SE1800037A1 - Method to Build Fiber-to-Home (FTTH) Networks - Google Patents

Abstract

Method for building access networks and/or distribution networks, wherein said method comprises the steps:- designing a network layout for said distribution network and/or said access network; wherein said network layout prescribes the placement of at least one pipe/cable (2,3) in at least one main microditch (7); said network layout further prescribes at least one joint point (F) and/or at least one branch to at least one final destination from said at least one main microditch (7);- sawing a microditch (1 or 7) in said area, with a machine (8) comprising a saw blade (14) and a stabilization device (13);- placement of said at least one pipe/cable (2,3) in said microditch (1 or 7) by means of control means (17) in said stabilization device (13);- successive placement of each of said at least one pipe/cable (2,3) to its final destination via said branches from said main micro-ditch (7)- backfilling and possible compaction of said micro-ditch (1 or 7)- sealing of said micro-ditch (1 or 7 )

Description

TECHNICAL FIELD The present invention relates to a method for building a distribution network and / or access network for Fiber-Till-Hemmet FTTH by sawing the rriikrodiken and laying of special pipes / cables. a method according to claim 1.

Background of the invention The expansion of fiber optic communication networks in residential areas is hindered by high costs for excavation and restoration of the road surface, such as asphalt or concrete. A typical connection in a residential area costs about EURO 3000 excluding VAT and therefore many homeowners are hesitant to make such investment. This in turn means that the degree of connection becomes low when a residential area is built, which further increases the cost of connection. The reason for this is that the cost of the backbone network is more or less independent of the degree of connection and a low degree of connection means that fewer property owners have to share the total cost of the backbone network.

Alternatively, connecting the houses through green areas / plots of land between properties in a residential area is in most cases not possible. With all certainty, the costs would be significantly lower because it would even be possible to plow down hoses / pipes for fi bakgbm but dam possess tm you probably if most came uaagaam rar properties with people who do not want to join. Restoring flower beds, shrubs and thread can also be very costly. Finally, it would probably be a huge task to arrange permission from all the property owners involved.

The present application describes a new method for making micro-ditches and laying pipes / cables in the micro-ditch, which is called Micro Trenching Technology (MTF). In this respect, there is a need in the art for a device that can be used in conjunction with the new method and / or improves said new method.

SUMMARY OF THE INVENTION An object of the invention is to provide a method for sawing micro-ditches and laying pipes / communication cables which completely or partially solve problems and disadvantages of known technology. Another object of the invention is to provide a machine which improves the laying of pipes / cables (eg communication cables) in the micro-ditch so that the cost can be reduced and time saved.

The above-mentioned object is achieved with a machine arranged for sawing the micro-ditch and laying pipes / cables in the milnodiken, said machine comprising a saw-blade device for sawing a micro-ditch in an area; wherein said machine further comprises stabilizing device arranged for Stabilizing the walls of said micro-ditch when laying pipes / cables in said micro-ditch, said stabilizing device being placed immediately on said saw blade in said micro-ditch and said stabilizing device comprising guide means for guiding the at least one pipe rod.

Embodiments of the machine according to the invention are those specified in the appended dependent patent claims and are described in the following detailed description.

A machine according to the present invention makes it possible to saw the micro-ditch and automatically place pipes / cables in the same in an efficient manner, which saves money and money. In particular, the invention provides a solution with which pipes / cables can be placed in a controlled and predetermined manner and at high speed.

Other advantages and applications of the present invention will become apparent from the following detailed description of the invention.

