The present invention relates to a trench cutting apparatus and method of cutting a trench. In particular, but not exclusively, the present invention relates to an apparatus and method of cutting a trench, which is suitable for cutting a trench in both relatively hard ground and also relatively loose material or sandy soil.
The formation of trenches in the ground is a well-known requirement and is typically used for burying utility supply means, for example, oil, gas and water pipes, and electricity and telecommunication cables. In underwater environments, the cutting of a trench is often used for burial of pipes and cables and usually utilises specially constructed or adapted equipment configured for underwater conditions, for example the nature of the seabed. Herein “seabed” is used to refer to the bed of the sea or of a lake or even a river, unless otherwise specified.
A wide variety of cable laying and burial equipment is available and can be selected depending on the environment and specific needs (e.g. seabed conditions and burial depth). Various apparatus for constructing a trench and laying a cable or pipe are known in the art. These can include soil cutting devices in the form of ploughs, jetting apparatus, and chain cutters. Jetting is generally suitable for soft or loose soils, whilst mechanical cutting is generally suitable for hard or dense soils. The soil cutting device may be mounted on a vehicle that moves over the ground (e.g. the seabed) either under its own power or by external means. For example, the trench cutting vehicle might be towed by a tractor vehicle or by a ship at the surface of the sea.
When cutting a length of trench, particularly in the seabed, different soil and/or rock types are often encountered along the length of the trench. It is often useful to switch between different types of cutting device for cutting different soil and rock types. For example, a relatively hard rock may cut better using a chain cutter or other mechanical cutting tool, whilst a relatively sandy soil may be cut better using a jetting apparatus. In the jetting process, a combination of high flow and low pressure water jets may be used to fluidize and displace granular sediment, for example, and low flow and high pressure water jets may be used for cutting and transporting of clay lumps, for example. This process opens a channel into which the cable is allowed to sink.
Mechanical cutting may employ a cutting wheel or a cutting chain to cut a trench in generally compacted seabed or rock. The cable may be placed into the trench behind the trench cutting vehicle as the trench is cut. Following either of the jetting or mechanical cutting processes, the trench may be back filled to bury the cable.
Currently, when cutting different soil and rock types in a single trench, the trench cutting vehicle may be lifted from the sea bed and the cutting tool replaced with a different cutting tool before the trench cutting vehicle is redeployed to continue cutting. WO2015/032730A1 discloses a trenching vehicle in which a chain cutter may be replaced with a jetting device. However, such a system can cause problems with slack in the cable or pipeline since the cable is continually lifted and placed back down for the cutting tool replacement.
As the trench cutting vehicle 100 reaches sandy soil 106, as shown in
At this point, as shown in
It would be useful to provide a trench cutting apparatus that can more easily adapt to cut different types of rock or soil.
According to a first aspect of the present invention there is provided a trench cutting apparatus comprising:
Suitably, in the jet cutting mode the position of the cutting element is fixed relative to the central support element.
Suitably, in the jet cutting mode, each of the at least one jetting outlet is aligned with a respective opening in the cutting element such that fluid is ejected through the cutting element.
Suitably, the apparatus further comprises a measuring element to determine alignment of each of the at least one jetting outlet with the respective opening in the cutting element.
Suitably, the apparatus further comprises a controller configured to stop movement of the cutting element such that each of the at least one jetting outlet is aligned with the respective opening in the cutting element.
Suitably, the apparatus further comprises a stopper element for preventing movement of the cutting element in the jet cutting mode.
Suitably, the central support element comprises a plurality of jetting outlets.
Suitably, the at least one jetting outlet is located on a substantially forward facing surface of the central support element.
Suitably, the cutting element comprises a chain cutter and the central support element comprises a support arm.
Suitably, a plurality of jetting outlets are distributed substantially evenly along the length of the support arm on a forward facing surface thereof.
Suitably, the cutting element comprises a rock wheel or shearing drum and the central support element comprises a shaft.
Suitably, the apparatus further comprises a fluid supply inlet coupled to the central support element.
Suitably, the apparatus further comprises the pump configured to pump fluid from the fluid supply inlet, through the central support element and out through the at least one jetting outlet.
Suitably, the pump is configured to eject fluid from the at least one jetting outlet at a pressure of from 0.5 to 25 bar.
Suitably, the trench cutting apparatus is configured to activate the pump during the mechanical cutting mode to thereby eject fluid from the jetting outlets to clean or lubricate the cutting element.
According to a second aspect of the present invention, there is provided a trench cutting vehicle comprising the trench cutting apparatus according to the first aspect.
Suitably, the trench cutting vehicle further comprises a cable support element for supporting an elongate element above the ground distal from the cutting element. Suitably, the trench cutting vehicle further comprises a share and depressor element configured to guide the elongate element into a cut trench and prevent trench collapse prior to placement of the elongate element in the trench.
