JP2001508685A - Emergency evacuation system - Google Patents

Abstract

(57) [Summary] Emergency evacuation systems use three main concepts-delayed free descent, transient structures and energetics-to provide quick and safe rescue. An inflatable downcomer section (3) with an inlet opening is located along the side of the structure or at the top of the elevator shaft. In an emergency, a gas generator connected to the tubing is activated to inflate the tubing with gas. The inner surface of the tube includes energy absorbing structures (5, 7, 11) strategically placed to slow the rate of descent. These structures absorb energy from the descending body and transfer part of the vertical force to horizontal force by the evacuees temporarily deflecting sideways within the vessel. Threads due to friction cover the surface of the structure to further reduce the speed of the evacuees. An inflatable exit ramp (17) is located at the bottom of the tube to ease evacuees' descent and guides evacuees to the shelter. A backup system including an annulus of the high-pressure water nozzle is installed in the pipe to prevent evacuees from accelerating in the event of a failure of the internal structure. The system can be installed as a single unit or disassembled into multiple tube sections. The number and location of the inlet openings will vary depending on the situational needs of the structure to which the system is attached. The invention has many configurations, including fixed internal and external equipment, ground and airborne rescue units, and the like, and has similar configurations for marine applications.

Description

DETAILED DESCRIPTION OF THE INVENTION                             Emergency evacuation system                                Background of the Invention   The invention is a building, Emergency evacuation systems for ships and other fixed and movable structures Regarding the stem.   People work and live normally in high places that do not allow safe free descent in emergencies . Ladder is often not available or inappropriate at height. From the window or on the roof In most cases, The only defensive option. In fact The Any descent over 5m will result in damage or death with an unavoidable probability You. Selective evacuation plans for individuals such as helicopter escape from the rooftop take time Kari, Dangerous Also fire, explosion, Often due to surrounding structures and weather, It is possible.   Emergencies such as fires often limit escape options. Emergency disorder Introductory and disruptive situations increase evacuation frequency and delay rescue. Downstairs with fire The steps are Excessive numbers of excited people rush to the exit and push each other to gain safety Combine, Tripping can be a dangerous experience. Heat and toxic gases make evacuation more difficult I do. There is a need for a system that provides a quick and easy escape route.   Recent emergencies throughout the United States have indicated the need for faster evacuation systems. During the New York World Trade Center explosion, Rescue work to evict the building The workers took more than 5 hours. With no smoke and no power, Other evacuation conditions are ideal So Was. No fire, There were no consecutive threats. Buildings are strong structurally safe Had. Highly trained and well equipped emergency services and easy access to personnel did it. Fire, Under non-ideal situations with smoke and continuous threats, Lose a lot of lives Must have been inevitable.   Regardless of the situation, World Trade Center in substantially less time than existing systems There is a need for an evacuation system that can be evacuated from structures corresponding to the size of the forest.   New evacuation systems must be compatible with existing structures. new Evacuation system equipment Existing structure must be economically viable Should not require a wide range of changes. Moreover, Cheap All equipment cannot interfere with the other functional appearance of the building, Also, Not working Sometimes the aesthetic wholeness of the structure must never be destroyed.   Existing emergency descent systems are inadequate. Most systems are permanent fixed structures Use Relies on springs and hydraulics to reduce evacuee descent rates. Simple There is a need for a simple and inexpensive mobile evacuation system.                                Summary of the Invention   The emergency evacuation system disclosed herein is useful for fixed and movable structures. You. The invention relates to fixed and / or movable internal or external equipment, Upright in the ground Mobile rescue unit, Several different configurations, including configurations for offshore and offshore use have. The benefits of this system are reduced costs compared to other evacuation methods, Time and climate Independence, Minimum risk, Possibility of high-speed evacuation, And for basic use of existing structures Includes easy installation without interference.   