Brief Description of the Figures The accompanying figures are intended to clarify and explain the present invention, in which: - Figure 1 shows a flow chart of MTT; - Figure 2 shows a flow chart of an embodiment of MTT; Figures 3a and 3b schematically show a cross section of a street area with a micro ditch; Figure 4 schematically shows the cross-section of Figure 3, the micro-ditch being backfilled with a filling material, such as sand, and sealed with two sealing layers; Figure 5 shows a typical layout of a home-to-home network; Figure 6 shows how branches to individual properties are sawn from a main micro-ditch; Figure 7 shows branching to individual properties in case controlled drilling is used instead of sawing; Figure 8 shows a sawing machine with its saw blade / saw blade and a stabilizing device for laying pipes / cables placed directly behind the Saw Lens; Figure 9 shows the sawing machine where the stabilizing device is arranged for the simultaneous laying of a number of tubes / cables at the same time as the order of the hoses / cables is maintained in the micro-ditch; Figure 10 shows in detail where the top pipe / cable should be cut for the access pipe / cable to be given sufficient length to reach its and - Figures 11-13 show further embodiments of the stabilizing device (the channels are only indicated in figures 11-13 and should therefore no real representations are seen) Detailed description of the invention To achieve the purposes described above, a machine for sawing and laying pipes / cables is provided. The arms have realized the need for the laying of pipes / cables before the walls of the micro ditch collapse and before stones (or gravel / soil) and especially stones larger than the width of the ditch wedge into the sides of the micro ditch and prevent installation of pipes / cables all the way down to the bottom of the micro ditch. By achieving this, time (and money) is saved because the installation can be carried out without unnecessary interruptions. For this reason, the present machine is arranged for sawing in an area. Therefore, the machine includes a saw blade, preferably circular, for sawing the micro-dies ("micro uenches"). The sawn microdics are arranged to receive pipes / cables, which means that the sawn microdics have been given suitable dimensions.

The machine also comprises a stabilizing device arranged to stabilize micro-dike walls when laying pipes / cables and for this reason the stabilizing device is placed immediately after the saw blade in the sawn micro-dike so that the walls are stabilized until pipes / cables have been laid / installed by means of control means. the stabilizer.

For Stabilization of the walls of the micro-ditches, the stabilizing device consists of suitable stabilizing elements such as suitable side elements which are arranged to "hold up" the walls until the pipes / cables have been installed in the micro-ditch. It is important that the stabilizing device is placed immediately behind the saw blade so that the ditch that is sawn with the saw blade is stabilized immediately after they have been sawn so that it does not collapse or rocks or other objects fall into the ditch before pipes / cables are laid. Therefore, according to one embodiment of the invention, the maximum permissible distance between the saw blade and the stabilizing device is greater than 0 mm but less than 10 mm. The dimension of the stabilizing device depends on the size of the pipes / cables, the number of pipes to be laid at the same time and the depth of the installation in the trench. However, the width of the hose stabilizing device should be slightly smaller than the width of the saw blade.

Furthermore, in order to obtain controlled and automatic laying of pipes / cables, the device also has control means which guide the pipes / cables down into the ditch in a controlled and orderly manner. The combination of stabilization and control has been shown to reduce cost and time in an efficient manner. and installation can be carried out simultaneously. The guide means are arranged on the stabilizing device and therefore the invention enables pipes / cables to be placed in the sawn micrearth while the stabilizing device is being stabilized. Pipes / cables can thus be laid with high precision (eg at right height in the micro ditch) because the ditch is "clean" as long as the ditch is stabilized by the device. The stabilization device can be made of any suitable strong material so that the ditches can be stabilized. The material should suitably be rigid, tough and hard but still fl visible to withstand stresses during operation. The attachment of the stabilizing device to the milling machine must have a certain fl flexibility to prevent damage if the stabilizing device gets stuck. Steel or steel alloys are suitable because they can be given the right properties when alloying with other metals such as platinum and magnesium. As there is a limited space in the sawn micro-product, the walls of the stabilizer must be as solid as possible to handle passing pipes / cables, but still have the properties described above. Steel alloys with a hardness corresponding to 400 - 700 Brinell have proven to be suitable for these applications. It has also been found that the stabilizing device can be manufactured as a carbon monoxide. Parts of the stabilizing device can be removed separately before mounting a According to an embodiment of the invention, the stabilizing device has an input and a single output for pipes / cables, where the input and the output m 'are connected to the control means. Preferably, the control means are channels through which the pipes / cables are guided through the stabilizing device. During operation the entrance is suitably arranged above ground level and vertically or near vertically while the outlet is below ground level in the milcrodike and horizontally or near horizontally arranged to avoid wear on the pipes / cables. Therefore, the minimum distance (ground level) between the outlet of the stabilizer and the saw blade is slightly longer than the minimum recommended bending radius of the pipes / cables to be installed, which means that the minimum distance depends on the minimum recommended bending radius of the pipes / cables. This usually means between 100 mm and 500 mm measured at ground level, but other distances are possible. In addition, the input, the output and the control means can together be detachably arranged on the stabilizing device, e.g. as a detachable cassette. By fastening the means in a detachable cassette, the installation time is shortened in some cases or because the time-consuming task of plugging many pipes / cables into their respective ducts can be avoided.

