NO337239B1 - System and method for extracting smoke from road tunnels - Google Patents

Description

Technical Field:

The present invention relates to a module, a system and a method for extracting smoke from tunnels, particularly smoke development inside long road tunnels due to car accidents.

Background technique:

Accidents in tunnels are more dangerous than in the open air. An explosion or fire can cause significant damage, and hazardous substances cannot be removed quickly. Smoke causes poor visibility, lack of oxygen occurs quickly and panic can occur. The table below from the tunnel fire safety handbook from 2005 (Alan Beard & Richard Carrel) lists some of the tunnel accidents in recent years, and gives an insight into the tragic consequences of tunnel fires.

As a consequence, serious accidents related to smoke development in road tunnels have been a topic of discussion for ten years, and many solutions have been proposed in an attempt to reduce the consequences regarding smoke-developing accidents. Examples can be found in the publications DE 3117147 Al, DE 19825420 Al, DE 102004027761 Al, EP 1544408 Al, EP 1398461, KR 101088341 B, DE 102007040237 Al, US 4361079 and DE 7524273 U, which all describe solutions where the tunnels are equipped with a closed extraction duct which is connected to one or more ventilation devices. As explained in DE 3117146 Al, the use of smoke sensors placed along the tunnel will ensure the passage of smoke from the smoke source into a nearby, closable hole belonging to the extraction channel. The extracted smoke can be directed to the outside either vertically or longitudinally.

However, there are many tunnels around the world that have no, or insufficient, systems for smoke extraction, and some of these are of considerable length, for example over 1000 metres. To install a solution based on the solutions of the prior art mentioned above, i.e. to install a dedicated extraction duct having closable openings, high costs and considerable labor are required.

It is therefore an aim of the present invention to provide an assembly which ensures effective smoke extraction at or near the smoke source and which can be installed in existing and new tunnels in a simpler and more cost-effective way.

Summary of the invention:

The present invention is presented and characterized in the main claims, while the dependent claims describe other characteristics of the invention.

The invention relates in particular to a smoke extraction module, a smoke extraction system and a method for using such a system and which ensures the extraction of smoke from tunnels, in particular large road tunnels. The module comprises a channel for the transport of smoke, a suspension device which is at least indirectly connected to the channel to thereby ensure a suspension connection between the channel and the tunnel wall or the tunnel ceiling, as well as a disconnection mechanism which, when activated, is arranged to disconnect the channel from the suspension device so that a displacement of the channel is ensured. The displacement causes a longitudinal tilt relative to the neighboring channels. Hereafter, a tunnel shall be interpreted as including any cavity where a fire outbreak is considered to represent a danger to life and health for living individuals and/or is considered to represent a danger of causing serious material damage. Examples are road tunnels, train tunnels, mines, etc.

In a preferred embodiment, the channel remains suspended in the tunnel wall or tunnel ceiling after disconnection.

In another preferred embodiment, the disconnection mechanism comprises an activator such as a relay which is configured to receive signals from a smoke detector located inside the tunnel and which is configured to start the disconnection of the channel by, for example, the activation of one or more coils.

In another preferred embodiment, the disconnection mechanism further comprises a smoke detector for detecting smoke inside the tunnel. In an alternative embodiment, the smoke detector is a remote smoke detector which transmits signals to the receiver.

In another preferred embodiment, the disconnection mechanism further comprises a fastening device such as a locking bolt, while the module also comprises one or more support devices. The suspension device and the support device can advantageously be releasably connected by the fastening device. Furthermore, the suspension device and the support device can be rotatably connected, for example by using a hinge.

In another preferred embodiment, the disconnection mechanism comprises an activator configured to receive signals from a smoke detector located inside the tunnel, as well as one or more elongated objects such as a rod, a wire, a cable or the like extending between the fastening device and the activator.

In another preferred embodiment, the suspension device comprises one or more first hangers while the support device comprises one or more second hangers, where the first and second hangers are connected to the tunnel wall or the tunnel roof during use. In this embodiment, the second hanger can be connected to the module so that the channel remains suspended in the tunnel wall or tunnel roof after disconnection. The connection can be directly on the channel itself or on the support device.