The invention has three basic concepts: Ie delayed free descent, Transient structures and d Including nursing.   The delayed free fall (RFF) This is the core concept of this system. Jumping high It is the easiest and fastest way to descend. Unfortunately, Typical When an adult jumps out of a building, Humans depend on weight and surface area, but about 160 fps Fall at the end speed of the eat. Sudden deceleration from this speed is not desirable. No. The saying that kills you is not a fall but a sudden stop is hard to refute . The RFF will slow down or slow the acceleration of evacuees, causing damage to evacuees. A technique that extends free fall without significant risk of injury. Generally, Fall Only two techniques to slow or disable body acceleration: In other words, a reverse propulsion rocket Thrust, as provided by And a body that wears a parachute on the body This is a technology to increase the surface area of the surface. This invention is energy absorption, Energy replacement And In extreme situations use principles such as thrust applied via high pressure jets You. High-pressure jets can be integrated into the system using water towers or emergency service fire engines. Can be a jet of water incorporated.   Energy absorption in the present invention is: Impact of evacuees during descent and at the end of descent Achieved by applying to various flexible structures Is done. Basically, Energy absorption is Temporarily replace gas with inflated structure From the cushioning effect From contacts that absorb repeated shocks, Also additional energy From the point of friction with flexible laces extending from the cushion pads that absorb the lugies Occurs. These characteristics are combined to slow the rate of descent.   The internal structure of the downcomer section of the present invention is an energy absorbing structure that slows down speed: In other words, deflector bulge, Inflatable padding, Deflector slope, Diff Includes lectre curtain and exit slide. In addition to absorbing energy, This structure In the construction, some vertical force is converted to horizontal force so that the evacuees are temporarily turned sideways Convert. This is what is meant by energy substitution. Deflector car Tens try to increase the resistance of descending evacuees. Rather than having a smooth surface, Curtains function to reduce the speed of evacuees passing through. It is serrated with small projections. The internal structure hinders the evacuees from accelerating, Also, never let the descending evacuees increase significantly in speed. It is a refugee Increases the likelihood of escape from an emergency intact or virtually intact.   In situations where internal structures collapse, Automated fail-safe backup system Is activated. Backup system is high pressure absorbing energy of evacuees Including the use of water jets.   The second concept included in the present invention is: Transient structures (TS). This invention Even if you use It needs fixed structures Without Rather, only transient or latent structures are required. At least already Upgrade or replace existing elevator shafts or new construction When doing The equipment of the present invention is effectively invisible, It also interferes with normal driving Not. This invention does not apply any load except for the capacity to accommodate evacuees during emergency transportation. And is mainly composed of synthetic fibers / fabrics.   The standard equipment of the present invention involves an interlocked multiple inflatable configuration. The structure is supported, Also In one configuration, it is braced against an existing wall, such as an elevator shaft wall, Thus During the expansion process, The invention provides structural security and provides support in use.   The evacuation system can be integrated into multiple modules or disassembled Can be equipped. The unit extends to the height of the first floor or multi-story Can be. The units of the preferred system extend to four or five floors.   The system can be designed for single use or multiple evacuation. This The material of the invention of the invention has tear resistance and dielectric breakdown resistance, Over a wide temperature range It is flexible and strong. Some important units or subassemblies of the invention The engine will not work in situations where the system may be damaged or damaged. Emergency backup systems that use forms can be included. Located on the first floor The termination / exit assembly of the present invention is an assembly so protected .   The third concept included in the present invention is energetics (E). Energies Technology has been used on the private stage A relatively old technology for military applications.   