In addition, the inventors have realized that the effective depth of the stabilizer in the microdickets should be up to 50 mm less than the effective depth for the saw according to the embodiment. The difference in depth between the saw blade and the stabilization device, during operation, determines how quickly the ground level can be allowed to change (i.e. go down). The saw blade must have sawn the trench so deep that the stabilizing device does not touch the bottom of the sawn trench to avoid the stabilizing device getting stuck in the ground. This eliminates unnecessary forces on the stabilizer and the risk of it being destroyed. This could occur when the local level becomes rapidly lower.

In addition, according to yet another embodiment of the invention, the stabilizing device and the saw blade have been arranged so that they can be raised and lowered independently of each other. This is an advantage when, for example, the saw blade needs to be replaced due to wear or if another type of saw blade is required (Lex. One type for asphalt and another for concrete). Furthermore, the stabilizing device needs to be replaced and then this can easily be done if the two parts can be raised and lowered independently of each other. In addition, during shorter interruptions in the sawing process, the saw blade is raised but the stabilizing device must remain in the micro ditch as the need for the ditch remains. However, the stabilizing device and the saw blade can be further arranged so that both parts together can be loosened and lowered to avoid damage, e.g. subterranean infrastructure is found.

The stabilizing device is suitably mounted as a separate unit on the sawing machine by means of a number of movable shafts for raising and lowering. The movable shafts can be driven by a motor specially designed for this purpose. The sawing machine can also be equipped with fast fastening devices and drive devices for both the stabilizing device drive and the saw blade on the left and right side (in the sawing direction). This means that both the left or right side of the machine can be used for sawing and laying pipes / cables, which may be necessary due to obstructive infrastructure, traffic situation in the area, etc.

Figure 9 shows an embodiment of a machine according to the invention. The stabilizing device has a front part and a rear part, where the front part is mounted immediately behind the saw blade. It is also shown that the front part of the stabilizing device has a shape which is grain-complementary to the shape of the saw blade, which in this case is circular. In other words, in this case the upper part of the stabilizing device has a concave circular shape, with or almost the same radius as the saw blade and is mounted as close to the saw blade as possible, and at a distance less than 10 mm from the saw blade. The reason that the part of the stabilizer that is underground must be placed as close to the saw blade as possible is to make it impossible for soil, stones or other objects to collapse to the bottom of the ditch or wedge between the sides of the ditch. In this embodiment, the guide means are formed as channels within the stabilizing device. The channels are illustrated with dashed lines in the figures. Furthermore, the rear part of the stabilizing device, where the output of the control means is located, can have preferred shapes. A shape is substantially parallel to the complementary shape described above. Another shape is substantially opposite to the complementary shape and the third embodiment forms a shape which is substantially diagonal to the bottom and up to the top of the rear portion in These embodiments are shown in Figures 11-13. It should also be noted that the input, output and channels are located on the rear part of the stabilizing device in this embodiment. The stabilizing device may also have a wedge-shaped SP in (SPßtsigt) cross-section in the front in fi amâtrikming.

Preferably, as mentioned above, the stabilizing device should have a maximum width in cross section which is the same or slightly smaller than the width of the saw blade. astsågade milcrodiket.

Another important aspect of the invention is that with the use of control means a mutual order of the number of pipes / cables can be preserved when they are placed in the sawn micro-ditch. This is very important as more than one pipe is placed at the same time. In an installation scenario, a pipe / cable is cut in front of a special property at a special distance after the property. It is important that this pipe / cable is separated from the pipes / cables among the top pipes / cables in the amount of pipes / cables that are found in the ditch so that it can be easily found. The pipe / cable must be cut before the stabilizer. Therefore, it is important to know which of all the pipes / cables going into the stabilization device comes out at the top of the ditch. In addition, since the color of the pipe / table for a particular property is determined in advance, the pipes / cables must be arranged so that the pipe / cable with the correct color comes out at the top, cut to the correct length when the particular property has been passed.

