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The invention to which this application relates is to a method and apparatus which can be used in the formation of tunnels and in particular, tunnels which can be used as a means for passenger transport therealong in addition, or alternatively, to existing transport means.
In certain cases, the existing transport means may be kept in operation whilst the new route is created and when the new route is functional the existing transport means is closed. Alternatively a new route is created in accordance with the invention to be used in addition to the existing transport route, or the new route may in fact be a completely new facility and created independently of and without any reference to any existing transport routes.
Increasingly, there is a demand to look more closely at the transport routes which are used for train tracks and roads and the need to have these transport routes above, or on, the surface. This demand is particularly relevant in conurbations where, firstly, the provision of the transport route on or above the surface, causes disruption in terms of noise and pollution to residents who happen to be living close by and, secondly, the transport routes take up valuable land which could be more profitably used for other purposes.
It is known to be able to provide tunnels to allow at least a part of the transport route to be located underground and thereby make the space on the surface available for other uses. However, the use of conventional tunneling techniques in which the tunnels are bored through the rock and soil to form the new, tunneled, transport route, is expensive and is required to be formed at the depth of, typically, 20 to 30 meters under the surface. The need to provide the tunnels at that depth under the surface, does, in turn, mean that the access routes to and from the tunnel from the surface, need to pass at a pre-determined steepness of slope. However, due to the depth of the known tunneling techniques, this means that the access routes themselves need to be relatively long which, in turn, means that a significant amount of space is required to be provided at each end of the tunneled portion. This adds significant further expense to the project and also, in certain instances, means the project cannot practically achieved due to the required space at each end for the access routes.
It is also known to provide underpasses which typically comprise a relatively short section of tunnel which allow a transport route to pass through the underpass and normally transversely to the transport route which is located on the surface. The purpose of these underpasses is to allow different transport routes at different levels to cross while minimising the disruption to the existing transport route while the underpass is formed thereby allowing grade separation.
It is therefore an aim of the present invention to provide a means of forming a tunnel to allow a transport route to pass therealong whilst, at the same time, minimising any disruption to any existing transport routes, minimising environmental and social surface disruption, and also minimising the amount of space which is required to be used when forming the tunnel and to allow subsequent access to and from the same. At the same time it is imperative that the tunnel which is formed has the structural strength to have the required relatively long lifespan, once formed.
In a first aspect of the invention there is provided a method of forming a tunnel structure, said method comprising the steps of forming at least two spaced apart access tunnels along a length, forming at least one guide surface along each of the access tunnels, introducing a plurality of units from at least one end of the said length and successively sliding the said units along the said at least one guide surface of said access tunnels, said units successively introduced and moved along a linear path as the material in which the tunnel is to be formed is excavated in advance of the leading one of the said units with respect to the direction of movement of the units, until the required length of tunnel is formed and wherein the path along which the tunnel is formed is located under or adjacent to an existing transport route.
Typically, the existing transport route can continue to be used during at least the majority of time of forming the said tunnel.
In one embodiment, the existing transport route can be retained in use following the formation of said tunnel or, once the tunnel is formed, the transport route can be decommissioned such that the transport route passes along the tunnel which has been formed and the surface above the tunnel can be used for other purposes.
In one embodiment, the tunnel is formed underneath the said existing transport route or to a side of the existing transport route.
In one embodiment of the invention, the units are formed to provide at least the roof section and the said access tunnels are positioned to form at least part of the side walls of the tunnels.
In one embodiment, prior to moving the units along the surfaces of the access tunnels are plurality of piles are formed downwardly from the access tunnels and along the said access tunnels. Typically therefore the main tunnel is formed by the said units, access tunnels and piles.
In one embodiment, the main tunnel is formed with at least one intermediate wall or walls which are substantially parallel to the side walls and which can be used as a barrier between, for example, respective lanes and/or tracks formed along the tunnel. Alternatively first and second tunnels can be formed to run parallel.
The provision of the tunnel in this form means that the tunnel can be formed at a substantially reduced depth from the surface such as, for example, between 2 and 10 meters from surface. As a result of this, the depth in which the access roads are required to pass from the surface to the entrance to the tunnel is substantially reduced and so the overall length of the construction which is required in order to form the tunnel and access roads is considerably reduced with respect to the prior art method and system and which in turn means that there is a practical possibility of providing the tunnel structure whereas previously, using conventional construction techniques, space and/or size constraints means that the same is not possible.
