NO346342B1 - FIRE-RESISTANT CRACK INDICATOR FOR IMBED IN INJECTED CONCRETE CONSTRUCTION IN TRAFFIC TUNNELS - Google Patents

Description

FIRE-RESISTANT CRACK INDICATOR FOR IMBED IN INJECTED CONCRETE CONSTRUCTION IN TRAFFIC TUNNELS

Background for the invention

The present invention generally relates to infrastructure in connection with traffic tunnels. More particularly, the invention relates to a crack indicator for injection-molded concrete vaults in traffic tunnels, where the crack indicator contributes to improved safety in the event of fire.

Furthermore, the invention relates to fire-retardant sealing of expansion joints in one operation without refilling the opening with fire-retardant sealant.

Background technology

According to known technology for traffic tunnels, the draining insulation material is usually arranged in the form of polyethylene foam (PE foam) on the rock wall of the tunnel, where the main purpose of said foam is to direct leakage water from the rock away from the roadway in the tunnel and into longitudinal edge trenches near the transition between the rock wall and the roadway . The PE foam has good insulating properties that prevent the water from freezing and thus creating hanging ice in the tunnel.

A serious disadvantage of PE foam is that it is flammable and emits smoke and gases in case of fire. For safety reasons, it has therefore been necessary to cover the foam with concrete, which in the present case is shotcrete that is applied in a suitable thickness, which can typically be approx. 80 mm.

After the shotcrete has been applied, it stands and hardens for a relatively long time, which can typically be a minimum of 28 days. During curing, the concrete shrinks with cracking as a result. In order to control the formation of cracks, so-called crack indicators are arranged in the concrete across the length of the tunnel at suitable intervals.

The formation of cracks will then occur at the aforementioned rice indicators. The size of the crack at the rice indicator will change as a function of temperature and humidity.

Today's solution for rice guides comprises an angle strip (L-shape) which is screwed into the PE foam with a special screw (see Figure 1). According to current technology, a felt is normally mounted as a sliding surface under the rice indicator. Assembly takes place in the following order: felt, angle strip and reinforcement. When the list is installed and the reinforcement of the vault is finished, the list, the reinforcement and the PE foam inside are sprayed with shotcrete. When the concrete has then stood and hardened, a crack has formed along the plastic angle as the concrete has shrunk. There is then an opening that can have access to the PE foam. Due to the risk of fire, such an opening that has formed cannot be left open as it entails the risk that a possible fire could break through the opening and set fire to the PE foam that lies behind the shotcrete. They have therefore chosen to go back and fill the opening with a fire-retardant sealant.

Filling said opening with sealant is a complicated, labour-intensive and expensive operation which also prevents traffic in the tunnel during the rest of the assembly work. Since the formation of cracks occurs over time, the need for further filling can be an obstacle to starting traffic or result in traffic having to be taken out of the tunnel. The joint compound also has its weaknesses when the tunnel comes into operation. This is because the mass hardens and becomes hard, and when the tunnel is to be washed; which is typically done by a high-pressure washer, the mass is washed away and thus the opening is unprotected.

Today's rice indicators therefore generally have several disadvantages, including in terms of safety, availability, costs, complexity and logistics. More specifically, there are problems with the current solution in that a fire can spread to PE foam. Furthermore, the solution is complex in that it includes both an angle strip and fire-retardant sealant, which must be arranged in two steps at intervals. The felt that is mounted where the rice indicator is to be placed provides a sliding surface, but it is not fire retardant. The solution according to known technology is complex and expensive, among other things, because it comprises several elements that must be arranged using different methods in a sequence. The availability of the tunnel in question is reduced both in connection with the initial installation of the system, during operation and during subsequent maintenance. For similar reasons, costs will increase in the various phases over the tunnel's lifetime.

Patent application US 4815886 A “Expansion joint for concrete and method for use” presents a self-supporting rice indicator for use in the manufacture of concrete products, the rice indicator comprising a single, molded unit in the form of an inverted T with a flat base adapted to rest on the ground and a vertical beam perpendicularly connected to the center of the base, the beam being thicker at the point of connection with the base than at the top.

Patent application GB 985573 A "Improvements in or relating to waterstops" presents a water stop device for connection between concrete masses. The device comprises a strip of elastomeric material having half of its width split to form elements bearing complementary male and female formations adapted to engage each other when the elements are brought together.

