NO342057B1 - A bolt fastener - Google Patents

Abstract

A bolt fastener means for centering and holding a bolt in a bolt hole, comprising a body with an outer surface extending a length from an abutment surface to an entrance surface. The abutment surface has a greater extent than the entrance surface, the outer surface is provided for abutment against the bolt hole wall, and a cavity extends throughout the length of the bolt fastener between the abutment surface and the entrance surface and is adapted to accommodate at least a portion of the bolt.

Description

A bolt fastening device

Field of the invention

The invention relates to a bolt fastening device for centering and holding a bolt in a bolt hole, as described in the preamble to claim 1.

The background of the invention

Tunnels, mountain halls and rock rooms are often lined with water-repelling constructions which can also be insulating against frost. Components in these constructions and other technical devices are fixed in bolts that are fixed in drill holes with hardening compound. The holes can be drilled in the surrounding rock, in concrete walls, or the like. The hardening mass can, for example, be concrete or a two-component adhesive that is introduced as a liquid mass. Where glue is used, this can also be packaged in an ampoule. The bolt is often inserted into the holes after the mass has entered.

According to current standards and requirements for the installation of such bolts, the bolt must be centered in the hole so that the hardening compound provides optimal anchoring between the bolt and rock. Occasionally the bolt can seep or fall out before the compound has hardened, even if the compound is tough. If the bolt falls out, it represents a significant risk of damage to material and personnel. There is therefore a need to give the bolt a temporary hold until the mass has hardened.

After the bolt has been inserted to the bottom of the hole and secured against seepage, it may be necessary to adjust its position in the longitudinal axis of the hole so that the end pointing into the room is in the correct position in relation to the structure it is to support.

Bolts of different diameters are often used on a project. It is desirable to have as few variants of accessories as possible as it facilitates purchasing and logistics in and out of the tunnel, and control of the various accessories and stock of these. For example, cam steel bolts with a diameter of 16 mm are mounted in holes with diameters that can vary from, for example, 22 to 29 mm. Cam steel bolts with a diameter of 20 mm are often used in the same project. These are also mounted in holes with great variation. To simplify logistics, inventory control and assembly planning, it is an advantage if equipment associated with bolts can work for several combinations of bolt and hole diameter.

The holes that are drilled have varying diameters and can also be oval, this is due to, among other things, wear on the drill bit and varying drill steel quality.

The bolts that are installed can vary in length by several metres. This means that the weight also varies a lot. In combination with variations in bolt and hole diameter, it is challenging to create the right friction between bolt and rock. Some existing solutions for creating this friction are based on the material in the aid that will hold the bolt in place being compressed and/or springy to create friction. This gives a limitation in how heavy the bolt can be, or also for how many combinations of bolt and hole diameter a component can work satisfactorily for.

Constructions for water and frost protection of tunnels and rock rooms are carried out with relatively high precision. You often have a digital 3D model (CAD model) where the hole depths and angle of the hole are calculated, as well as the position of the holes is marked. The drilling is carried out by computer-controlled drilling machines. In some cases, the bolts are up to 4 meters long. If the bolt is not centered in the entire length of the hole, it can cause a relatively large deviation in the position of the end of the bolt in the tunnel space. In some cases, this can cause unnecessary challenges for the installer and delay the installation work.

Various aids are used today to counteract or prevent the bolt from falling out before the mass has hardened/solidified, as well as to center the bolt in the hole. The challenge with current solutions is that they can be cumbersome to use, do not provide optimal centering or do not provide a good enough hold for bolts that are longer than 1.2-2 m. Most aids are also diameter-specific in the sense that you have to know which diameter that is in the bolt hole, and have the correct dimension/version of the aid at hand.

Aids that exist today to center and temporarily hold a bolt in a hole include metal springs. This is a helical element with elements projecting from the center to provide friction against the wall of the bolt hole. The metal spring is mounted with a separate tool to mount it on the bolt, but it is relatively cumbersome to apply. This only centers the bolt in one position on the bolt, and is diameter-specific for bolt and hole diameter and the combination of these.