According to a third aspect of the present invention there is provided a method of cutting a trench comprising:
Suitably, the method further comprises fixing the position of the cutting element with respect to the central support element during the jet cutting mode. Suitably, the method further comprises aligning each of the at least one jetting outlets with a respective opening in the cutting element in the jet cutting mode such that fluid is ejected through the cutting element.
Apparatus arranged to implement a method in accordance with any preceding claim.
Certain embodiments of the invention provide an apparatus that can more easily switch between cutting of relatively hard rock or soil and relatively loose or sandy soil.
Certain embodiments provide a trenching apparatus in which problems with cable slack are reduced or mitigated.
Certain embodiments provide an apparatus that is easier and quicker to use with reduced time needed for tooling changes.
Certain embodiments provide the advantage that bend radius of a pipe or cable can be better controlled, especially during the jetting process.
Certain embodiments provide the advantage that the trench may be formed quicker than with previously known apparatus or methods.
Embodiments of the invention are further described hereinafter with reference to the accompanying drawings, in which:
In the drawings like reference numerals refer to like parts.
In this example, the central support element 202 is a support arm and the cutting element 204 is a chain cutter that is configured to be driven around the support arm. The support arm 202 includes one or more drive sprockets. In this example a drive sprocket 206 is located at a first end of the support arm 202 and a further sprocket 208 at a second end of the support arm 202 distal to the first end. In other examples, instead of a further sprocket 208, an idler (e.g. a wheel or pulley that guides the chain cutter 204 around the support arm) may be provided at the second end of the support arm 202. The drive sprocket 206 is connected to a drive element (e.g. a motor), which actuates rotation of the drive sprocket 206 to drive the chain cutter 204 around the support arm 202.
The chain cutter 204 includes a chain element 210 and a plurality of cutting heads 212 coupled to the chain element 210. The cutting heads 212 are configured to mechanically cut through ground or seabed material when the chain cutter 204 rotates about the support arm 202.
The central support element 202 includes at least one jetting outlet 214. In this example, a plurality of jetting outlets 214 are distributed along the length of the support arm 202. Turning to
As shown in
The chain element 210 also includes coupling links 304 (see
The trench cutting apparatus 200 can operate in both a mechanical cutting mode and a jet cutting mode. In the mechanical cutting mode, the cutting element 204 (in this example the chain cutter) is driven around the central support element 202 to cut material forward of the trench cutting apparatus 200. That is, as the cutting element 204 is driven around the central support element 202, the cutting element 204 cuts material in front of the trench cutting apparatus 200 in the direction of travel of the trench cutting apparatus 200. In the jet cutting mode, a pump (not shown) is activated to eject fluid from the jetting outlets 214. The trajectory of the ejected fluid (jets) is substantially forward of the trench cutting apparatus 200. The ejected fluid thereby fluidizes or cuts material forward of the trench cutting apparatus 200 and can assist in transporting displaced material away from the trench.
In some examples, one or more of the jetting outlets (e.g. in an upper portion of the central support element) may be positioned such that the direction of the jets have an upward component to assist in soil transportation. Similarly some of the jetting outlets (e.g. in a lower portion of the central support element) may be positioned such that the directions of the jets have a downward component. This can help to assist in fluidizing the bottom of the trench. At least some of the jetting outlets may be positioned such that the direction of the jets have a significant lateral component (i.e. forward of the device). This can help to ensure that the full face width of the trench is cut or fluidized.
As such, in both the mechanical cutting mode and the jet cutting mode, the trench cutting apparatus is configured to cut material forward of the apparatus (in front of the apparatus in the direction of travel). Thus, the trench cutting apparatus 200 is able to continually cut material forward of the apparatus to cut a continuous trench.
In the mechanical cutting mode, the jetting outlets are aptly inactive (i.e. do not eject any fluid) and the cutting element 204 is driven around the central support element 202. When switching to the jet cutting mode, the jetting outlets 214 are activated (i.e. fluid is ejected). A pump may control the ejection of the fluid from the jetting outlets 214 and may also control the pressure at which the fluid is ejected. For example, fluid may be ejected at a pressure between 0.5 bar and 25 bar, or more suitably between 0.5 bar and 16 bar. Aptly, the fluid may be ejected at a pressure between around 2 bar and 5 bar to most efficiently fluidize material.
As discussed above, the cutting element 204 may include openings 302 through which the fluid may be ejected. Suitably, in the jet cutting mode, the rotational speed of the cutting element 204 around the central support element 202 may be significantly reduced compared to the mechanical cutting speed or may be completely stopped relative to the central support element 202.