Patent application US 4979846 A “Contraction joint for concrete linings” presents a contraction joint for use in forming a concrete layer. The joint includes a socket, a central projection extending from the socket, the projection having an upper top section of uniform thickness and a lower triangular section with a cut-out portion to aid in contraction and expansion of the joint.

Brief presentation of the invention

The invention relates to a fire-retardant crack guide for embedding in a shotcrete construction arranged against a flammable, draining insulation material in a traffic tunnel. The crack indicator forms an elongated profile with an essentially constant cross-section, where the crack indicator comprises a crack part suitable for helping to control the formation of a crack through the concrete structure at the crack indicator, and a first foot part arranged to be attached to the insulation material, where the first foot part protrudes on one side of the profile section across it in relation to a longitudinal axis of the profile.

The rice indicator comprises a second foot part which protrudes on the opposite side of the rice part in relation to the first foot part. The second foot part is also arranged to be attached to the insulation material.

In a preferred embodiment, the solution may consist of an extruded rubber profile which has an approximately constant cross-section. The footings have a distributed, unshaped surface so that the concrete can slide along these when it shrinks. The crack indicator can advantageously have a Y-shape so that it has a resistance to being pushed to the side when it is sprayed with concrete. The crack indicator can be made of a fire-retardant rubber with or without material that makes it expand. The Y-shaped rice indicator can advantageously include a connecting part between the two foot parts which will help to prevent the fire from passing through if the rest of the rice indicator should be damaged by the fire. Furthermore, the midfoot part will prevent the profile from flattening when spraying with concrete. There are holes in the profile to be able to attach the rice indicator to the PE-Foam with a special screw developed for this purpose.

The crack indicator is constructed in a fire-retardant material and with dimensions that prevent a fire in the tunnel from spreading to the insulation material.

The foot parts can advantageously provide a sliding surface to contribute to possible relative movement between the concrete vault and the insulation material.

In a preferred embodiment, the transverse dimension of the tear part increases towards the two foot parts in order to increase the stiffness of the tear indicator by forces affecting the tear part in a transverse direction, where said increase can advantageously be at least double.

The rib part can advantageously comprise a first and a second leg part so that the cross section of the rib part takes on a y-like shape suitable for forming an elongated space between the leg parts, and where the two leg parts are connected to each other's foot part.

The two foot parts can be arranged with an opening between them so that the elongated space is open in the longitudinal direction of the profile. A fire-extinguishing material can be arranged in the elongated space.

The leg parts can advantageously be dimensioned to allow relative movement of one foot part in relation to the other.

The two foot parts can be connected by an intermediate foot part between the foot parts so that the foot parts together form a continuous contact surface suitable for a form-fitting device against the insulation material.

The two foot parts and the middle foot part can have the same thickness to provide rigidity to the rib part above transverse forces and to the foot parts for transverse forces and displacements of the foot parts in relation to each other. Alternatively, the middle foot part can be thinner than the two foot parts to give combined stiffness and flexibility to the rice indicator in that the distance between the foot parts is not essentially allowed to increase over the length of the middle foot part, but is allowed to be reduced.

The rice indicator can form a massive body without internal spaces.

The groove part and the foot parts can respectively be designed with parallel side surfaces, where the foot parts are firstly arranged perpendicular to the groove part and secondly are directly connected, so that the cross-section of the profile forms a T-shape.

The foot parts can be provided with a plurality of holes for special screws with a head and core, where the screws are for attaching the crack indicator to the insulation material, where the size of the holes is smaller than the head, but the holes are larger than the core to provide the possibility of relative movement.

The crack indicator is constructed of flexible and fire-retardant rubber. The fire-retardant material can expand in the event of a fire, so that the fire-retardant effect increases.

Problems solved by invention

A main aim of the present invention is to provide a traffic tunnel designator and methods which overcome the problems mentioned above.

Purpose of the invention

The present invention solves problems with today's rice indicators.

The main purpose of the invention is to provide a crack indicator to control crack formation in concrete vaults during shrinkage of shotcrete. A more specific purpose is to improve the management of crack formation.

An overall purpose of the present solution is to achieve a traffic tunnel with improved properties. Said characteristics may be related to, among other things, security, availability, costs, complexity and logistics.

A central purpose is to increase safety in the event of fire in the tunnel. A more specific purpose in this context is to prevent the fire from spreading from the tunnel course, via cracks in the concrete vault and into the underlying, combustible material in the form of insulating, draining foam.