The invention also relates to a smoke extraction system for extracting smoke from tunnels. The system comprises a plurality of smoke extraction modules according to the features described above which are mutually arranged in a row to form a channel which runs along the tunnel during use. The system also comprises an evacuation system arranged at at least one longitudinal end of the duct for extracting smoke.

In addition to the module and system mentioned above, the invention also relates to a method for disconnecting a smoke extraction module arranged in a smoke extraction system comprising a plurality of modules arranged in a row to form a channel that runs along the tunnel, where each module comprises a channel for transporting smoke and a suspension device which supports the channel from the tunnel wall. The method comprises the following steps: a) detecting a level of smoke that exceeds a preset value using a smoke detector and b) by means of an actuator activating a disconnection mechanism which disconnects the duct from the suspension device, thereby causing longitudinal displacement which

corresponds to a longitudinal bias relative to the nearby channels (2) In a preferred embodiment, the method also includes the step of transmitting signals from the smoke detector to an activator between step a) and step b), where said activator is configured to activate the disconnection mechanism.

All the method steps can preferably be controlled by using a common control unit.

Brief description of the figures:

Fig. 1 is a perspective view of a smoke extraction system according to the present invention placed in a tunnel, Fig. 2 shows several details of the smoke extraction system in fig. 1 where a fire situation has occurred below a smoke extraction module according to the invention, Fig. 3 shows the smoke extraction system in fig. 2 after a successful disconnection from nearby modules, Fig. 4 is a perspective view of the smoke extraction system in fig. 1 after a successful disconnection of the module from the neighboring modules, Fig. 5 is a perspective view of a smoke extraction module according to a first embodiment of the invention, before disconnection. Fig. 6 (a) and (b) are detailed views of a disconnection mechanism arranged on a smoke extraction module according to a first embodiment of the invention, where Fig. 6 (a) and fig. 6 (b) shows the disconnection mechanism respectively before and immediately after disconnection. Fig. 7 shows the smoke extraction module in fig. 4 after a successful disconnection has been carried out, Fig. 8 is a perspective view of a smoke extraction system according to the invention, including a smoke extraction unit arranged at each longitudinal end of an assembly of modules, Fig. 9 is a perspective view of a smoke extraction module according to a second embodiment of the invention , before disconnection. Fig. 10 shows the smoke extraction module in fig. 9 from an opposite radial side of the module, Fig. 11 is a detailed view of a part of the disconnection mechanism arranged on a smoke extraction module according to a second embodiment of the invention, before disconnection, Fig. 12 (a) and (b) are detailed views of another part of the disconnection mechanism arranged on a smoke extraction module according to a second embodiment of the invention, where fig. 12 (a) and (b) show the internal components with and without a disconnection activation coil, respectively, Fig. 13 is a detailed view of the disconnection mechanism arranged on a smoke extraction module according to a second embodiment of the invention, immediately after disconnection, and Fig 14 is a perspective view of the smoke extraction module of fig. 9 after completing a successful disconnection.