Aptly, during the jet cutting mode, the position of the cutting element 204 is fixed relative to the central support element 202. The cutting element 204 may aptly be aligned with the central support element 202 and the jetting outlets 214. The alignment may be such that the jetting outlets 214 each align with a respective opening 302 in the cutting element 204 such that fluid may be ejected through the cutting element 204 (see
Referring now to
As shown in
In order to determine alignment of the jetting outlets 214 with the respective openings 302 in the cutting element 204 in the jet cutting mode, a measuring element may be provided. The measuring element may be included in the motor, and may include a toothed wheel.
The toothed wheel includes a plurality of teeth about the circumference and can thereby detect rotational distances (and speed etc.) by a non-contact proximity sensor or an encoder, for example. The measuring element may determine the alignment of the jetting outlets and openings according to the rotational position of the toothed motor. Alternatively or additionally, the trench cutting apparatus may include a controller that is configured to stop movement of the cutting element 204 such that each of the jetting outlets 214 are aligned with a respective opening in the cutting element 204.
A stopper element (e.g. a mechanical stopper) may alternatively or additionally be provided to prevent movement of the cutting element in the jet cutting mode. For example, the stopper element may be configured to prevent rotation of one or both of the sprockets 206, 208 during the jet cutting mode. The mechanical stopper may include a mechanical location device, for example a block, to prevent rotation of the cutting element 204 by engaging one or more of the sprockets or the cutting element in an otherwise unengaged location.
The trench cutting apparatus also includes a fluid supply inlet 710. In this example, the fluid supply inlet is coupled to a side of the central support element 202. A pump may be provided to pump fluid from the fluid supply inlet 710 from the surrounding environment (e.g. the surrounding sea water) into the central support element 202 and out through the jetting outlets 214. As is shown by the dotted arrows in
Aptly, the central support element 202 and the fluid supply inlet 710 are configured to minimise the change in cross-section and flow as the fluid passes to the jetting outlets 214. This helps to avoid energy dissipation and allows for a more efficient device. As is shown most clearly in
The trench cutting apparatus 200 is coupled to the main body portion 802. As shown in
As shown in
The trench cutting vehicle 800 also includes a cable support element 814 configured to support a cable above the ground distal from the trench cutting apparatus 200. The cable support element 814 is coupled to the main body portion 802 and is arranged to guide the cable over the trench cutting apparatus 200 and to the depressor 816. The depressor 816 can then guide the cable downwards and into the trench.
Because the trench cutting apparatus can operate in both a mechanical cutting mode and a jet cutting mode, there is no requirement to lift the trench cutting vehicle from the seabed to swap between mechanical and jet cutting modes. Thus a cable can remain supported in the cable support element 814 throughout the whole of the trench cutting operation. As such, the required cable slack can be established at the beginning of the trench cutting operation and carried by the trench cutting vehicle 800 along the whole length of the trench.
At 1102 the method includes operating the trench cutting apparatus in at least one of the mechanical cutting mode and the jet cutting mode. In the mechanical cutting mode the cutting element is driven around the central support element to cut material forward of the trench cutting apparatus. In the jet cutting mode a pump is activated to eject fluid from the at least one jetting outlet to fluidize or cut material forward of the trench cutting apparatus. Various modifications to the detailed designs as described above are possible. For example, although the cutting element has been described above as a chain cutter, other cutting elements may also be suitable.
The shaft 1002 includes jetting outlets 1014 on a substantially forward facing portion of the surface of the shaft. Similarly to the chain cutter described above, the rock wheel may include openings 1016 that can align with the jetting outlets 1014 in the jet cutting mode such that fluid may be ejected from the jetting outlets 1014 and through the openings 1016 in the rock wheel 1004.
The trench cutting apparatus includes a fluid inlet 1020 through which fluid is drawn into the shaft 1002. In this particular example, the shaft 1002 includes a fluid reservoir 1022 into which the fluid is drawn. The fluid may be drawn directly from surrounding seawater via a suitable pumping device or alternatively the fluid inlet may be connected to a remote fluid supply.
During the jetting mode, a pump is activated to eject fluid from the jetting outlets. The pump may also draw the fluid into the shaft 1002 via the fluid inlet 1020. The trench cutting apparatus 1000 may operate in the jet cutting mode and the mechanical cutting mode in a similar manner to the trench cutting apparatus 200 described above.
In another example, the cutting element may be a shearing drum. The shearing drum may operate similarly to the rock wheel described above, with the main difference being that the shearing drum is driven at the centre of the shaft rather than at the circumference. In some examples, the trench cutting apparatus may be configured to activate the pump during the mechanical cutting mode to thereby eject fluid from the jetting outlets to clean or lubricate the cutting element, for example the chain cutter of
The trench cutting apparatus described above may be provided coupled to a trench cutting vehicle as shown in
Although in the example described above a particular chain element configuration is shown, it will be appreciated that other chain element configurations may also be suitable. Aptly the chain element is configured such that the cutting elements may be coupled to the chain element, though in other examples the cutting elements may be integral with the chain element. The chain element is aptly configured to have at least the same number of openings as jetting outlets so that each opening may align with a corresponding jetting outlet during the jet cutting mode.