Another known technique includes plastic cuffs, but these can have a poor hold on the bolt in the hole if the bolt is longer than 1.2-2 m long because the bolt then becomes too heavy. This poses a major risk for equipment and personnel in the tunnel where the bolts are mounted in the suspension (ceiling). The plastic cuff is also small to handle with gloves and can be fiddly to fit. In addition, they are diameter-specific for bolt and hole diameter and the combination of these, and provide varying hold depending on the hole diameter. The plasma sleeve only centers at the end of the bolt.

There are plastic clips (so-called P-clips) for fully threaded bolts, but they can give a poor hold on the bolt if it is longer than 1.2-2 m long, because it will then be too heavy. This poses a major risk for personnel in the tunnel where the bolts are mounted in the suspension (ceiling). Plastic cuffs are also diameter-specific for bolt and hole diameter and the combination of these, and provide varying hold depending on the hole diameter. They do not work on cam steel bolts. Plastic clips center the bolt where the clip is mounted, and two clips are required to center the length of the hole.

In addition, there are wooden or plastic wedges that are wedged between the bolt and the hole, but these do not center the bolt in the hole (neither on the inside nor on the outside), are cumbersome to use and can damage the powder coating and galvanization when the bolt is pressed against rock.

Known technology includes NO333879, which describes a device for centering bolts intended to be inserted into holes drilled in rock or the like, to secure or hold the bolt intended to be anchored by means of a stiffening or hardening mass, which device comprises an elongated, axially hollow clip with an axial slot that extends along the entire length of the clip.

NO 319141 describes a method and a device for securing mountains with end-anchored bolts.

NO 20066000 describes a method for providing a rock bolt for rock bolting, in that a rock bolt with a tubular bolt part with a closed cross-section is inserted and expanded for bearing contact in a borehole in a rock structure.

SE 451615 describes a sleeve device for embedding bolts in boreholes, provided with punched out protrusions and holes and can be filled with grout and introduced into a drill hole where a bolt is inserted and thus pushes out the grout through the holes whereby the sleeve member and the bolt are incorporated into the grout.

To ensure proper anchoring between the bolt and rock, the bolt should be centered throughout the length of the borehole. A holding and centering device must be able to accommodate the variations in hole diameter and be adapted to the circular as well as non-circular shape of the hole that has been drilled in order to provide good centering and securing of the bolt. It must be able to hold bolts with a large variation in weight, and it is an advantage if the same holding device can be used for several bolt diameters and in holes with a large variation. There are currently no solutions that are easy to use and provide such a position and anchoring in a reasonable and efficient manner.

In those cases where the bolt is pushed into the hole after the hardening mass has entered, it is advantageous if a possible centering device mounted on the end of the bolt provides the least possible resistance as the hardening mass must force it. Some solutions have friction elements with a design that reduces the flow of the hardening mass past the bolt during entry. If you want to center the bolt in the entire depth of the hole and hold the bolt firmly, you must use two products today. It is advantageous if centering and temporary holding functions can be combined in one product to streamline the logistics and assembly process, as well as reduce costs.

Summary of the invention

According to the invention, there is provided a bolt fastening device for centering and holding a bolt in a bolt hole, comprising a body with an outer surface extending a length from an abutment surface to an entry surface. The contact surface has a larger extent than the entry surface, the outer surface is provided for contact against the wall of the bolt hole, and a cavity extends the entire length of the bolt attachment device between the contact surface and the entry surface and is designed to accommodate at least a part of the bolt.

In one embodiment, the longitudinal axis of the cavity mainly coincides with the central axis of the bolt fastening device.

In one embodiment, the cavity is substantially cylindrical.

In one embodiment, the cylindrical cavity has an inner diameter smaller than the outer diameter of the bolt.

In one embodiment, the outer surface has at least one portion with a substantially conical shape.