A further purpose is to provide a fire-proof joint without additional protection, for example by arranging sealant in the joint.

Another central purpose is to simplify procedures for the installation, operation and maintenance of traffic tunnels. More specific purpose in this context is to reduce the number of steps in the process for installing concrete vaults with roof indicators over underlying material.

An overall purpose of the invention is to reduce costs for installation, operation and maintenance of traffic tunnels. A further overall purpose is to simplify operations in connection with the installation, operation and maintenance of traffic tunnels.

Another purpose is to simplify maintenance and to increase the mechanical robustness of the solution when washing.

The means needed to solve the problems

The present invention achieves the goals set out above by a plan guide for traffic tunnels as defined in the introduction to the independent claims, with the characteristics of these.

A number of non-exhaustive embodiments, variants or alternatives of the invention are defined in the dependent claims.

The present invention achieves the goal set out above by a set of independent claims.

Brief description of the drawings

In the following, the invention will be described in more detail with reference to the drawings which show several examples of implementation, and where

- Figure 1 shows a cross-section of a traffic tunnel with a concrete vault

- Figure 2 shows a cross-section of a part of a concrete vault in a traffic tunnel where a drawing indicator has been mounted according to known technology

- Figure 3A shows a view of the reinforcement of a concrete vault in a traffic tunnel as in Figure 1, where a floor indicator according to the present invention is arranged - Figure 3B shows an enlarged view of Figure 3A where the floor indicator is arranged - Figures 4A-C show cross sections of part of a concrete vault in which a crack indicator according to the present invention was arranged with examples of alternative crack formation at the crack indicator after curing

- Figures 5A-C show projections of an embodiment of the present invention seen respectively obliquely from above, directly from above and directly from the side - Figure 6 shows a detailed cross-section of an embodiment of the present invention

- Figure 7 shows cross-sections of alternative embodiments of the present

invention

Review of the reference numbers that refer to the drawings Brief reference numbers used in the drawings are presented below:

Detailed description of the invention with reference to figures

In the following, the invention will be described in more detail with reference to the drawings which show several examples of implementation.

Figure 1 a cross-section of a traffic tunnel (1) in which a route indicator (10) is arranged which can be according to the state of the art or the present invention. In the tunnel (1), draining insulation material (5) in the form of PE foam is arranged on the tunnel's rock wall (2). The main purpose of said foam (5) is to divert leakage water from the rock (2) so that it does not overflow the path (3) in the tunnel (1), but rather is led down into longitudinal edge trenches near the transition between the rock wall (2) and the roadway (3) .

The PE foam (5) has good insulating properties that prevent the water from freezing and thus creating hanging ice in the tunnel (1).

The PE foam (5) is covered with concrete (4), which in the present case is shotcrete that is applied in a suitable thickness which can typically be approx. 80mm.

After the shotcrete (4) has been applied, it stands and hardens for a relatively long time, which can typically be a minimum of 28 days. During curing, the concrete (4) shrinks with cracking as a result. In order to control the formation of cracks, so-called crack indicators (10) are arranged in the concrete across the longitudinal direction of the tunnel (1) with appropriate intervals. The formation of cracks will occur primarily at the aforementioned rice indicators (10). The figures also show bolts (6) to anchor the concrete vault in the rock wall (2).

Figure 2 shows a mounted rice indicator (10) according to the state of the art, where the rice indicator (10) comprises an angle strip (L-shape) which is screwed into the PE foam (5) with a special screw (16). A felt is arranged under the rice indicator (10) to provide a sliding surface for the concrete vault in relation to the PE foam (5). When the strip (10) has been fitted and the reinforcement of the vault (4) is finished, the strip (10), the reinforcement and the PE foam (5) inside are sprayed with shotcrete (4). When the concrete (4) stands and hardens, a crack forms along the plastic angle (10) because the concrete (4) has shrunk. An opening (8) is then created with direct access to the PE foam (5). Due to the risk of fire, such an opening cannot be left open as it entails the risk that a possible fire could break through the opening (8) and set fire to the PE foam (5) which is behind the shotcrete (4). It has therefore been chosen to go back and fill the opening (8 in Figure 2) with a fire-retardant sealant (9 in Figure 2).