Detailed description of the invention

Figure 1 shows the inventive smoke extraction system 20 arranged inside a road tunnel prior to the implementation of any smoke extraction procedure. An extraction unit 21 in the form of a vacuum pump is arranged at a longitudinal side of a smoke guide link, which link consists of a plurality of smoke extraction modules 1,1' with channels 2,2' arranged in a row along the entire road tunnel. The pumping capacity of the vacuum pump 21 should be equal to or higher than the pumping capacity necessary to extract smoke from any place in the road tunnel to one or both ends of the guide link during at least one fire attack. The minimum required pump capacity will of course depend on parameters such as the length of the road tunnel, the mean diameter of the smoke guide link, the number of modules 1 in the guide link, etc. Fig. 2 shows more details of the smoke extraction system 20, where a single fire has started in a van located directly under a specific module 1, hereafter defined as the fire module 1. As is clear from the figure, the channels 2' belonging to nearby modules 1' during normal operation are arranged in gas-flowing connection with the channel 2 of the fire module 1, i.e. on each of its longitudinal sides. In order to be able to automatically detect and determine the position(s) of any fire inlet, a plurality of smoke detectors 9 are arranged at specific locations inside the tunnel, preferably at regular intervals along the entire length of the tunnel. In the specific embodiment in Figure 2, the smoke detectors are fixed to the tunnel wall 4, i.e. arranged remotely from the channels 2,2'. Alternatively, however, they can (or additionally) be attached to the channel itself. Figures 3 and 4 are corresponding views of the smoke extraction system 20 respectively in figures 1 and 2, where the fire module 1 has been disconnected from the remaining part of the smoke guide, thereby forming two open fluid channels which extend from the end of the adjacent modules 1' placed nearest the position of the fire inlet, to the corresponding vacuum pump 21.21'. The double arrows indicate the direction of the smoke 6 during pumping.

Details of two different disconnection mechanisms 5 for disconnecting the fire module 1 from the nearby modules 1' will now be described.

Figure 5 shows a first embodiment of the inventive module 1 where a stable suspension of the module 1 is ensured by the connection of two hangers 14, each of which is attached at one end to the tunnel roof/wall 4 and the other end to channel-encased locking collars 10,11 arranged near the longitudinal end of the channel 2. Furthermore, each locking collar 10,11 comprises an upper collar 10, a lower collar 11 and a disconnection mechanism 5 (indicated by a dashed square in Figure 5), where the disconnection mechanism enables a releasable connection between at least one of two opposite end pair belonging to the upper and lower collars 10,11 during normal / suspended position. The disconnection mechanism 5 comprises an activation device 7 arranged inside a cover 29 at the upper collar 10 and a bolt 8 (or any other releasable fastening device) which connects the two collars 10,11 at their ends. As better illustrated in Figures 6(a) and (b), the opposite ends of the upper and lower collars 10,11 include radial projections 18,18' with holes 32,33, at least the upper hole 32, belonging to the upper collar 18, has an inner diameter greater than the outer diameter of the bolt heads 8". The stem 8' of the bolt 8 is fixed to the lower projection by known means (threads, nuts, etc). When the bolt 8 is fixed to the lower projection 18' and extending through the upper hole 32 (figure 6 (a)), an end part 27 shaped like a fork is arranged to partially enclose the stem 8' of the bolt 8 directly below the bolt head 8", thereby also fixing the bolt 8 to the upper collar 10. The end member 27 remains in this locked position by means of a voltage controlled latching relay 34 which presses a spring (not shown) against the stem 8' of the bolt as long as no other tension is applied. Figure 6 (b) illustrates the situation when the locking relay 34 has been activated by the application of a specific voltage (or any other activation requirement for the specific locking relay). The end part 27 is retracted as a result of reduced pressure on the spring set up by a coil in the relay, and the bolt head 8' is pulled through the upper hole 32 by the force of gravity. The upper and lower collars 10, 11 are then disconnected, and the duct 2 of the fire module 1 gets the desired longitudinal displacement relative to the ducts 2' of the nearby modules 1' which start the smoke extraction. The double arrows 35 in Figures 6 (a) and 6 (b) indicate the direction of force to the end part 27 respectively without and with voltage applied to the locking relay 34. Figure 7 shows the equilibrium position after completed disconnection of a total of four disconnection mechanisms 5, i.e. one disconnection mechanism 5 for each end pair of the upper and lower collars 10,11, In this embodiment, two hangers 14,15 are used per longitudinal channel, the first and second hanger 14,15 are respectively fixed to the upper and lower collar 10,11.