Energetics is basically a chemical reaction that involves Mostly monopropellants Combustion similar to a rocket, Here, rapid expansion of gas (exhaust) expands the structure. Used to inflate or perform some limited task. Energete One such civil use of ix is in automotive airbags. Energete A more general name for the functional unit is the gas bag generator (G BG). The advantages of GBG are its reliability, Its maintainer for a considerable period of time Negligible or nonexistent Its almost immediate start-up and quick service Includes cycle completion performance. GBG produces a fixed amount of gas at a preset pressure Assemble to order. If the resulting combustion exhaust gas is inert, Emergency letter The advantages in the context are clear. GBG is built into the application object, Also normal cheap The GBG can be forgotten except in the case of a full check. Pressure is required in this invention Because it is not formed until There is no need to finish the pressure vessel. Inflatable bra This invention uses a pressure vessel, except for a temporary backup storage unit consisting of do not do.   The system works with immediate inflation on request. Power supply required Not. Rather, only solid igniters with normal control mechanisms and safety systems is necessary. The complete expansion of the present invention takes less than 90 seconds, regardless of size. add to Ability Provides continuous inflation for a limited time in case of limited system damage To be incorporated into this system.   This invention lowers the cost of existing structures, Without interfering with the intended use Combine several unique features that greatly enhance the safety of evacuees. This The stem is not necessarily limited to that, building, Offshore platform, Mine stand Pit, And uniquely suitable for use on almost any fixed or movable structure, including ships are doing. The independent rescue and extraction model of the present invention provides a permanent system before a catastrophe. It can be used for structures that are not equipped with a system. In addition, this system For personal use Due to lack of training, Or current evacuation or insertion technology for conflicting environments Suitable for special driving charges from aircraft in inappropriate situations.   These and other objects and features of the invention are: Described above and below It will be evident from the following specification and disclosure including the claims and drawings.                             BRIEF DESCRIPTION OF THE FIGURES   Figure 1 shows the friction point, Pipe section with splashing bulge and turning slope, And 1 shows an embodiment of the invention having an outlet ramp.   FIG. 2 is a sectional view of the tube taken along line 2-2 of FIG. The inner surface of the tube 2 shows a turning slope extending inward.   FIG. 3 is a cross-sectional view taken along line 3-3 of FIG. Inside from the inner surface of the tube It shows a bulge that stretches out.   FIG. 4 is a cross-sectional view of the tube taken along line 4-4 of FIG. The inner surface of the pipe Indicates a friction point extending from the inside to the inside.   Figure 5 shows a turning slope that extends inward from the inner surface of the tube, Inflatable cushion And shows one embodiment of a section of a tube section having a rebound bulge.   FIG. 6 is a cross-sectional view of the tube taken along line 6-6 in FIG.   FIG. 7 is a front elevation of the tube section of FIG. 5 showing the turning slope and the inflatable cushion. FIG.   FIG. 8 is a cross-sectional side view of an embodiment of a turning slope having a valve and a friction assistor. It is an illustration.   FIG. 9 is an end elevation view of the turning slope of FIG.   FIG. 10 is a detailed view of the turning slope surface of FIG. 8 showing a friction assistor.   FIG. 11 is a detailed view of the spring operation and energy absorption of the turning slope.   FIG. 12 is a front elevational view of the outlet ramp and lower portion of the tube.   FIG. 13 is a side elevation view of the outlet ramp and tube of FIG.   FIG. 14 shows the configuration in the left unused position and the configuration in the right usage position. 1 shows the external equipment according to the invention of FIG.   FIG. 15 shows the outer multiple access of the left and right non-use and use configurations. FIG. In addition, the central entrance opening and deflector are shown graphically. You.   FIG. 16 shows this configuration in a configuration in a non-use configuration and a configuration in a use configuration, respectively. Figure 7 illustrates a light outer window access embodiment.   FIG. 17 is a detailed view of the outer window access embodiment of FIG. Dense 3 shows a closed combing adapter.   FIG. 18a, 18b and 18c are the outer window access shown in FIGS. In embodiments the membrane and heat shield are stored, Expanding and enlarged plan view The details are shown below.   