Although the example described above includes a drive sprocket and a further sprocket, in other examples multiple drive sprockets and/or multiple further sprockets may be provided. For example, two drive sprockets may be provided with one drive sprocket located at either side of the chain element. Similarly, two further sprockets may be provided with one further sprocket located at either side of the chain element. In other examples, three or more drive sprockets and/or further sprockets may be provided.
Aptly, the trench cutting apparatus includes a plurality of jetting outlets. The jetting outlets are suitably distributed substantially evenly on a forward facing surface of the central support element. Suitably, a line of jetting elements are provided along either side of the central support element, e.g. along either side of the forward facing surface of the support arm.
In other examples, the trench cutting apparatus may include only a single jetting outlet. For example, the jetting outlet may be an elongate outlet extending along a surface of the central support element. In this way, an elongate jet of fluid may be ejected from the jetting outlet, to fluidize or cut material forward of the trench cutting apparatus.
The pump described above may form part of the jet cutting apparatus or alternatively may be provided externally to the jet cutting apparatus (e.g. as part of a trench cutting vehicle). Although in the examples described above, the cutting element is described as aptly fixed relative to the central support element during the jet cutting mode, it will be appreciated that in some examples the cutting element may continue to move relative to the central support element during the jet cutting mode. For example, the speed of the cutting element relative to the jet cutting mode may be reduced compared to the mechanical cutting mode such that a combined jet cutting and mechanical cutting mode is achieved.
Although a cable or pipe may be specifically referred to herein, it will be appreciated that the apparatus described above may be suitable for laying any elongate element in a trench.
With the above described arrangement, a cable may be supported throughout the entire trench cutting process. As such, the minimum bend radius of the cable can be controlled, thereby reducing risk of damage to the cable during the trenching process.
By supporting the cable throughout the entire trenching process, the cable slack can be established at the beginning of the process and carried along the length of the trench. Since the cable does not need to be released throughout the trenching process for tooling changes, the slack can be better controlled, thereby reducing risk of over tensioning the cable.
The above described trench cutting apparatus can easily switch between a mechanical cutting mode and a jet cutting mode as necessary. Thus, the most effective cutting mode can be activated according to the material to be cut. This can thus reduce wear on the cutting apparatus, and particularly the cutting element when cutting relatively loose or sandy material, or material of relatively low cohesive strength.
In the above described arrangement, problems with trench infill between a mechanical cutter and a jetting tool is eliminated since the two tools are combined into a single trench cutting apparatus. This helps reduce the risk of soil or rock falling into the trench before the cable is positioned in the trench. Therefore the chances of having to re-lay portions of the cable that are not deep enough within the trench are reduced. Thus, time taken for the overall trenching process can be significantly reduced.
With the above described systems, cable, pipe or other elongate element or product can be placed at the bottom of a trench in a relatively uniform and level position. This can reduce strain on the product, which may thereby improve the serviceable lifetime of the product.
It will be clear to a person skilled in the art that features described in relation to any of the embodiments described above can be applicable interchangeably between the different embodiments. The embodiments described above are examples to illustrate various features of the invention.
Throughout the description and claims of this specification, the words “comprise” and “contain” and variations of them mean “including but not limited to”, and they are not intended to (and do not) exclude other moieties, additives, components, integers or steps. Throughout the description and claims of this specification, the singular encompasses the plural unless the context otherwise requires. In particular, where the indefinite article is used, the specification is to be understood as contemplating plurality as well as singularity, unless the context requires otherwise.
Features, integers, characteristics, compounds, chemical moieties or groups described in conjunction with a particular aspect, embodiment or example of the invention are to be understood to be applicable to any other aspect, embodiment or example described herein unless incompatible therewith. All of the features disclosed in this specification (including any accompanying claims, abstract and drawings), and/or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations where at least some of such features and/or steps are mutually exclusive. The invention is not restricted to the details of any foregoing embodiments. The invention extends to any novel one, or any novel combination, of the features disclosed in this specification (including any accompanying claims, abstract and drawings), or to any novel one, or any novel combination, of the steps of any method or process so disclosed.
The reader's attention is directed to all papers and documents which are filed concurrently with or previous to this specification in connection with this application and which are open to public inspection with this specification, and the contents of all such papers and documents are incorporated herein by reference.
Number | Date | Country | Kind |
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2019360 | Jul 2017 | NL | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/070008 | 7/24/2018 | WO | 00 |