A method that makes it possible to lay a number of pipes / cables at the same time has a large commercial value because the installation process can be carried out much faster than has previously been possible in the field of technology. For this reason, according to this embodiment of the invention, the stabilizing device has a number of guide means where each of the means guides one or a number of pipes / cables down into the ditch. For example, the device may comprise a number of channels so arranged that a known order of the tubes / cables is maintained, which means that an order of the tubes / cables out of the stabilizing device is known from the order into the stabilizing device, and consequently the order into and out of the stabilizing device is related to each other and known. This can be achieved by a "one-to-one relationship" between the input and the output of the device, which means that they do not cross each other. The arrangement of pipes / cables must be arranged so that it is one of the upper pipes / cables among the number of pipes / cables in the ditch that is always the one to be branched by the next destination. Therefore, the pipe / cable entering the lowest (rear) inlet, including the top pipes / cables out of the outlet, and the pipe / cable entering the top (front) entrance must be among the lower ones out of the outlet. . As shown in Figures 6 and 7, branch branches from the main trench are sawn before the main trench is sawn or it is also that the main trench has been sawn. The order in which the ditches are to be sawn can be determined so that the most efficient fl fate is obtained during installation. Each branched trench runs from the main trench to the final destination for a specific pipe / cable. When the main trench has been sawn and the pipes / cables have been installed, the top pipe / cable is created (before it is inserted into the stabilizer) at a special distance behind the location of the respective branch trench so that this pipe / cable can be lifted from the main trench and inserted into the branch trench to its final destination. 10. The pipe / cable is cut correctly, it has a length that is sufficient up to fi am until the final destination needs to be spliced. In this way, one by one the branches / cables to each passing property are branched through the ditches.

Depending on the width of the ditch and the size of the pipes / cables, one or more pipes / cables can be placed side by side at the top of the main ditch. It is important that the pipe / cable that is in turn branched to its final destination is always found among the top ones. In order to achieve this connection with the main ditch being sawn and a number of pipes / cables being laid, the pipe / cable that will become one of the top pipes / cables in the ditch and what is to be branched to the dam-specific destination must be cut at a predetermined distance or the corresponding branch trench has been passed so that the pipe / cable can then be lifted up and laid over the branch trench to its final destination. The pipe / cable must be cut after the site corresponding to the branch trench has been passed with a certain minimum distance so that the length of the pipe / cable is long enough without having to be spliced when it is lighted from the main trench over the branch trench and up to the final destination.

If the stabilizing device (formerly called "plow") is designed with individual channels for the pipes / cables or has individual channels that each have room for a number of '10 pipes / cables, it is easy to identify which pipe / cable will be found at the top idiket and thus also which pipe / cable is to be cut before entering the ismbiiisefingmofariingen. Example) of such a pipe fitting is shown in Fig. 9. The stabilizing device according to this embodiment has an inlet for pipe / cable and a single outlet for pipe / cable which are connected to each other by means of a number of channels as control means (illustrated by dashed lines) for the pipes / cables. According to an embodiment of the invention, the output of the stabilizing device comprises a “matrixWdel (or vector) so arranged that the channels ü are arranged in a matrix with n rows and m columns and can thus separate tubes / cables in a controlled manner horizontally and vertically when placed in the saw node node.

In summary, one of the (currently) top pipes / cables which is intended for a certain end destination is cut one by one at a certain minimum distance or each branch and then this pipe / cable is removed from the main ditch and transferred to the branch ditch fi am to its final destination.

Furthermore, the sawing machine may comprise at least one drum arranged to hold the pipes / cables before they are placed in the micro-ditch via the stabilizing device. In this way, easy access to the pipes / cables is obtained.

Furthermore, the machine according to the invention may also comprise other suitable means, such as one or more motors for driving the saw blade and stabilizing device and / or pre-propulsion means (such as driveline and wheels), wireless communication with, for example, a remote server unit, processing means, sensors, GPS means, GPS sensors. vehicle means, display means for displaying information such as graphs, database means, reading means for reading mechanical coding means on saw blade, immobilizer, etc.

When operating the saw blade and / or stabilizing device, this can be done via direct mechanical operation, hydraulic operation or electric operation. Mechanical drive gives the highest efficiency while electric drive gives the lowest efficiency so the former is preferable if high efficiency is needed, which is often the case.