In one embodiment, an open slot extends the entire length of the bolt fastening device.

In one embodiment, the width of the open slot is smaller than the diameter of the bolt.

In one embodiment, at least one projecting position indicator is arranged in the cavity, and the positioning indicator is arranged to create resistance against a structural pattern on the bolt.

A centering device has also been provided for centering a bolt in a bolt hole.

The centering device is provided for attachment to one end of the bolt to be inserted into the bolt hole, and a plurality of fins for supporting abutment against the wall of the bolt hole.

In one embodiment, the fins are aligned parallel to the central axis of the bolt.

In one embodiment, a band connects the fins in a tangential direction around the bolt.

In one embodiment, the band is shaped so that the band's smallest diameter is smaller than the outer diameter of the bolt.

A mounting tool for the bolt fastening device has also been produced.

The assembly tool has an elongated body, an impact surface, an end surface arranged for contact with the contact surface, and an internal U-profile for contact with the bolt.

In one embodiment, the end surface has an outer diameter that corresponds to the diameter of the contact surface.

A system has also been developed for centering and holding a bolt in a bolt hole, where a bolt fastening device is connected to a centering device via a tear-off connection.

With the invention, a regulatory anchoring between bolt and rock is ensured, where the bolt is centered in the entire length of the borehole. The holding and centering device takes up variations in hole diameter and is suitable for both non-circular and circular shape of the hole that has been drilled, and provides good centering and securing of the bolt in the bolt hole. The invention is easy to use and positions the bolt in the bolt hole in a reasonable and efficient way, while ensuring a good temporary fastening of the bolt regardless of the bolt's length, weight and diameter.

Brief description of the drawings

These and other characteristic features of the invention will be explained in more detail in the following description of a preferred embodiment, given as a non-limiting example, with reference to the attached drawings, where:

Figure 1 is a cross-section of a bolt in a bolt hole, where the bolt has a bolt fastening device at the entrance of the hole and a centering device at the end.

Detailed figures of the bolt attachment device and the centering device are also shown.

Figure 2a is a perspective drawing of the bolt fastening device.

Figure 2b is a perspective drawing of the bolt attachment device attached to a bolt.

Figure 3 shows examples of different cross-sections of the bolt fastening device in plane X in Figure 2b.

Figure 4a is a perspective drawing of the centering device on a bolt end.

Figure 4b shows the centering device seen from above.

Figure 4c shows an alternative embodiment of the centering device seen from above.

Figure 5 is a perspective drawing of the bolt attachment device attached to a bolt, as well as an impact tool.

Figure 6 is a perspective drawing of the bolt fastening device and the centering device connected with a tear-off element.

Detailed description

The following description will use terms such as "upper", "lower", "inner", "outer", etc. These terms generally refer to the drawings and perspectives shown in the figures, and which are associated with a normal use of the invention. The terms are only used as an aid to the reader and should not be restrictive.

Figure 1 shows a cross section of a bolt 1 in a bolt hole 2 in a rock wall 3. The bolt hole can also be drilled in a concrete wall or the like, and the bolt hole 2 has walls 25. A bolt fastening and centering device 4 is attached to the bolt 1 at the entrance to the bolt hole 2, and on the end of the bolt 1 which is innermost in the bolt hole, a centering device 5 is attached. The detailed figures show the bolt attachment and centering device 4 and the centering device 5 in enlarged sections. The bolt fastening device 4 has a mainly conical or wedge-shaped outer shape, and when it is pressed firmly between the bolt and the wall of the bolt hole 25, pressure is created between the bolt 1 and the walls of the bolt hole 25 so that the bolt 1 is held firmly in the hole 2. Because the bolt 1 is centered in the middle of the bolt fastening device 4, the bolt 1 is centered at the outer end of the bolt hole 2. The centering device 5 ensures that the innermost end of the bolt 1 is also centered in the bolt hole 2, so that the hardening mass is evenly distributed around the bolt 1 throughout the length of the bolt, and the bolt 1 is firmly anchored in the bolt hole 2.