Typically, a shielded or enclosed area is provided in advance of the leading unit and within which excavation works occur in order to form the space in the soil into which the units can be moved.
Typically, the units are moved into position successively, by jacking apparatus which is provided at the end from which the tunnel is formed and which progressively move the units into position.
Typically, the access tunnel surfaces along which the units are slid are provided as tracks along which the units can be slid. The access tunnels are initially formed in and the tracks are then prepared in the same for the receipt of the units therealong.
In one embodiment, the units are pre-cast and delivered to the site of use for introduction to form the tunnel or, alternatively, the said units are formed on site.
In either embodiment, the units are typically formed from concrete which is suitable re-enforced to form the structural requirements of the tunnel.
In a further aspect of the invention, there is provided a tunnel including a plurality of units, at least two spaced access tunnels including a track along which successive units are slide into position and supported thereby, wherein said units and access tunnels, in combination, form at least part of the side walls and roof of the tunnel and a plurality of piles depend downwardly from, and are spaced along, the access tunnels and said tunnel is formed in parallel with an existing transport route so as to provide a transport route therealong in addition, or alternatively, to the existing transport route.
Typically a portion or portions of the existing transport route at least at one end of the tunnel are used as a means for approach to access the said end of the tunnel.
Thus, in accordance with the invention, there is provided a method and apparatus for the formation of a tunnel structure at a relatively shallow depth from the surface and to allow the tunnel which is formed, to be used as a replacement or additional transport route to an existing transport route which is formed on the surface. The ability to form the tunnel in parallel with the existing transport route means, for example, that the existing transport route can be used as a means for approach to access the ends of the tunnel once the same is formed, with minimum disruption.
Specific embodiments of the invention are now defined with respect to the accompanying drawings wherein;
Referring firstly to
The present invention allows the transport routes to continue to be provided, or indeed have an increased capacity, whilst making the previously required surface area available for other uses and does so whilst having no, or relatively minimal, impact on the continued use of the existing transport route whilst the new transport route is formed.
The initial steps by which the transport route can be formed in accordance with the invention are illustrated in
Once the access tunnels have been formed and before or after the piles have been completed, the access tunnels are prepared for the movement of units therealong and this preparation includes the formation of guide surfaces such as slide tracks 17 along the length thereof. The next stage is for part of the access tunnels to be removed, as illustrated by the hatched portion 19 illustrated in
The structure 20 is formed from a series of units 22 which are successively moved along the slide tracks 17 formed in each exposed access tunnel 11, 13. In this embodiment the units each comprise side wall portions 26, 28, and a roof section 30 which, in conjunction with remaining portion of the access tunnel and pilings 15 define the tunnel cavity 34 along which the new transport route 36, such as the new road will pass.
In order to be able to advance the units 22, then, as shown in
As the tunnel structure is formed in the manner described, the tunnel has its own integral strength and therefore can be formed and positioned at a significantly shallower distance from the surface 4 than when using conventional tunnel boring techniques. This in turn means that the distance 18 which has to be dealt with by access roads down to and up from tunnel to the surface 4 can be significantly shorter in length and thereby reduce the amount of land which is required to be provided in order to form the tunnel structure.
In
The tunnels are formed under existing transport routes 2 and
In certain cases the tunnel formed in accordance with the invention can be used in conjunction with open cut sections so that along the length of at least a portion of the road there are provided tunneled sections and open cut sections, with new road being under the surface and not visible from the surface.
Number | Date | Country | Kind |
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1422937.1 | Dec 2014 | GB | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/GB2015/054108 | 12/22/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2016/102946 | 6/30/2016 | WO | A |
Number | Name | Date | Kind |
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6640505 | Heierli | Nov 2003 | B1 |
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20140090191 | Aston | Apr 2014 | A1 |
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20160090831 | Malcolm | Mar 2016 | A1 |
Number | Date | Country |
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2014114941 | Jul 2014 | WO |
Number | Date | Country | |
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20170342834 A1 | Nov 2017 | US |