Figure 8 shows an illustration of the smoke extraction system 20 comprehensively

- a smoke duct consisting of five modules 1.1',

- a vacuum pump 21,21' arranged at each end of the guide joint to pump out smoke 6,

a disconnection mechanism 5 fixed at both ends of each module 1,1' for

selectively shifting one or more corresponding channels 2,2',

smoke detectors 9 arranged along the entire length of the guide link and

a control unit 35 for controlling the operating parameters of the vacuum pumps 21, 21', the transmission signals to the smoke detectors 9 and the activation of the locking relays 34 placed inside the disconnection mechanisms 5.

With the specific setup, any module 1 can be disconnected from neighboring modules 1'. For example, if the smoke detectors 9 marked /'/' and/'v detect smoke 6 indicating one or more fires, signals will be sent that initiate the activation of one or more disconnection mechanisms 5 connected to the modules 2' located immediately above the activated smoke detector ( e) 9. From this it follows, with reference to Figure 8, that only the channels which are directly connected to the vacuum pumps 21, 21' and the central module 2 will remain in their original positions. In practice, the number of modules in a road tunnel will be significantly higher.

Figure 9 shows a second embodiment of the inventive smoke extraction module 1,1', before disconnection. As in the first embodiment (figure 5), a stable suspension of the module 1 is ensured by the connection to two hangers 14, each of which is attached at one end to the tunnel roof/wall 4 and the other end to channel-encased locking collars 10,11 arranged near it longitudinal end of the channel 2. Furthermore, each locking collar 10,11 comprises an upper collar 10, a lower collar 11 and a bolt (or any other releasable fastening device) which connects the two collars 10,11 at their ends. The opposite ends of the upper and lower collars 10,11 comprise upper and lower radial projections 18,18' with holes 32,33, both holes having an inner diameter greater than the outer diameter of the stem 8' of the bolt 8, but smaller than the outer diameter of the bolt head 8". The lower part of the stem 8' presents a radial hole. After the bolt 8 is passed through both holes 32,33 to the radial protrusions 18,18' so that the bolt head 8" rests on the upper radial projection 18, a suitable locking bolt 17 is inserted, thereby locking the ends of the two collars 10,11. An identical arrangement can be made on the radially opposite sides of the channel 2. However, in a preferred embodiment (Figure 10) the upper and lower collars 10,11 on this side are connected by pivoting hinges 16. Unlike in the first embodiment, the activation of the disconnection procedure takes place by a common activation mechanism 7 located at a distance from the bolts 8. A cable or rod 12 extends from each of the locking bolts 17 to the activation mechanism 7, which is shown in detail in Figure 11. Figures 12 (a) and (b) show the interior of the activation mechanism 7, where the ends of the cables/rods 12 are connected to a common tension-controlled coil 24 (figure 12 (a)), where the latter enables a pulling force on the cables 12 in the direction of each other in order to pull the cables a distance which is sufficient to extract the respective locking bolts 17. In the same way as for the first embodiment, the locking bolts 17 remain in place and therefore lock the two collars 10,11 as long as no tension is applied p to the coil 24. Figure 12 (b) shows the activation mechanism 7 with the coil 24 removed. A relay 13 can be seen located below the coil 24 which is electrically connected to the coil 24 and a smoke detector 9, the latter via electrical wires 23. It follows that when the smoke detector 9 detects smoke 6 above a predefined smoke density, a signal is transmitted through the wires 23 which activates the relay 13, which in turn applies the necessary tension to the coil 24 to be able to pull the locking bolts 17 out of the bolts 8 (figure 13). Figure 14 shows the equilibrium position after a completed disconnection of a total of two disconnection mechanisms 5, i.e. one disconnection mechanism 5 for one or two pairs of upper and lower collars 10,11. Also in this embodiment, two hangers 14,15 are used per longitudinal channel, where the first and second hangers 14,15 are fixed to the upper and lower collar, respectively.

In the preceding description, various aspects of the module, system and method according to the invention have been described with reference to the illustrative embodiments. For purposes of explanation, specific numbers, systems and configurations have been explained to provide a complete understanding of the device and its operation. However, this description is not intended to be limiting in any way. Various modifications and variations of the illustrated embodiments, as well as other embodiments of the device, which are obvious to persons with knowledge in the field described, shall also be considered to lie within the scope of the present invention.

