This invention relates to apparatus for, and a method of, installing a transmission line such as an optical fibre telecommunications line. In the United Kingdom, the telecommunications network includes a trunk network which is substantially completely constituted by optical fibre, and a local access network which is substantially completely constituted by copper pairs. Flexibility in the copper access network is provided at two points en route to the customer; firstly, at street-side cabinets serving up to 600 lines; and secondly, at distribution points serving around 10-1 5 lines. Eventually, it is expected that the entire network, including the access network, will be constituted by fibre.

The ultimate goal is a fixed, resilient, transparent telecommunications infrastructure for the optical access network, with capacity for all foreseeable service requirements. One way of achieving this would be to create a fully- managed fibre network in the form of a thin, widespread overlay for the whole access topography as this would exploit the existing valuable access network infrastructure. Such a network could be equipped as needs arise, and thereby could result in capital expenditure savings, since the major part of the investment will be the provision of terminal equipment on a 'just in time' basis. It should also enable the rapid provision of extra lines to new or existing customers, and flexible provision or reconfiguration of telephony services.

In order to be completely future proof, the network should be single mode optical fibre, with no bandwidth limiting active electronics within the infrastructure. Consequently, only passive optical networks (PONs) which can offer this total transparency and complete freedom for upgrade, should be considered.

The most common passive optical network is the simplex single star, with point-to-point fibre for each transmit and receive path, from the exchange head end (HE) to the customer network terminating equipment (NTE). This network design has been used throughout the world and meets all the access criteria. It involves high fibre count cables, and unique electro-optic provision at HE and NTE for each customer. The resulting inherent cost can only be justified for large

business users, who generally also require the security of diverse routing, which increases the cost still further.

The advent of optical splitters and wavelength-flattened devices has enabled the concept of the PON to be taken one step further. These passive components allow the power transmitted from a single transmitter to be distributed amongst several customers, thereby reducing and sharing the capital investment.

The use of splitter based PON architecture thus reduces the cost of fibre deployment in the access network. When compared with point-to-point fibre, savings will result from: (i) reducing the number of fibres at the exchange and in the network; (ii) reducing the amount of terminal equipment at the exchange;

(iii) sharing the cost of equipment amongst a number of customers;

(iv) providing a thin, widespread, low cost, fibre infrastructure; and

(v) providing a high degree of flexibility, and allowing 'just in-time' equipment and service provision.

Additionally, PON architecture can be tailored to suit the existing infrastructure resources (duct and other civil works).

It will be apparent that upgrading the entire UK access network from copper to fibre will involve a major capital investment program. It is important, therefore, to minimise costs wherever possible. The specifications of our

International patent applications WO95/07475, WO95/07476, WO95/07477.

WO95/07478 & WO95/07486 describe a fibre management system which aims to reduce the cost of providing fibre from local exchanges to the network nodes

(equivalent to the distribution points of the copper access network) nearest the customers. The specifications of our International patent applications

GB95/00449 and GB95/00450 describe a way of minimising the cost of getting fibre into a customer's premises via a customer lead in (CL1) provided in an external wall of the premises. The present invention is concerned with minimising the cost of getting fibre from just outside a customer's premises to the nearest network node.

The present invention provides a method of installing a transmission line in the ground, the method comprising the steps of forming a tunnel in the ground using a mole constituted by a water-jetting head and piping for supplying

pressurised water to the head, and positioning the transmission line in the tunnel, wherein the head is guided along a pre-installed buried elongate member by manually pushing the piping thereby forming the tunnel adjacent to the elongate member. The pre-installed buried elongate member may be an underground service pipe (water or gas) or cable. Preferably, this member is a telecommunications line such as a twisted copper pair. The method of the invention thus permits the installation of a new telecommunications line using an old telecommunications as a guide, thereby providing a cost-effective way of installing the new telecommunications line from the curtilage to the CLI.

Advantageously, the transmission line is a ruggedised optical fibre which is rodded into the tunnel after the mole has been withdrawn.

Alternatively, the transmission line is an optical fibre transmission line which is propelled along the tunnel by fluid drag of gaseous medium passed through the tunnel, the optical fibre transmission line being installed in the tunnel after the mole has been withdrawn. In this case, a tubular pathway may be positioned within the tunnel prior to the propelling of the optical fibre transmission line, the optical fibre transmission line being propelled along the tubular pathway by fluid drag of said gaseous medium. The tubular pathway may be constituted by tubing which is connected to the moie at the head end thereof, the tubing being positioned in the tunnel by subsequently withdrawing the mole from the tunnel.