Figure 3A shows a drawing of reinforcement (7) of a concrete vault in a traffic tunnel as in Figure 1, where a drawing guide (10) according to the present invention is arranged. Figure 3B shows an enlarged view of Figure 3A where the line indicator (10) is arranged. When using crack indicators (10) according to the present invention, the reinforcement (7) can first be arranged continuously along the tunnel (1). The reinforcement (7) is attached to the bolts (6). The expansion joint can advantageously be placed centrally in relation to the fastening bolts (6) for little movement in the reinforcement (7). Then a groove is cut in the reinforcement (7) across the longitudinal direction of the tunnel (1) with suitable spaces for the arrangement of the rice indicator (10). The tear indicators (10) are then typically arranged by being attached to the underlying PE foam (5). The crack indicators (10) in combination with the cutting of the reinforcement (7) provide the possibility of relative movement between parts of the concrete vault (4) by controlled crack formation along the crack indicators (10). When using rice indicators (10) according to known technology, one must first arrange a felt, then a rice indicator before the reinforcement (7) is arranged against the rice indicator. This can cause problems in that one does not hit optimally with the reinforcement (7) in relation to the rice indicators (10).

Figures 4A-C show cross-sections of an embodiment of the present invention in the assembled state. Figure 4A shows a state shortly after spraying with concrete (4), while Figure 4B-C shows the state after hardening of said concrete (4). The figures illustrate that shortly after spraying, the concrete (4) will seal around the rice indicator (10), while after the concrete (4) has hardened, an expanded joint (8) will appear between the concrete (4) and the rice indicator (10). This is an expected effect that helps to control the formation of cracks in the concrete (4) and prevent the formation of cracks in places other than at the ridge indicators (10). The expanded joint (8) can be formed on any side of the rice indicator (10) as illustrated in Fig. 4A or also on both sides of the rice indicator (10) as illustrated in Fig. 4C. However, the crack formation (8) could have disadvantages, among other things, in connection with fire safety as previously described in relation to prior art.

The crack indicator (10) in the illustrated example of an embodiment essentially has a Y-shaped cross-section. The crack indicator (10) comprises a central crack part (11) which has a main function in forming the actual crack/crack (8) in the concrete (4), and two foot parts (12A-B). The slot part (11) protrudes in relation to the foot parts (12) and is thus arranged to be enclosed by shotcrete (4). The foot parts (12) are arranged to be able to rest against the PE foam (5) on one side and against the concrete vault (4) on the opposite side. The foot parts (12) of the rice indicator (10) can typically be designed to be attached to the PE foam (5). Furthermore, it is essential that the foot parts (12) are dimensioned to provide sufficient fire-retardant effect in relation to the underlying material (5), for example in the form of PE foam, and to provide possible longitudinal sliding of the concrete vault (4) in relation to The PE foam (5). Such sliding can typically take place from a center where the rice indicator (10) is located.

The design of the crack indicator (10) with foot parts (12) arranged as described above, ensures that cracks form where desired and that cracks at the crack indicator (10) do not become continuous from the tunnel run (1) into the PE foam (5). This is important in order to increase fire safety by preserving fire tightness in the event of cracks forming in rice cookers (10).

Figure 5A shows a projection of an embodiment of a rice indicator (10) seen obliquely from above. The crack indicator (10) forms an elongated profile suitable for being arranged against the PE foam (5) along the tunnel tunnel periphery across the tunnel tunnel's longitudinal direction. In the foot parts (12), there is a hole (15) suitable for passing through special screws (20) for attaching the rice indicator (10) to the PE foam (5) located behind. The crack indicator (10) is made of a material with a flexibility that allows adaptation to the curvature of the tunnel (1). This is described in more detail below.

Figure 5B shows a view of an embodiment of the rice indicator (10) seen directly from above. Here it is illustrated that the holes (15) for the passage of screws (20) are arranged in the foot parts (12) with a suitable distance in the longitudinal direction of the drawing indicator (10). Furthermore, holes (15) are arranged in the foot parts (12) on both sides of the rice indicator's rice part (11), where the holes (14) on the two sides are arranged in parallel in the longitudinal direction in relation to each other.

Figure 5C shows a view of an embodiment of the rice indicator (10) seen straight from the side across the longitudinal direction of the profile.