The sloping, outer surface of the bolt fastening device 4 can be conical, so that in a cross-section through the central axis of the bolt fastening device 4, the outer surface will appear as a straight line. Optionally, the outer surface 6 can be divided in stages so that it has two or more parts with conical surfaces with the same or different pitch. The cross-section in Figure 1 shows a bolt fastening device 4 with two such parts, where the angled outer surface 6 consists of two conical surfaces with different pitches. If the outer, angled surface 6 is divided into one or more such steps or sections, the bolt hole diameter can be adapted in sequences (eg 22-28, 30-36, etc.) without the bolt fastening device 4 becoming unnecessarily long. Such stepping can also be used if the bolt fastening device 4 is to be used on bolts with different diameters and combinations of hole diameter sequences.

Figure 2a shows a bolt fastening device 24 with a mainly conical surface, and Figure 2b shows the bolt fastening device 24 attached to a bolt 1. The bolt fastening device 24 has a mainly cylindrical hollow core 7 which extends in the entire length direction of the bolt fastening device 24. The diameter of this cylindrical, hollow core 7 is smaller than the outer diameter of the bolt 1, so that when the bolt fastening device 24 is threaded onto a bolt 1, the bolt fastening device 24 will exert a pressure or a clamping force against the bolt 1, so that the bolt fastening device 24 is thus attached to the bolt 1 and does not fall off, but can be moved to the desired position. The bolt fastening device 24 allows entry from the ends of the bolt 1, so that the bolt fastening device 24 can be entered from one of the ends and guided along the bolt 1 to the desired position. The bolt fastening device 24 is preferably made of a flexible material, or with a design that enables and allows the bolt fastening device 24 to be flexible in the radial direction to a certain extent, so that a bolt fastening device 24 with the same original inner diameter can fasten on bolts 1 of different thickness .

The bolt fastening device 24 has in the longitudinal direction a mainly conical or cone-shaped outer shape 20, with an open groove 8 which extends in the entire longitudinal direction of the bolt fastening device 1. This open groove 8 means that the cross-section of the bolt fastening device 24 seen in the longitudinal direction does not form a closed circle, but has an opening or a gap 24 which comprises approximately 1⁄4 of the circumference of the bolt fastening device 24 seen in the longitudinal direction. The groove 24 can be as small as 10-20% of the circumference of the bolt fastening device 24, but it must be large enough to allow the bolt fastening device 24 to be inserted onto the bolt 1 across the longitudinal direction, i.e. that the bolt fastening device 24 is guided onto the bolt 1 in a radial direction. The width of the groove 8 must not be wider than the diameter of the bolt 1, because the bolt attachment device 24 will then not attach to the bolt. The width of the opening 8 is controlled by factors such as the material properties of the bolt fastening device 24, the design of the bolt fastening device 24, etc.

The outer cross-section through the body of the bolt fastening device 24 in the longitudinal direction is mainly shaped like a wedge, where contact with the bolt 1 is mainly parallel to it. The outer surface 20 that meets the wall in the hole where the bolt 1 is inserted is inclined, i.e. not parallel to either the bolt hole or the cross-sectional profile of the bolt 1, and facilitates that the distance from the surface of the bolt 1 to the surface of the hole wall can vary.

When the bolt fastening device 24 is threaded onto a bolt 1, a part of the bolt 1 will mainly fill the hollow, cylindrical space 7 so that the bolt fastening device 24 partially encircles and attaches to the bolt 1. A typical bolt 1 may have a structural pattern consisting of a plurality of inclined, protruding beads 9 on two sides in the longitudinal direction of the bolt 1, as well as two longitudinal ribs 10 which are placed diametrically opposite on the bolt 1. A bolt 1 can be either fully threaded or a reinforcing bolt with a surface structure as mentioned. When the bolt fastening device 24 exerts a clamping force on the bolt 1, it is mainly either the threads, the beads 9 and/or the ribs 10 on which the clamping force will be exerted.