Claims (14)

1. A smoke extraction module (1) for use in a smoke extraction system (20) comprising a plurality of smoke extraction modules (1) which ensure the extraction of smoke (6) from tunnels, the module (1) ) comprises - a channel (2) for transporting smoke (6), - a suspension device (10) which is at least indirectly connected to the channel (2) and which ensures a suspension connection between the channel (2) and the tunnel wall or tunnel roof (4), characterized in that the module (1) further comprises - a disconnection mechanism (5) which, when activated by an activator, is arranged to disconnect the channel (2) from the suspension device (10) so that a displacement of the channel (2) is enabled relative to nearby channels (2 ) during use of the smoke extraction system (20) in that the displacement of the duct causes a longitudinal skew relative to the nearby ducts (2). 2. The smoke extraction module (1) according to claim 1, characterized in that the channel (2) remains suspended in the tunnel wall or the tunnel ceiling (4) after disconnection. 3. The smoke extraction module (1) according to one of the preceding claims, characterized in that the disconnection mechanism (5) comprises - the activator (13) is configured to receive signals from a smoke detector (9) located inside the tunnel, the activator (13) is configured to initiate the disconnection of channel (2). 4. The smoke extraction module (1) according to one of the preceding claims, characterized in that the disconnection mechanism (5) further comprises a smoke detector (9) for detection of smoke (6) inside the tunnel. 5. The smoke extraction module (1) according to one of the preceding claims, characterized in that the disconnection mechanism (5) further comprises a fastening device (8) and that the module (1) further comprises a support device (11), where the suspension device (10) and the support device (11) is releasably connected by the fastening device (8). 6. The smoke extraction module (1) according to claim 5, characterized in that the suspension device (10) and the support device (11) are rotatably connected. 7. The smoke extraction module (1) according to claim 5 or 6, characterized in that the disconnection mechanism (5) comprises - the activator (13) configured to receive signals from a smoke detector (9) placed inside the tunnel and - an elongated object (12 ) continuously between the fastening device (8) and the activator (13). 8. The smoke extraction module (1) according to any one of claims 5-7, characterized in that the suspension device (10) comprises a first hanger (14) and the support device (11) comprises a second hanger (15), where the first and other hangers (14, 15) are connected to the tunnel wall or tunnel roof (4) during use. 9. The smoke extraction module (1) according to claim 8, characterized in that the second hanger (15) is connected to the module (1) so that the channel (2) remains suspended in the tunnel wall or tunnel roof (4) after disconnection. 10. A smoke extraction system (20) for extracting smoke (6) from tunnels, characterized in that the system (20) comprises a plurality of smoke extraction modules (1) according to one of claims 1-9 mutually arranged in a row for to form a channel which runs along the tunnel during use, where the system (20) further comprises an evacuation system (21, 21') arranged at at least one longitudinal end of the channel for extracting smoke (6). 11. The system (20) according to claim 10, characterized in that the displacement of the channel (2) causes a longitudinal misalignment relative to two nearby channels (2'). 12. Method for disconnecting a smoke extraction module (1) arranged in a smoke extraction system (20) comprising a plurality of modules (1) arranged in a row to form a channel that runs along the tunnel, where each module (1) comprises a channel (2) for transporting smoke and a suspension device (10) which supports the channel (2) from the tunnel wall (4), characterized in that the method comprises the following steps: a) detecting a level of smoke ( 6) that exceeds a preset value using a smoke detector (9) and b) by an activator to activate a disconnection mechanism (5) which disconnects the duct (2) from the suspension device (10), thereby causing a displacement of the duct corresponding to a longitudinal bias relative to the nearby channels (2) 13. Method according to claim 12, characterized by transmission of signals from the smoke detector (9) to the activator (13) between step a) and step b), said activator (13) is configured to activate the disconnection mechanism (5). 14. Method according to claim 12 or 13, characterized in that the module (1) is according to one of claims 1-9.