FIG. 19a, 19b and 19c are in storage state, respectively. Partial working condition and full FIG. 3 shows a detail of a side view of the outer window access embodiment of the invention in operation.   FIG. 20a, 20b and 20c are in storage state, respectively. Partial working condition and full FIG. 3 shows a detail of a plan view of the outer window access embodiment of the invention in operation.   FIG. 21 shows details of a membrane having a pressure cross beam.   FIG. 22a, 22b and 22c are outer casings that form a heat shield upon activation. Indicate   FIG. 23a, 23b and 23c are external to the invention in different activated states. FIG. 4 is a partial plan view of the placed embodiment.   FIG. 24 is a plan view of a segment installed outside in a completely used state.   FIG. 25 is a detailed side elevational view of an activated window access embodiment of the present invention having reinforced cross beams. It is.   FIG. 26 is a detailed sectional view of the enlarged film showing the reinforced cross beam.   FIG. 27 is a detailed cross-sectional view of the tube showing the strengthened cross beam fixed in place.   FIG. 28 is a detailed sectional view of an external installation portion of the present invention.   FIG. 29a, 29b, 29c and 29d are progressive changes in the turning slope of the pipe. The combination plan and elevation detail of the shape You.   FIG. 30 shows an emergency water jet brake system installed around the inner surface of the pipe. Show stem.   FIG. 31 shows a deflector inclined portion, Deflector curtain, Bounce back bulge Illustrates an embodiment of an elevator shaft installation of the present invention having a sloping portion and a corrugated outlet. Show.   FIG. 32 shows the output of the embodiment of the elevator shaft installation of FIG. 31 before operation of the system. Indicates the mouth level.   FIG. 33 is a front elevational view of the lower end of the tube and the corrugated outlet ramp of FIG.   FIG. 34 is a top elevation view of the embodiment of the elevator shaft installation of FIG.   FIG. 35 shows a falling wall, Corrugated exit feed, Deflector curtain, Deflector Ramp, Use Elevator of this invention with bounce bulge and inflated padding An example of installation of a rotor shaft is shown.   FIG. 36 shows the evacuee descent route of the embodiment of FIG. 35 in detail.   Figure 37 shows the bulge splashed back, Deflector curtain and deflector tilt Fig. 7 shows entry of an evacuee to an installation example of a use attitude elevator shaft having a slope.   FIG. 38 shows a cushioned deflector connected to the slope edge of the deflector ramp. Fig. 4 is an illustration of a side of a turning slope having a reflector curtain.   Fig. 39 shows an elevator door with a descending entrance with a cold light edge. A.   Figure 40 shows an elevator system with an exit ramp and a fail-safe brake jet. Figure 3 shows the exit level of a working example of setting up a raft.   FIG. 41 is a cross-sectional view of the elevator shaft taken along line ee in FIG. 40. is there.   FIG. 42 shows a feeder, Spraying equipment, With lift and inflatable pendulum barrier -Shows in detail the outlet end of a shaft installation embodiment;   FIG. 43 is a plan view of one downcomer section of the embodiment in which the elevator shaft is installed.   FIG. 44 is a detailed view of the downcomer portion of FIG. 43 on the cushion side.   FIG. 45 illustrates a cross section of the deflector bulge.   FIG. 46 is a detailed view of the outer surface of the bulge of FIG.   FIG. 47 shows a positive view of a friction assister having nine hollow cushioned shafts for escape. FIG.   FIG. 48 shows a friction twisted yarn, Single with inflation cushion and escape retention and inflation point It is a detailed view of a hollow shaft with one escape cushion.   Figure 49 shows the pipe section when the elevator cannot descend to the bottom of the elevator shaft. 5 shows the bottom of a modified elevator car that functions as a segment of the car.   FIG. 50 is a side elevation view of the elevator of FIG.   FIG. 51 shows a monopropellant generator, Control device, Automatic valve and transient expansion 1 is a schematic view of a generator facility having a pressure storage device.   FIG. 52 schematically shows a sea-based evacuation system.   FIG. 53 is a schematic diagram showing a sea-based evacuation system viewed from the side of a ship.   Figure 54 extends downward from the ship's deck and arcs away from the ship's side Figure 3 shows a marine evacuation system with a lower part.   FIG. 55 graphically illustrates a gas piston extending from the side of the vessel to inflate the tube. Show.   FIG. 56 shows a lifting gas bag, Gas bag generator, And the side of the structure Emergency service evacuation system with fixed guide cable to lift pipe section Shown in form.   