pistons, piston shoes, etc.

The invention is defined by the independent patent claims. The independent claims define advantageous embodiments of the invention.

In a first aspect, the invention relates more specifically to a device for a piston pump for use under water, where a pump shaft, via a cylinder housing which is axially fixed to the pump shaft, is arranged to move a number of pistons between a first position and a second position in respective cylinder bores, and each of the pistons is connected to a piston shoe which is held firmly in an inclined rotational path, characterized in that the rotational path of the piston shoes and a sliding ring is arranged between a support ring and a sliding surface on an inclined plate.

A ball joint on an end portion of each piston can be attached to the respective piston shoe by means of a collared locking sleeve which engages with a locking groove around the piston shoe.

The piston shoe can be held in place in an opening in the slip ring.

The cylinder housing can rest against a valve plate which is provided with a first and a second slot, the first slot being in fluid communication with an inlet port and the second slot being in fluid communication with an outlet port, and is arranged to form a fluid flow connection between the piston and the inlet port, and in the pressure phase of the piston to form a fluid flow connection between the piston and the outlet port. The first slot may have a flow cross-section that is larger than the flow cross-section of the second slot.

In another aspect, the invention relates more specifically to a method for adapting a piston pump for use under water, where the pump shaft via a cylinder housing that is axially fixed on the shaft is arranged to move a number of pistons between a first position and a second position in cylinder bores , characterized in that the method includes the steps: attaching the pump's pistons to each piston shoe with a collared locking sleeve that encloses a ball joint on each piston, and allowing the locking sleeve to engage with a locking groove around the piston shoe;

to attach the piston shoes by means of a slip ring between a support ring and an inclined plate with a sliding surface.

The method may comprise the further step of:

to change the pump's delivery quantity at a given rpm by inserting an inclined plate with a different angle.

The construction enables a compact form of construction. The pump's delivery quantity is controlled by speed regulation of the motor. If you want the pump to have a different delivery quantity at a given speed, an inclined plate with a different angle is inserted, so that the stroke length of the pistons changes according to the preferred delivery quantity.

The device and the method according to the invention thus provide a pump which is suitable for pumping media with little or no lubricating ability at great ocean depths.

In what follows, an example of a preferred embodiment and method is described which is visualized in the accompanying drawings, where: Fig. 1 shows in perspective a pump according to the invention; Fig. 2 shows an axial section through the pump; Fig. 3 shows a cylinder housing in perspective; Fig. 4 shows on a larger scale a section from fig. 2; Fig. 5 shows on a smaller scale and in partially exploded perspective a pump seen obliquely from above; Fig. 6 shows a partially exploded perspective of a pump seen obliquely from below;

Fig. 7 shows a side view and an axial section of a piston with a piston shoe; and

Fig. 8 in perspective a valve plate with an inlet opening and an outlet opening.

In the drawings, the reference numeral 1 denotes a piston pump which comprises a known in and of itself cylindrical pump housing 2 with a coupling flange 3, an end cap 4 and a pump shaft 5 which is supported in a first bearing 6 in the center of the coupling flange 3 and a second bearing 7 in the center of the end cap 4 (see in particular figure 2). The first bearing 6 is held in place by a locking disc 8 which is screwed to the coupling flange 3.

A cylinder housing 9 (see in particular figure 3), preferably made of a ceramic material, surrounds a part of the pump shaft 5. A central hole 10 is provided with longitudinal grooves 10a which engage with corresponding grooves 5a (see figure 2) on the outside of the shaft 5 On the outside, the cylinder housing 9 is provided with a support ring 11, preferably made of metal. Inside the cylinder housing 9, a spring 13 is arranged which, at the inner end of the cylinder housing 9, rests against a first support ring 14a which engages with a groove 14b in the pump shaft 5 (see Figure 4). The spring 13 presses the cylinder housing 9 in the axial direction against a valve plate 15, preferably made of a ceramic material and which is attached to the inside of the end cap 4 by pushing against a ring 16 which rests against a second support ring 17a which engages with a internal groove 17b in the cylinder housing 9.