Friction between the bolt 1 and rock/concrete can be regulated by the choice of material in the bolt fastening device 24, the possibility of deformation of the bolt fastening device 24 which can enclose the structural elements 9,19 on the bolt 1 and surface pressure between the three elements (hole surface, bolt surface and bolt fastening device 24).

The bolt fastening device 24 has recesses 21 on the inside, i.e. recesses on the cylindrical inner surface, to reduce the amount of material and give the bolt fastening device 24 better mechanical properties in relation to elastic deformation. Correspondingly, the outer surface 20 can have recesses 22 to achieve the same.

The recesses extend in the longitudinal direction of the bolt fastening device 24, and different designs of the recesses 21, 22 will result in different cross-sections of the bolt fastening device, examples of such cross-sections are shown in Figure 3. The recesses 21, 22 do not need to extend the entire length of the bolt fastening device 24, but will typically extend approximately from the contact surface 18 (the thickest end of the bolt fastening device 24) and towards the entry surface 23 of the bolt fastening device 24. The entry surface 23 is the part of the bolt fastening device 24 that is first inserted into the bolt hole. Because the bolt attachment device 24 is mainly cone-shaped, the contact surface 18 will have a larger extent than the entry surface 23, and the contact surface 18 has a larger extent (e.g. a larger diameter) than the diameter of the bolt hole, so that the bolt attachment device 24 will be wedged firmly at the entrance to the bolt hole, and could not enter the bolt hole in its entirety. The recesses 21,22 can be limited to those parts of the bolt fastening device 24 where there is a need for material reduction or the bolt fastening device 24's mechanical properties are to be improved.

The bolt fastening device 24 can advantageously be cast, preferably in plastic or a composite material. The bolt fastening device 24 can also be made of metal. In order to optimize the friction or the friction coefficient and/or surface pressure, the bolt attachment device 24 can be cast in, for example, two or more materials with different properties. For example, one material may have a good coefficient of friction, while another may have good tensile strength. A third material can have good deformation properties to enclose the structural elements 9,10 on the bolt in an advantageous way.

The bolt fastening device 24 can also have a cross-section like a closed circle, this is shown in connection with Figure 3. If the bolt fastening device 24 has a closed, circular cross-section, the bolt fastening device 24 must be inserted onto the bolt 1 from one of the bolt 1's ends.

A position indicator 11 on the cylindrical surface of the cylinder chamber 7 is provided so that optimal placement on the bolt 1 is achieved. On reinforcing bolts, the structural pattern 9,10 on the bolt 1 can vary around the circumference, i.e. in the tangential direction of the bolt 1. This means that the bolt attachment device 24 can achieve varying attachment properties depending on which tangential position on the bolt 1 it has. A pin or position indicator 11 that projects in the radial direction towards the bolt 1, large enough so that it sticks easily in the bolt's beads 9 when the bolt fastening device is guided in the longitudinal direction of the bolt 1, will give feedback to the fitter by vibration and sound. In order to achieve a good attachment for heavy bolts, the bolt attachment device 24 can advantageously be positioned so that the fitter should rotate the bolt attachment device 24 until the vibration/sound ceases, i.e. that the position indicator 11 is in the area near the rib 10. If the fitter wishes to facilitate easy readjustment of position of the bolt 1 in the longitudinal axis of the hole after the bolt fastening device 24 has been pressed into the hole with sufficient holding force, this can ensure that the vibration/sound persists.

Figure 3 shows eight examples of different cross-sections that the bolt fastening device can have.

The cross-section is seen in the longitudinal direction of the bolt fastening device, from plane X in Figure 2b.