Micro Trenching Technique MH) An in-depth knowledge of the MIT method is needed. Figure 1 shows a fate diagram of an MTT method for laying at least one pipe / cable under a road surface in an area containing the steps: - Sawing a micro-ditch in an area through the first layer L1 into the second layer L2; a pipe / cable in the micro ditch so that at least one pipe / cable is placed under the first layer LI; and backfilling of the micro ditch to restore the pavement of the road.

Figures 3a and 3b schematically show a cross section of an area where a pipe is located in a The area in Figures 3a and 3b is a three-dimensional area of a typical road area, the area comprising a first layer L1 which is the wall covering such as asphalt or concrete and a second layer L2 which is a base layer for the first layer L1 and which usually consists of macadam, sand and soil. As shown in Figure 3, the second layer L2 is of course located below the first layer L1.

The sawing step involves: sawing the micro-ditch through the first layer L1 into the second layer L2, which means that the micro-ditch is sawn as shown in Figures 3a and 3b. The micro-ditch is sawn so deep that at least one pipe / cable is placed in the micro-ditch under the first layer L1 (ie all-installed pipes / cables are placed under the first layer L1). By using the present method, all pipes / cables required for a professional network can be laid so deep that they are protected if the road surface L1 is removed or replaced, for example when roads are repaired.

Then at least one pipe and / or a communication cable is placed in the micro-ditch. The pipe is a pipe arranged to hold "blows" (so-called EPFU) or support cables. The tube (s) and / or the communication cable (s) are laid in the micro-ditch so that they are completely laid under the first layer L1.

Finally, the nrilcodiket is filled with a suitable filling material so that the road surface remains. The backfill material consists of sand or other material with suitable properties. The microdiket is filled with the backfill material to a suitable level, and if necessary compacted with a ground vibrator arranged for the width w of the microdik. Finally, the microditch is sealed with a sealing material, such as bitumen, to maintain a waterproof seal. If a waterproof seal is not required, repair can also be done with cold asphalt, which is a simple and inexpensive method of restoration. A suitable amount of cold asphalt is poured over and scraped into the micro ditch and then compacted to a smooth and even surface. Any excess asphalt can then be collected and removed.

The step of backfilling may, according to a preferred embodiment, include the steps of: - sealing the micro-rod iron with the bottom of the first layer L1 with a first seal S1; and- closure of the micro-ditch is flush with the top of the first layer L1 with a second closure S2.

Figure 4 shows the embodiment described above. The top and bottom of the first layer are shown in Figure 4. To obtain a seal with good adhesion, it is recommended that hot bitumen or bitumen mixture be poured in when sealing the micro-ditch. Other materials such as concrete or polymer-modified bitumen also work.

The first closure S1 seals the ditch iron with the bottom of the first layer L1, so that the micro ditch can be washed with a high pressure washer to remove sand residues from the asphalt-concrete edges. During the washing, the micro-ditch can be dried and preheated using a propane burner and finally the micro-ditch is filled evenly with the top of the first layer L1 with a suitable sealing material such as hot bitumen for crack repair.

According to a further embodiment, the microcrodice is sawn with a machine having a saw blade which is diamond clad. Such a diamond-clad saw blade easily saws through the hardest materials, such as stone or concrete, and has been found to be very suitable in the present application, since it provides very clean cuts when sawing the micro-rod. In prior art methods of sawing the micro-ditch, such as the use of saw blades with toothed hard metal (tungsten carbide), amounts of small cracks occur on the edges of the micro-ditch and which make complete sealing significantly more difficult and much more expensive compared to the present method. 12 The micro-ditch is preferably sawn with a modified so-called weighing saw (sawing device) with a diamond-clad saw blade. To further optimize the performance of the road saw in the present application, the inventors have realized that one or more of the following improvements are useful and should therefore be considered as embodiments: 0 change of direction of rotation of the saw blade to so-called "up-cut" for improved removal of sawn material; 0 modified cover for the saw blade and a front outlet to optimize the removal of sawn material and to reduce the spread of dust particles and to leave the microdialet clean and ready for laying pipes / cables; Stabilization device as shown in Figures 8 and 9 with one or more guide means, pre-channel pipes / cables, directly after the saw blade so that micro-digging and laying of pipes / cables can take place in a process. In the case where the stabilizing device has control means for a number of tubes / cables, these control means must be arranged so that the outputs fi the stabilizing device are placed one above the other in such a way that the order of the tubes / cables n from the input of the stabilizing unit and down into the micro-ditch is preserved; 0 drum trolley pulled by the weighing saw with holder for drums for pipes / cables and warning tape with search wire; and 0 servo that keeps the saw blade vertical on uneven ground, for example when two off-road saw wheels are on the pavement and two wheels are on the road surface.