The cylinder housing 9 rotates with the pump shaft 5 and slides against the valve plate 15 which is provided with a first and a second slot 15a, 15b which are in fluid communication with respectively an inlet port 19 and an outlet port 18 in the end plate 4. The first slot 15a which is in fluid communication with the inlet port 19, has a larger current nine narrower cross-section than the second slot 15b which is in fluid communication with the outlet port 18.

The cylinder housing 9 is provided with a number of through cylinder bores 12 arranged in the cylinder housing 9's axial direction. A piston 20 is placed in each of the cylinder bores 12. Each piston 20 is provided with a ball joint 21 (see figure 7) which is attached to an assigned piston shoe 22 by means of a collared locking sleeve 23 which engages with a locking groove 24 around the piston shoe 22. The piston shoe 22 is held in place in an inner sliding ring 25 which is provided with openings for each piston shoe 22 and which rests against a support ring 26. The piston shoes 22 rest against an inclined plate 27 with a recessed ceramic sliding plate 28. The inclined plate 27 is attached to the inside of the coupling flange with bolts 29.

When the piston pump 1 is put into operation by rotating the pump shaft 5 using a drive device not shown, the cylinder housing 9 rotates with the pump shaft 5. The connection between the pistons 20 and the piston shoes 22 and the retention of the piston shoes 22 in the inclined sliding ring 25 generates an oscillating, axial movement of the pistons 20 so that a full pumping cycle is performed for each rotation of the pump shaft 5. In the suction phase of a piston 20, the respective cylinder bore 12 is in fluid communication with the inlet port 19 via the first slot 15a of the valve plate 15, and in the pressure phase of the piston 5 the respective cylinder bore 12 is in fluid communication with outlet port 18 via valve plate 15 second slot 15b.

Claims (7)

1. Device for a piston pump (1) for use under water, where a pump shaft (5), via a cylinder housing (9) which is axially fixed to the pump shaft (5), is arranged to move a number of pistons (20) between a first position and a second position in respective cylinder bores (12), and each of the pistons (20) is connected to a piston shoe (22) which is held firmly in an inclined rotational path, characterized in that the rotational path of the piston shoes (22) and a sliding ring (25) is arranged between a support ring (26) and a sliding surface (28) on an inclined plate (27). 2. Device according to claim 1, where a ball joint (21) on an end part of each piston (20) is attached to the respective piston shoe (22) by means of a collared locking sleeve (23), which engages with a locking groove (24) around the piston shoe (22). 3. Device according to claim 1, where the piston shoes (22) are held firmly in openings in the sliding ring (25). 4. Device according to claim 1, where the cylinder housing (9) rests against a valve plate (15) which is provided with a first and a second slot (15a, 15b), the first slot (15a) being in fluid communication with a inlet port (18) and the second slot (15b) are in fluid communication with an outlet port (19), and are arranged to form a fluid flow connection between the piston (20) and the inlet port (18) in the suction phase of a piston (20), and in the pressure phase of the piston (20) to form a fluid flow connection between the piston (20) and the outlet port (19). 5. Device according to claim 1, where the cylinder housing (9) rests against a valve plate (15) which is provided with a first and a second slot (15a, 15b), the first slot (15a) being in fluid communication with a inlet port (19) and the second slot (15b) are in fluid communication with an outlet port (18), and are arranged to form a fluid flow connection between the piston (20) and the inlet port (19) in the suction phase of a piston (20), and in the pressure phase of the piston (20) to form a fluid flow connection between the piston (20) and the outlet port (18), and where the first slot (15a) has a flow cross-section that is larger than the flow cross-section of the second slot (15b). 6. Procedure for adapting a piston pump (1) for use under water, where the pump shaft (5) via a cylinder housing (9) which is axially fixed on the shaft (5), is arranged to move a number of pistons (20) between a first position and a second position in cylinder bores (12), characterized in that the procedure includes the steps: attaching the pump's pistons (20) to each piston shoe (22) with a collared locking sleeve (23) that encloses a ball joint (21) on each piston (20), and allowing the locking sleeve (23) to engage with a locking groove (24) around the piston shoe (22); and to fasten the piston shoes (22) by means of a sliding ring (25) between a support ring (26) and an inclined plate (27) with a sliding surface (28). 7. Method according to claim 6, where the method includes the further step: changing the pump's (1) delivery quantity at a given rpm by inserting a slant plate (27) with a different angle.