In cross section a), the bolt fastening device has a closed, circular profile so that the bolt fastening device must be threaded onto the bolt from one of the bolt's ends. The material the bolt fastening device is made of can also be partially elastic and compressible, so that the inner diameter of the bolt fastening device can be smaller than the bolt's outer diameter. Thus, the bolt fastening device will exert a slight pressure on the bolt it is to be attached to when it is threaded onto the bolt, and the bolt fastening device will also allow fastening on bolts of different diameters. In this case, the bolt fastening device will be compressed when it meets the edge of the hole it is to enter, and the tension the bolt fastening device creates between the bolt and the rock or concrete thus locks the bolt in place in the hole.

In cross-section b) the bolt fastening device has a partially circular profile, with an opening or a slot which allows the bolt fastening device to be threaded onto the bolt in a radial direction, i.e. threaded onto the bolt laterally. The material properties and function of the bolt fastening device will otherwise be similar to that described in section a).

In cross-section c), the bolt fastening device has an opening or a groove as described in b), and internal recesses which result in the cross-section being a thin-walled construction with ribs projecting inwards towards the centre. Such a geometry will be economical in terms of material use and in terms of weight, and also allows the bolt fastening device to be made in a more brittle (less elastic) material than is the case with a) and b). Because the ribs in c) can be thin and thus relatively deformable, the bolt fastening device will adapt to different thicknesses of the bolt.

In cross-section d), the bolting device has an opening or groove as described in b), and internal and external recesses which result in the cross-section being a thin wall that forms both the outer, mainly conical profile of the bolting device, and the same wall defines the inner, cylindrical cavity. In the cross-section d) the wall has an outer contour like a gear wheel, i.e. the cross-section has a contour like teeth with straight side edges and with an outer, curved surface. Such a design of the bolt fastening device will provide an advantageous span between the bolt and the rock/concrete, because the wall of the bolt fastening device will be able to shift tangentially to a certain extent as it is deformed in the radial direction.

Cross-section e) is in principle similar to cross-section c) except that this cross-section does not have an opening/gap. The ribs in e) can have decreasing thickness towards the centre, so that they are more flexible and allow greater deformations closer to the bolt.

The bolt fastening device with cross-section f) is in principle similarly designed to the bolt fastening device in a), but with internal recesses. These recesses will be formed on the contact surface of the bolt fastening device. The recesses will make the bolt fastening device more susceptible to local and global deformation.

In cross-section g) the bolt fastening device has an opening or a groove as described in b), and with equal inner and outer recesses which result in the cross-section being radial ribs with a conical surface positioned mainly in the middle. This design will allow deformation of the outer profile of the bolt fastening device, because the radial ribs are more easily deformed elastically or plastically than a closed, outer surface. In this way, the bolt attachment device can be easily secured between the mountain and the bolt.

In cross-section h), the bolt fastening device has an opening or a groove as described in b), and exclusively external recesses. Such a design will allow a lot of deformation of the bolt fastening device's outer profile, while the inner cylindrical cavity will be flexible enough to fasten around bolts of different dimensions and enclose protruding structures on the bolt.

In cross section i), the bolt fastening device consists of three segments with a relatively large radial extent. These segments are connected by a geometry that allows the segments to move in both radial and tangential directions relative to each other. Such a design will mean that the bolt fastening device can be made in a relatively rigid material, while at the same time the device will allow elastic deformation and be able to adapt to both different thicknesses of the bolt it is to be used on, and an uneven edge of the hole it is to enter.

Figure 4a shows the centering device 5 mounted on one end of the bolt 1.

The centering device 5 is attached to the bolt 1 by being guided down onto the end of the bolt 1.

The centering device 5 consists of two or more fins 12 aligned substantially parallel to the central axis of the bolt 1, and projecting in a substantially radial direction from the bolt 1. In one embodiment, the fins 12 can be deformed when the bolt 1 with the centering device 5 is introduced into a bolt hole, to give a centering pressure from the bolt and out towards the wall in the bolt hole. In another embodiment, the fins 12 do not provide a centering pressure, but keep the bolt 1 centered in the bolt hole within an acceptable tolerance. The fins 12 are aligned parallel to the center axis of the bolt 1 so that the hardening mass can pass as easily as possible when the bolt 1 and the centering device 5 are introduced into the hole after the hardening mass has entered.