Figure 8 shows an embodiment using a sawing machine comprising a saw blade rebuilt for "up-cut". "Up-cut" is defined as the direction of rotation of the saw blade in relation to the direction of sawing as shown in Figure 8. All known sawing machines have the opposite direction of rotation. By changing the direction of rotation of the sawing machine to "up-cut" helps to remove sawn material from the micro ditch and thus provides a "clean" micro ditch.

Furthermore, the sawing machine is equipped with a stabilizing device arranged directly behind the saw blade, the stabilizing device having at least one guide member, such as e.g. channels, for guiding the pipes / cables when they are placed in the micro ditch directly after the saw blade. In the event that a number of pipes / cables are to be laid at the same time, the stabilization device is arranged so that it is capable of laying pipes / cables in a maintained order. This can be achieved by having individual channels for pipes / cables in the stabilizing device so that the order of the pipes / cables is maintained through the stabilizing device. This makes it possible to identify which pipe / cable comes at the top of the micro-ditch and thereby make it possible to know which pipe / cable is to be cut for each final destination, see Figure 10.

In general, the depth d of the micro-ditch should be greater than the depth of the first layer d] together with the height d2 of at least one pipe / cable, i.e. d> dl + d2 which means that the depth d of the micro-ditch is greater than the height of the first layer dl plus the total height of one or fl your pipes and / or communication cables. As shown in Figures 3a, 3b, and 4, the above relation applies.

However, the cost increases with increasing depth d at the milcodike. Therefore, the ditch should not be deeper than necessary. Normal depth d of the micro-ditch can be about 400 mm, but unlike the width w of the micro-ditch, the depth d o fl a can be adjusted continuously during drive fi when using a weighing saw. The depth of the saw can therefore be reduced gradually as the number of pipes laid in the micro-ditch Furthermore, the micro-ditch should not be wider than necessary as a wider milcodike entails higher costs than a narrow micro-ditch. On the other hand, a narrower micro-ditch can make it more difficult to install pipes / cables so that there is an optimal width for the micro-ditch, because if the micro-ditch is too narrow, all pipes / cables will be stacked on top of each other so that the depth of the top pipe / cable will be too grunt.

Due to the above discussion, the inventors have found by tests suitable dimensions of a micro-ditch should be a depth d between 200 - 500 mm (and preferably 300-500 mm) and a width w between 10 - 30 mm (and preferably l5-25 mm) according to an embodiment for optimized installation efficiency and low cost. Furthermore, traffic disturbances with these dimensions are minimized as vehicles can easily pass over an open micro-ditch.

Furthermore, with reference to the fate diagram in Figure 2, the method for laying at least one pipe / cable according to another embodiment comprises the following steps: - scarming of an area by means of a ground penetrating radar; and 14 - identifying obstacles in the area using data generated by the ground penetrating radar, - sawing a micro-ditch in the area through the first layer L1 and down into the second layer L2; laying at least one pipe / cable in the micro-ditch so that at least one pipe / cable is placed under the first layer L1; and - backfilling the micro-ditch to restore the road surface.

It should be noted the steps of scanning and identification are performed before other steps in the method according to this form of dehydration.

According to this embodiment, the area is scanned by means of a ground-penetrating radar unit, such as for example a GEO radar or other suitable equipment.

Using information generated by the ground penetrating radar, obstructions are identified underground in the area, such as sewer pipes, electrical cables, structural structures, etc. The scanning and identification steps mean that when performing the subsequent sawing step, you can avoid accidentally cutting / damaging obstacles in the area, which can result in delays and extra costs in the micro-ditching process. If you have sawn a micro-ditch in the scanned area, at least one pipe and / or single-communication cable is laid in the micro-ditch. Finally, the micro-ditch is filled with suitable filling material so that the path is restored.