Figure 6 shows a cross-section of an embodiment of a rice indicator (10) across its longitudinal direction. The crack indicator (10) comprises a crack part (11) with a mainly Y-shaped cross-section. Furthermore, the drawing indicator (10) comprises two foot parts (12A-B) each with a contact surface for arrangement against the underlying material (5) and the overlying concrete vault (4). The slit part (11) comprises two leg parts (111A-B) which merge into the two foot parts (12A-B), and which help to form the Y-shaped cross-section. The slit part (11) with the leg parts (111A-B) contributes at the top of its Y-shape to form a space (14 in Figure 7). The space in the embodiment in Fig. 6 is open to the PE foam, while in Figure 7 a space is illustrated which is closed by a midfoot part (13).

In the cross-section of the foot parts (12), it appears that there is a hole (15) for a screw (16) to attach the rice indicator (10) to the underlying material. The screw (16) is a special screw suitable for screwing into PE foam. According to the present solution, the holes (15) are smaller than the head of the screw, but the holes (15) are significantly larger than the core of the screw (20), so that the possibility of relative movement in the form of sliding between the concrete vault (4) and the underlying PE- foam (5).

The Y-shape of the groove part (11), optionally with a closed space (17), helps to provide suitable rigidity to reduce the tendency of the groove part (11) to bend when sprayed with concrete. Furthermore, the leg parts (111A-B) of the Y-shaped drawing part (11) are arranged to provide flexibility in the form of transverse movement in relation to the longitudinal direction of the drawing guide (11).

Figures 7A-D show cross-sections of alternative embodiments of the rice indicator (10).

Figure 7A-B shows embodiments where the tread part (11) is Y-shaped, and where the tread guide comprises an intermediate foot part (13) which connects the two foot parts (12A-B). In both of these embodiments, the midfoot part (13) helps to form a substantially closed space (17) between it and the two leg parts (111A-B). Furthermore, the intermediate foot part (13) contributes to, together with the foot parts (12A-B), forming a continuous contact surface for the device against the substrate material.

The middle foot part (13) can have the same thickness as the foot parts (12) as shown in Fig. 7A; which contributes to rigidity in the transverse direction for the rice indicator (10). Alternatively, the middle foot part can have a smaller thickness than the two foot parts (12); which provides a substantially closed space (17) between the foot parts (12) and the midfoot part (13), and at the same time provides greater flexibility in the transverse direction than the solution with a thicker midfoot part (13).

The aforementioned room (17) can be utilized in alternative ways. It can, for example, be filled with fire-retardant material such as fire-extinguishing foam. More alternatively, the room can also be thought of as being used to convey a fluid, for example for temperature regulation. In an alternative embodiment that is not illustrated, the rice indicator (10) is solid in the sense that there is no open space, but that the leg parts (111A-B), the foot parts (12A-B) and the midfoot part (13) pass directly into each other.

Figures 7C-D show alternative embodiments where the rice indicator (10) has a mainly T-shaped cross-section formed by the rice part (11) and the two foot parts (12A-B).

The rice indicator's (10) parts can have different designs. The slit part (11) and the foot parts (12) can each essentially have the shape of elongated, rectangular parallelepipeds as illustrated in e.g. Figure 7C, or include lower parts with such a shape. The slot part (11) can have a dimension in the projecting direction in relation to the foot parts (12), which is at least as large as the planned thickness of the concrete vault. The slit part (11) is typically arranged perpendicular to the foot parts (12). The foot parts (12) are typically identical. The cross-section of the rice indicator (10) is typically symmetrical about a central axis in the cross-section of the rice part (11).

The crack indicator (10) is designed to help provide suitable properties both in terms of stiffness/flexibility, friction/stiction against relevant adjacent materials and fire-retardant properties. The combination of geometric design and material selection helps to provide such properties. The intermediate foot part (13) can be arranged to extend if the concrete is stuck in one or both foot parts (12); which contributes to the fact that the rice indicator (10) as a fire-preventing surface is not broken by the formation of cracks.

The crack indicator (10) can advantageously be made of a material with suitable properties both in relation to fire prevention, robustness and flexibility. The material can be a fire-retardant rubber. The rubber will typically have properties that prevent fire from breaking through the opening and reaching the PE foam. You can also choose to use a rubber that has an additional function that causes it to expand when exposed to heat (fire) and thus also seals the opening that has occurred due to the shrinkage of the concrete.

One has now succeeded in providing a rice guide (10) which creates a joint (8) in the shotcrete (4) which is fire protected without having to be jointed. The solution also has the mechanical strength to withstand the tunnel (1) being washed.