FIG. 57 is a side elevation view of the embodiment of FIG.   Figure 58 shows the emergency service evacuation system temporarily set up for use on the side of the building. The stem is shown graphically.   FIG. 59 is a side view of the wall walker unit attached to the wall of the structure. .   FIG. 60 is a front view of the wall walker unit of FIG.   Figure 61 shows two gas generators located at the top of the elevator shaft Is shown.   FIG. 62 is an instruction panel for transmitting instructions for using the evacuation system. You.   FIG. 63 shows the use explanation panel of FIG. 62 arranged on the wall around the elevator door. Show.                        Detailed description of the preferred embodiment   Referring to FIGS. 1-13, The present invention relates to a porcelain inflatable by a gas generator. Combination of pipe sections. When the system is not working, The tube is flat and conspicuous In a state of absence. When activated, Gas generator puts gas into pipe Send Inflates the tube rapidly. Once inflated, Evacuees 3 are predetermined Enter the entrance opening, It descends through the tube 3. As shown in FIG. 2-4, friction Assister 5, The rebound bulge 7 and the turning slope 11 are inside the pipe 3 Extend side by side inward from the surface, Guides and slows the body as it descends the tube Make The evacuee safely descends through the pipe 3 and moves the bottom of the pipe 3 toward the evacuation center. Get out. This system is compatible with existing structures. For new constructs, The prefabricated tube section 3 can be manufactured into prefabricated building panels, In addition, gas generator The data can be installed in appropriate places. This invention is external as well as internal Suitable for use.   In a preferred embodiment, Emergency evacuation systems include external attachments to the structure. It is arranged. The deflated tube 3 may be a pre-packaged segment 13 or module. Come in as a tool. One segment is shown in FIG. Assembled pipe section 3 changed It can be connected with other segments 13 to create a continuous tube section 3 of possible length. this The preferred embodiment of the invention has a length ranging from one to four floors. The segment 13 having the length is used. The segment 13 that forms the prefabricated pipe section 3 is Such a structure is attached to the holding point 15 with appropriate climate and structure. Possible retention Point 15 is not necessarily limited to that, Simple bolt, Adhesive, Piston and And a hole filled with a coagulation compound. The segment 13 of the tube 3 is created by a gas generator. It remains deflated until it moves. When activated, the generator segments the gas Send to 13, The segment 13 expands outward from the structure to form a continuous tube 3. Desiring H The pressure of the pipe 3 is set at 30 to maintain the structural rigidity of the pipe 3 and to prevent backflow from fire. Maintained at psi. Evacuees enter the tube through a predetermined entrance opening. As shown in FIGS. 12-13, Exit ramp 17 provides cushioning for evacuees to descend It is arranged at the bottom of the tube portion 3. The padded cushion 9 is attached to the tube 3 line up.   Another preferred embodiment of the present invention is an easy-to-handle inlet opening as shown in FIG. It has a mouth 21. As shown in FIG. The entrance opening 21 is located on the roof, So Therefore, the evacuees can descend to the ground through the pipe 3 without being disturbed. This fruit The examples are inexpensive and easy to install. System to have a single inlet opening System reliability increases, Due to evacuees' actions or partial system failure Reduce the likelihood of congestion in the resulting system. However, a single entrance opening Clearly limit the number of people who can serve. Single point entrance opening also increases evacuation time I do. A variation of the single point inlet opening embodiment of the present invention is that the inlet point is located at the middle of the length of the tube 3. Place at a point.   A second preferred embodiment of the external attachment system is on the wall of the structure to which the system attaches. Has one or multiple entrance openings. FIG. 15 shows this source with multiple entry openings 21. An example is shown.   A third preferred external embodiment is the existing window space 25 located on the wall of the structure. Is used as the window entrance opening 27. FIG. 16 shows a non-use state and a use state. This embodiment of the configuration is shown. As shown in FIG. Windows are removed from window space 25 I will The window combing adapter 29 is located around the outer edge 31 of the window space 25. Be placed. The triple expanded transparent or opaque film 33 is a combing adapter The window window 25 is extended between the side surfaces of the windows 29. Combing adapter 29 The tube 3 is made continuous as shown at 16 and 17. Example of window entrance Installation is economical, Can be applied to most large structures, All people To evacuate rapidly from all floors, Easy to incorporate into new structures Retrofit existing structures easily.   