The method may also include the step of: installing or blowing a fi ber or fi berber cable in one or fl your pipes if pipes have been laid in the milcrodict.

It should also be noted that the method described above may also include the step: achieve one or fl your branch points connected to the micro ditch. Preferably, the branch points are made by means of a diamond-clad core drill or by a hand-held saw machine with a diamond-clad chain or saw blade. For this embodiment, the method may also include the additional step of drilling one or more channels from the branch points to one or more properties using controlled drilling. It is important that the ducts are drilled under the first layer L1 in the second layer L2. Pipes / cables are then installed in these ducts when the drill is pulled back.

The following description discusses various aspects regarding the layout and design of the microdics, branch points and channels, as well as strategies regarding sawing, branching, etc. in relation to and incorporated in the present method.

Layout Figure 5 shows a typical logical structure of a Fiber 'lill Hemnåt (FTTH) in a residential area, where "D" is a distribution node and "F" is a splice point where larger fi support cables are spliced less (or in the case of a PON network distributor where optical splitters are located). The network between the distribution node D and a splice point F is called the distribution network and the network between the splice point F and the individual properties is called the access network. Both pipes / cables for the distribution network and the access network can be installed using the existing method.

A residential area to be built with FTTI-I is "normally divided into a number of smaller residential areas. Somewhere in or outside the residential area there must be a place that houses the optical panels and electronics needed to form a so-called distribution node D. The distribution node D can be located Each distribution node D can contain electronics and professional panels for between a few hundred households to several thousand households. The size of the area to be connected to a single distribution node D can be adapted within wide limits and depends primarily on practical considerations, such as space distribution node D, difficulties in handling a variety of small distribution nodes D, etc. The present method can also be adapted for any desired number of bers per household.

De: finns wa hoodumypef av Fun-nar: punkr-riil-punm- m: punm- fi ii-muriipunkmawerk. In a so-called point-to-point network, the distribution node D contains the other end of all fi bres that originate in each individual household in the residential area. If, for example, an area with 500 households is dimensioned for 2 fi brer per house, this means that 1000 fi brer comes into the distribution node D. The distribution node D should preferably be centrally located in the area to be built as shown in fi gur 5.

The design of a point-to-multipoint network or a so-called Passive Optical Network (PON) is more or less the same. The difference is that the number of incoming fi spreads to the distribution node D in this case corresponds to the number of households divided by a factor (eg 8, 16,32, etc.). The examples in the further discussion are based on the assumption that a point-to-point network will be built. However, the described methods can also be applied to a PON as the distribution cables are scaled correctly. sea från aieaibu fi eneneaee n ensekef sig diembuuenekebref uu exervpunmer F praeefeae ibrrmnar eller i markskåp. The distribution cables are normally dimensioned for the number of households in the area plus 10% in reserve so that future newly built properties can easily be connected to the network. In a point-to-point network where, for example, a splice point F comprises an area with 22 properties and the requirement is 2 fi wires per property, 48 fiber from the distribution cable is required. Fibers from the distribution cables are spliced at the splice points F to the fr from the access cables. These access cables then go on to each individual property that is to be connected.

How many properties a junction point F is to supply depends mainly on financial considerations. If the area to be connected is too large, the average length of the access to each property increases, which increases the cost. On the other hand, if the area is dilapidated, the cost per property increases due to its share in the joint point F and its distribution cable. Consequently, there is an optimal size for a residential area where the cost is the lowest. The number of properties that provide this cost minimum depends mainly on the topography of the area and on the size of the properties' plots of land, but a rule of thumb is that an optimal number is normally somewhere between 16-48 properties from each joint pointF.

If sawing is carried out using a saw according to a design form, the Splice Point F must be placed centrally in each sub-area with, for example, 22 properties. The joint point F can be placed in a ground cabinet or in a cable bridge at the wave side. Typically, 10-12 pipes extend from the ground cabinet or cable gland in each direction along the road. Each of these 17 pipes then connects each of the properties. Finally, access cables are blown into each pipe.

Sawing strategy Usually residential areas have properties on both sides of a road and in this situation the can property connections can then be made in two different ways: either micro-ditches on both sides of the road and connect the properties to the nearest micro-ditch or you micro-ditches only on one side of the road or in the middle of the road and connects properties from both sides to dettamilcrodike.