The fins 12 are connected by a band 13 which goes around the entire circumference of the bolt 1. The fins 12 are connected at a point 14 which e.g. coincides with the center axis of the bolt 1, thus forming a connection point 14 on the tip of the centering device 5.

The connection point 14 also prevents the bolt 1 from being pushed through the centering device 5, and thus ensures that the centering device 5 sits at the end of the bolt 1 as far into the bolt hole as the bolt should.

The band 13 can be designed so that in a neutral state (i.e. in a state where the centering device 5 is not attached to a bolt 1) the smallest diameter of the band 13 is slightly smaller than the bolt 1, so that when the centering device 5 is attached to the bolt 1 then the inner diameter of the band 13 will expand and thus exert pressure on the bolt 1, which thus attaches the centering device 5 to the bolt 1. Such a geometry is shown in Figure 4b, where the band 13 does not therefore have a circular cross-section (a cylindrical profile), but in the example shown with three fins 12, the band 13 has a band segment 13' between each fin 12, in the example shown there are a total of three band segments 13'.

Figure 4c shows an alternative embodiment of the centering device 5, here the springy fins 19 have a decreasing thickness in the radial direction from the center of the centering device 5, and the fins 19 will be suitable for elastic deformation in the face of a rock wall. The springy fins 19 can also be inclined as shown in the figure, in order to reduce the pressure they create between the bolt and the rock wall.

The bolt attachment device and the centering device can advantageously be produced or cast as one part, but they can also be produced or cast separately. If cast as one part, the connection between the two components shall be made with weaknesses that allow an assembler to easily separate the parts by hand when the parts are to be used. This will make the assembly more efficient, and prevent a shortage of one or the other part.

Figure 5 shows a bolt 1 with a bolt fastening device 24 and an impact tool 15.

The impact tool 15 has an inner groove in the longitudinal direction shaped like a U. The U-profile provides that the tool 15 can be threaded onto the bolt 1 at any location, where the inner diameter or the distance between the parallel walls of the U-profile of the impact tool 15 is greater than the largest diameter of the bolt 1, so that the tool 15 can slide unhindered back and forth along the bolt 1. The impact tool 15 can also have a closed profile (a tube) to increase the stability along the bolt 1. In this case, the inner diameter of the impact tool must 15 also be larger than the largest bolt diameter the tool is intended to be used on.

The impact tool 15 has an impact surface 16 where you can use, for example, a hammer to knock the impact tool 15 against the bolt attachment device 24. At the opposite end, the impact tool 15 has an end surface 17 that abuts the contact surface 18 of the bolt attachment device 24. The surface 17 preferably does not have a larger diameter than the contact surface 18 on the bolt attachment device, so that the end surface 17 of the impact tool 15 will in most cases be able to collide with the contact surface 18 of the bolt attachment device 5, even if uneven formations in rocks etc. limit access to the surface 18 of the bolt attachment device. This is important so that the impact tool 15 does not hit the mouth of the hole and lose energy before this is transferred to the bolt fastening device 24. A conical surface 26 narrows the body of the impact tool towards the end surface 17. The impact tool 15 is used to strike or bump the bolt fastening device 24 as far into a bolt hole as possible. When the diameter of the surface 20 of the bolt fastening device 24 is approximately equal to the diameter of the bolt hole, the surface 20 will collide with the wall of the bolt hole, and the bolt fastening device 24 will wedge itself.

The impact tool 15 can, for example, have such a weight that the fitter does not need to use a hammer in addition. That is if the impact tool 15 is heavy enough, a fitter will be able to store energy in the tool 15 by accelerating it along the bolt until it hits the bolt attachment device 24.