Preferably, the method further comprises the step of removing the head from the piping of the mole, connecting a second water-jetting head to the piping, attaching the tubing to the second head, and removing the mole from the tunnel.

The invention also provides a cutting head for a water-jetted mole, the cutting head comprising an elongate main body portion formed with a longitudinally-extending bore for supplying pressurised water to a deflection face formed within the main body portion, a guide member fixed to the main body portion in the region of the deflection face, the guide member being sized and shaped for engagement with a buried elongate guide, an axially-extended slot formed in the main body portion on the other side of the deflection face to the bore, the slot being aligned with the bore and extending to the free end of the main

body portion thereby defining a passage for producing a first, axially-directed water jet which, in use, cuts a tunnel along the side of the guide, and the deflection face being such as to deflect some of the water supplied along the bore so as to define a second, transversely-directed water jet which, in use, washes over the guide member.

Conveniently, deflection face is defined by a radial blind bore formed in the main body portion, the radial blind bore intersecting said first-mentioned bore.

Advantageously, the main body portion is provided with an externally- threaded extension portion at that end thereof remote from the axial slot. Preferably, the guide member is constituted by a guide ring, and one end of the guide ring is fixed to the main body portion, and the other end of the ring is detachablv fixed to the main body portion. This facilitates positioning of the guide ring over the buried elongate guide.

The invention will now be described in greater detail, by way of example, with reference to the accompanying drawings, in which:-

Figure 1 is a perspective view of the cutting head of a guided water-jetted mole constructed in accordance with the invention;

Figure 2 is an axial cross-section taken through the front portion of the cutting head of Figure 1 ; Figure 3 is a plan view of the cutting head front portion;

Figure 4 is a front elevation of the cutting head of Figure 1 ; and Figure 5 is an axial cross-section taken through the front portion of a modified form of cutting head.

Referring to the drawings, Figure 1 shows a cutting head H made of stainless steel. The cutting head H has a main body portion 1 and a screw- threaded shank 2. The front end of the main body portion 1 (that is to say that end remote from the shank 2) is shaped to define a tapered nose portion 1 a. The main body portion 1 is formed with an axial bore 3 (see Figure 2) which is contiguous with a bore (not shown) in the shank 2. The bore 3 terminates at a deflection face 4 formed in the main body portion 1 by a cylindrical, radial blind bore 5. An axial slot 6 extends forwardly of the bore 5, terminating at the free end of the tapered nose portion 1 a. The main body portion 1 is provided with a flexible guide ring 7 made from a multi-stranded, high tensile steel wire which is

surrounded by short tube sections which act as rollers. One end of the guide ring 7 is permanently fixed to the main body portion 1 , the other end being detachably fixed to the main body portion by means of a grub screw (not shown). The guide ring 7 is positioned just behind the deflection face 4. The cutting head H is used with a plurality of stainless steel tubes 8 (one of which is shown in Figure 1 ), each of which has an internally-threaded portion at one end and an externally-threaded portion at the other end. The tubes 8 each have a length of 2m, an external diameter of 10mm and an internal diameter of 6mm. A first of the tubes 8 can be fixed to the screw-threaded shank 2 of the cutting head H by means of its internally-threaded end portion. Subsequently, further tubes 8 can be added (in a manner described below) by interengagement of adjacent internally-threaded and externally-threaded end portions.

The mole described above can be used to tunnel through the earth to provide a route for the subsequent installation of a telecommunications line such an optical fibre line. In particular, the mole can be used to tunnel from the curtilage of a customer's premises to the customer lead in point provided in the wall of those premises.

In order to guide the mole from the curtilage to the CLI, use is made of any service cable or pipe already buried in the ground. Preferably, where there is an existing telecommunications line (i.e. a copper pair) already buried in the ground, this is used to guide the mole. In this case, the first step of the tunnelling orocess is to dig a small pit at the curtilage so as to expose the buried telecommunications line (drop cable). The guide ring 7 of the cutting head H is then positioned over the cable by releasing the grub screw, positioning the ring over the cable, and then re-applying the grub screw. A first stainless steel tube 8 is then threaded onto the shank 2 of the cutting head. The free end of the rod 8 is then connected to a Gerni 600p water lance (not shown) which is supplied with water at a pressure of 2350psi at a rate of between 17 and 1 8 litres per minute.