The material is also designed to provide flexibility so that it does not crack due to movements in the surrounding concrete (4). Robustness in relation to crack formation is important for fire-retardant properties. The solution is also robust for, among other things, both mechanical and chemical stress during washing of the tunnel bore (1).

In connection with a rice indicator (10) according to the invention, a method is provided for the arrangement of the rice indicator (10) where it is not necessary to refill with fire-retardant sealant (9), but which nevertheless provides a fire-proof solution. Furthermore, a method is provided for installation by continuous installation of reinforcement (7) without having to end this at the joint in connection with installation of foil under the crack indicator (10).

Claims (14)

Patent claims 1. Fire-resistant grating guide (10) for embedding in shotcrete construction (4) arranged against a combustible, draining insulation material (5) in a traffic tunnel (1), where the grating guide (10) forms an elongated profile with an essentially constant cross-section, where the grating guide (10 ) includes the following: - a crack part (11) suitable for helping to control the formation of a crack through the concrete structure (4) at the crack indicator (10), and - a first foot part (12A) arranged to be attached to the insulation material (5), where the first foot part (12A) projects on one side of the groove part (11) across it in relation to a longitudinal axis of the profile; the drawing indicator (10) comprises a second foot part (12B) which protrudes on the opposite side of the drawing part (11) in relation to the first foot part (12A), characterized by that the second foot part (12B) is also arranged to be attached to the insulating material (5); and where the crack indicator (10) is constructed of fire-retardant rubber with a flexibility that allows adaptation to the curvature of the tunnel (1), and which is sufficiently fire-resistant to prevent a fire in the tunnel (1) from spreading to the insulation material (5), for example in form of PE foam. 2. Crack guide according to claim 1, where the foot parts provide a sliding surface to contribute to possible relative movement between the concrete vault (4) and the insulation material (5). 3. Crack indicator according to one of claims 1 to 2, where the transverse dimension of the crack part (11) increases towards the two foot parts in order to increase the stiffness of the crack indicator (10) by forces affecting the crack part (11) in the transverse direction, where said increase is beneficial can be at least double that. 4. Crack indicator according to claim 3, where the crack part (11) comprises a first and a second leg part (111A-B) so that the cross section of the crack part gets a y-like shape suitable for forming an elongated space (17) between the leg parts (111A-B ), and where the two leg parts (111A-B) hang together with each foot part (12A-B). 5. Crack guide according to claim 4, where the two foot parts (12A-B) are arranged with an opening between them so that the elongated space (17) is open in the longitudinal direction of the profile 6. Crack indicator according to claim 5, where a fire-extinguishing material is arranged in the elongated space (17). 7. Tear indicator according to claim 5 or 6, where the leg parts (111A-B) are dimensioned to allow relative movement of one foot part (12A-B) in relation to the other. 8. Crack guide according to one of claims 1 to 4, where the two foot parts are connected by an intermediate foot part (13) between the foot parts (12A-B) so that the foot parts (12A-B, 13) together form a continuous contact surface suitable for form-fitting device against the insulation material (5). 9. Crack indicator according to claim 8, where the two foot parts (12A-B) and the middle foot part (13) have the same thickness to provide rigidity to the crack part (11) above transverse forces and to the foot parts for transverse forces and displacements of the foot parts (12A-B) ) in relation to each other. 10. Crack indicator according to claim 8, where the intermediate foot part (13) is thinner than the two foot parts (12A-B) to provide combined rigidity and flexibility to the crack indicator (10) in that the distance between the foot parts (12A-B) is essentially not allowed to increase over the length of the midfoot part (13), but that it is allowed to decrease. 11. Rice indicator according to one of claims 1 to 3, where the rice indicator (10) is a massive body without internal spaces. 12. Score indicator according to one of claims 1 to 2, where the score part (11) and the foot parts (12A-B) are respectively designed with parallel side surfaces, and where the foot parts are first arranged perpendicular to the score part (11) and secondly are direct connected, so that the cross-section of the profile forms a T-shape. 13. Tear indicator according to one of the above claims, where the foot parts (12A-B) are arranged with a plurality of holes (15) to help attach the tear indicator (10) to the insulation material (5), where the size of the holes (15) provides the possibility for relative movement between the crack indicator (10) and the insulation material (5). 14. Tear guide according to one of the above claims, where the fire-retardant rubber expands in case of fire so that the fire-retardant effect increases.