Figure 6 shows the bolt fastening device 24 and the centering device 5 connected with a detachable element 27. If the bolt fastening device 24 and the centering device 5 are produced as one element, fastened together by a detachable element 27, an example of a method of use could be that the centering device 5 is first threaded over it the end of the bolt that will go into the hole. The bolt attachment device 24 is then separated by hand from the centering device 5 where there is a weakness 28 in the tear-off element 27.

The bolt fastening device 24 can now be applied from the side and guided along the bolt to the desired position before the bolt is inserted into the hole. If the fitter receives feedback from the position indicator that the bolt fastening device is in the wrong position on the bolt (i.e. that the bolt fastening device 24 must be turned tangentially on the bolt), then the bolt fastening device 24 can be rotated until the feedback ceases. When the bolt has been inserted and pushed into the correct position in the bolt hole, the bolt fastening device 24 is guided towards the opening of the hole so that it touches the mouth of the hole. Now an impact tool can be used to push the bolt fastening device 24 into the bolt hole so that a pressure occurs between the bolt fastening device 24, the bolt and the wall/mouth of the hole.

There may be a need to readjust the bolt's position. If this happens often, the fitter can choose to place the bolt fastening device 24 radially so that the position indicator warns of reduced holding power and/or use impact tools with reduced power so that readjustment is possible. The hold can still be good enough so that further use of impact tools is unnecessary.

Claims (15)

Claim 1. A bolt fastening device (4, 24) for centering and retaining a bolt (1) in a bolt hole (2), comprising a body with an outer surface (6, 20) extending a length from a bearing surface (18) to an entry surface (23), characterized in that the contact surface (18) has a greater extent than the entry surface (23), the outer surface (6, 20) is provided for contact against the wall (25) of the bolt hole, and a cavity (7) extends itself in the entire length of the bolt fastening device (4, 24) between the contact surface (18) and the entry surface (23) and is arranged to accommodate at least a part of the bolt (1). 2. Bolt fastening device according to claim 1, where the longitudinal axis of the cavity (7) mainly coincides with the central axis of the bolt fastening device (4, 24). 3. Bolt fastening device according to claim 1 or 2, where the cavity (7) is mainly cylindrical. 4. Bolt fastening device according to claim 3, where the cylindrical cavity (7) has an inner diameter that is smaller than the outer diameter of the bolt (1). 5. Bolt fastening device according to any one of the preceding claims, wherein the outer surface (6, 20) has at least one portion with a substantially conical shape. 6. Bolt fastening device according to any one of the preceding claims, where an open gap (8) extends throughout the length of the bolt fastening device (4, 24). 7. Bolt fastening device according to any one of the preceding claims, where the width of the open slot (8) is smaller than the diameter of the bolt (1). 8. Bolt fastening device according to any one of the preceding claims, where at least one protruding position indicator (11) is arranged in the cavity (7), and the positioning indicator (11) is arranged to create resistance against a structural pattern (9, 10) on the bolt (1). 9. A centering device (5) for centering a bolt (1) in a bolt hole (2), characterized by being provided for attachment to an end of the bolt (1) to be inserted into the bolt hole (2), and a plurality fins (12) for supporting contact against the wall of the bolt hole (25). 10. Centering device according to claim 9, where the fins (12) are aligned parallel to the central axis of the bolt (1). 11. Centering device according to claim 9 or 10, where a band (13, 13') connects the fins (12) in a tangential direction around the bolt (1). 12. Centering device according to claim 12, where the band (13, 13') is shaped so that the smallest diameter of the band (13, 13') is smaller than the outer diameter of the bolt (1). 13. A mounting tool (15) for the bolt fastening device (4, 24) according to claims 1-8, characterized by having an elongated body, an impact surface (16), an end surface (17) arranged for contact with the contact surface (18), and a internal U-profile for contact with the bolt (1). 14. Assembly tool according to claim 13, where the end surface (17) has an outer diameter that corresponds to the diameter of the contact surface (18). 15. A system for centering and holding a bolt (1) in a bolt hole (2), characterized in that a bolt fastening device (4, 24) is connected to a centering device (5) via a detachable connection (27).