Pressurised water is then supplied to the cutting head H by pressing the trigger of the water lance. Pressurised water is then forced along the bore 3 and against the deflection face 4, resulting in the formation of two separate water jets J 1 and J2 (see Figure 2). The water jet J1 is directed generally along the axial slot 6 towards the tapered nose portion 1 a of the cutting head H. This jet J1 is

effective to cut a tunnel in the earth in the region of the guiding cable. The other jet J2 is directed upwardly towards the cable and the guide ring 7. This jet J2 forces pressurised water around the cable and the guide ring 7 to prevent earth and stones jamming between the guide ring and the cable, and so preventing the forward movement of the cutting head H. Once the water has been turned on, the operator pushes the tube 8 into the ground. As this occurs, the water jet J 1 tunnels into the earth thereby forming a bore adjacent to the guide cable. When the tube 8 has been advanced until the water lance is about to enter the pit, the water is turned off, the lance is unscrewed from the free end of tube 8, and a further tube 8 is threaded onto the first tube 8. The lance is then screwed onto the free end of this second tube 8, the water is turned on again, and the cutting head H is rodded further into the ground by the operator. The procedure is repeated until the cutting head is beneath the customer lead-in point in the wall of the customer's premises. A small pit is then dug at this point to reveal the cutting head H. The cutting head H is then removed from the first tube 8, the tubes 8 are withdrawn from the pit at the curtilage, and a ruggedised optical fibre cable is rodded into the tunnel from either end.

Alternatively, a modified form of cutting head H' (see Figure 5) is fixed to the internally-threaded portion of the first tube 8 by means of an externally threaded shank 1 2 formed at one end of a main body portion 1 1 . The main body portion 1 1 and the shank 1 2 are formed with a central blind bore (not shewn) tor feeding water to a number of water jets 1 3 (only one of which can be seen) formed in the main body portion. An extension 14 is formed on that side of the main body portion 1 1 remote from the shank 1 2, the extension being provided with an internally-threaded shank portion 1 5. In use, a tube clamp (not shown) formed with an externally threaded shank is screwed into the internally-threaded shank portion 1 5, and a blown fibre tube is fixed in the clamp. This tube is typically made of a polymer such as a high density polythene, and has an outer diameter of 8mm and an inner diameter of 3.5mm. The tube is preferably supplied from a coil. Pressurised water is then supplied to the cutting head H' by pressing the trigger of the water lance, and the line of tubes 8 and the cutting head H' are withdrawn from the tunnel by pulling from the pit at the curtilage. As the cutting head H' travels along the tunnel water escaping from the jets 1 3 is effective to

remove any earth or stone which might otherwise impede its passage. When the cutting head H' reaches the pit at the curtilage, the blown fibre tube is removed from its clamp, after which an optical fibre cable can be blown through the tube in the known manner. In some cases, it may be possible to replace the cutting head H' by a simple threaded member for fixing to the first tube 8 and for threading in a tube clamp.

It will be apparent that the method and apparatus described above could be modified. For example, in order to reduce the amount of effort needed to install the tubes 8, a wetting agent could be added to the water supplied to the lance. A suitable wetting agent, which should be bio-degradable in soil, is a Sub-soil Boring Fluid supplied by Enviro Chem.

It would also be possible to install ducting for housing a new transmission line at the same time as the mole cuts the tunnel. For example, lengths of plastics tubing could be pushed over the tubes 8 as the mole is rodded in, the lengths of tubing being glued together, as they are added, using plastics collars.

The method of the invention results in a time-saving of approximately 70% (when compared with standard open trench and back fill methods or those utilising pneumatic moles) in the upgrade of direct buried telecommunications line customer feeds. This assumes a mixture of grass, flower beds and paving that would be considered a typical front garden. The method requires the digging of only two small pits, one at either end of the feed, and this minimises re-instatement costs. At the same time, there is minimised disruption to areas that have public access and to the customer's property. Moreover, the method of the invention involves a single man, low skill operation, and so is cheap to carry out.

Although the method of the invention is intended primarily for the replacement of direct, in ground, customer drop, cables, scaled versions of the technique could be used to replace any of the other utility lead-ins, for example gas pipes, water pipes, electric cables etc. In addition to the customer premises to curtilage location, scaled versions of the technique could be used for replacement of directly buried cables, ducts and pipes throughout the network infrastructure of all the utilities. In particular, for telecommunications applications, in addition to the customer drop provision, the method of the invention could be used for the

replacement and upgrading of distribution cables in frontage "T" topologies, in the replacement of damaged directly buried cable throughout the network, and in the replacement of blocked lead-in ducts.