However, in order to minimize the number of micro-ditches that cross the road, intersections are made according to one embodiment to the opposite side of the road to the plot boundary between two properties. There, pipes are placed in the micro-ditch to each of the two properties. In this way, only a ditch is needed that crosses the road for every other property on the opposite side of the road. Micro-digging that crosses the road for every other property is a cheap and cost-effective method.

Branching fi- from a main ditch Branching from a main milike ditch (a main micro ditch is defined as a micro ditch along the road) can be carried out in a number of different ways. As shown in Figure 6, branches can be sawn either before or after the main ditch has been sawn. The respective method is best performed at an angle corresponding to approx. 45 ° from the main trench in order to obtain a large bending radius on the branch pipe / pipeline. The branch ditches can either cross the main ditch or end along the main ditch. When the main micro-ditch is sawn and the ducting pipes are laid, it is easy to lift one of the top pipes one by one to each of the branch ditches and on to the respective property.

An alternative branching method is to first drill a hole at each branching point with the aid of a core drill with a suitable dimension. The main microdick can then be sawn through all of these holes as described above and shown in Figure 7. This method is suitable both for the track-bound branching method described above and when property connections / branches are made by means of controlled drilling. 18 An alternative method of making branches is to first drill a heel at each branch point. The holes can be made using a drill bit of suitable dimension (for a round hole) or using a hand-held tool with a diarnated clad saw blade or chain (lined rectangular heel ). The main micro-ditch can then be fi fastened / sawn through all these holes in the same manner as described above and shown in fi figure 7. This method is suitable both for making the property connection with a micro-ditch sawn in the manner described above as well as making the property connection with controlled drilling. Controlled drilling is sometimes preferable to make the property connections because you then avoid (eg go under) obstacles such as fences, hedges, trees, etc. However, this means that an additional expensive machine (drill) is required at the installation site.

Finally, it should be understood that the present invention is not limited to the embodiments described above but also relates to and includes all embodiments within the scope of the appended independent claims.

The present invention therefore relates to at least the following aspects and embodiments.

Al. A machine arranged for sawing the micro-ditch and laying of pipes / cables in the micro-ditch, said machine comprising a saw blade arranged for sawing a micro-ditch in an area; said machine further comprising a stabilizing device for stabilizing said micro-ditch walls when laying pipes / cables in said micro-ditch, said stabilizing device being placed immediately after said saw blade in said micro-ditch and said stabilizing device comprising control means for controlling the pipe / cable.

A2. Machine according to A1, wherein said control means are arranged so that an order of a number of pipes / cables is maintained when they are placed in said micro-ditch.

A3. A machine according to any one of A1-A2, wherein said stabilizing device comprises a single input and an output for pipes / cables, said input and output being connected to said control means. 19 A4. A machine according to A3, wherein said control means are channels in said stabilization device and wherein said input and said output are connected to each other by means of said channels.

A5. A machine according to A4, wherein a minimum distance between said output and said saw blade is between 100 to 500 mm.

A6. A machine according to A4 or A5, wherein said input, said output and said channels together are releasably attached to said stabilizing device.

A7. A machine according to any one of A1-A6, said stabilizing device having a front part and a rear part, said front part being located immediately on said saw blade and having a section having a shape complementary to said saw blade shape.A8. A machine according to A7, wherein said saw blade has a circular shape.

A9. A machine according to any one of A6 to A8, said input, said output and said channels being arranged on the rear part of said stabilizing device.

A10. A machine according to any one of A7 to A9, said stabilizing device having a single wedge shape in cross section at said front part.

All. A machine according to any one of A1-A10, wherein said stabilizing device has a maximum width in cross section equal to or slightly less than a width of said sauce lens A12. Machine according to any one of A1-All, wherein the distance between said saw blade and said stabilizing anode is greater than 0 mm but less than 10 mm.

A13. A machine according to any one of Al-Al2, wherein an effective depth of said stabilizing device in said micro-ditch is up to 50 mm less than an effective depth of said saw blade. 'A14. A machine according to any one of A1-A13, wherein said stabilizing device and said saw blade are arranged to be raised and lowered independently of each other.

A15. A machine according to any one of A1-A4, said machine further comprising at least one drum arranged to hold tubes / cables before laying said tubes / cables in said microcirculation via said stabilizing device.