Preferably, The membrane 33 of the embodiment of the window entrance portion is independently formed as shown in FIGS. It is triple with an expansion gas bag between each layer that can be expanded, For this reason Provides full redundancy.   The membrane 33 and the adapter 29 are, as shown in FIGS. Upper part of tube part 3 And at the lower segment 13 are physically continuous. Activation of upper and lower section 13 Helps the window opening 25 to be used. However, the window opening inflation system is For reasons it is a separate unit. Quickly removable internal transparent shield 35 is activated Until it is fixed in place. Shield 35 before operation Prevent membrane damage due to destruction or accident. As shown in FIGS. 18-24, Once the system is working, The shield 35 is separated at the center and The diaphragm vibrates outward toward each side of the window opening 25. The arm of the shield 35 is a butterfly Can be stopped. Shield 35 provides a pressure seal that allows expansion of membrane 33. Shi The field 35 becomes a heat shield for protecting the tube section 3 when separated, Evacuation by this Extend the time. As shown in FIGS. 18 and 20, This invention is an internal seal And an external shield 41. The film 33 is connected to the inner shield 35 and the outer It is between the unit shields 41. When activated, The inner shield 35 is separated at the center and Open in the direction. The outer shield is also separated at the center when the membrane 33 expands outward, Move in the direction. As shown in FIGS. 23 and 24, The external reinforcement 43 provides structural rigidity to the pipe. It is arranged on the outer surface of the tube part 3 for giving.   Additional security options are available in the window entrance opening embodiment. In the preferred embodiment And An override lock 42, which can be operated from a remote or adjacent location, Shield 35 to prevent the opening of the 41. Overridero The lock is Area closest to access point is potentially hazardous to user due to emergency Is designed to refuse entry when it is. Rock is the last thing on the floor Operated by hand by evacuees Or, search for harmful heat or toxic gas conditions. Can be operated automatically when notified.   Preferably, As shown in FIGS. 25-27, Carbon fiber composite beam 47 is membrane 3 3 is incorporated into the structure. Cross beam 47 is triple It is located on the central layer 49 of the film 33. The cross beam 47 Help expand the membrane 33, Once again When ready for use, it provides the membrane 33 with shape and rigidity. Cross beam 47 is flexible in horizontal plane But rigid in the vertical. The cross beam 47 is desirably flattened oval in cross section You. This cross-sectional shape shows the evacuees caught in the tube 3 in the case of partial tube damage. Limit the likelihood. The cross beam 47 may be partially broken during the expansion cycle or a subsequent tube. Combined vertically with reinforced panels to keep evacuees in the tube in case of destruction of part 3 . The cross beams 47 are stored in the wall channel in the form of flat loops. In Figure 25-27 As shown, When the invention is activated, The cross beam 47 is outside by the expanding film 33. Pulled to the side. When the membrane 33 is fully expanded, Cross beams 47 are fixed in place . Cross beam locking groove is trapped in spring-loaded ratchet lock system . The outermost point from the structure to which the pipe 3 is attached at the center of each cross beam 47 is shown in FIG. Joint 51. The joint 51 of each cross beam 47 has an oval cross section in the pipe 3. Enable you to   All outdoor installation new evacuation systems (life step systems) have common features Share. One common feature is the outer shape formed from the casing of the compression assembly. The partial heat shield 41. When the system is activated, Shield 41 is outside center Open sideways. The tube 3 brought into the casing expands and further extends the wall of the casing. Press outside. Heat shield 41 has many advantages, For example, thermal resistance in a fire situation, Obstacles to see inside the pipe from a favorable point in the evacuation structure (terrorists and The tremendous benefits of the criminal's flight), Protection of the pipe section from wind drift, The effect of buffeting and explosion, And provide structural rigidity.   A second common feature of all outdoor installation embodiments of the present invention is that Progressive deformation shoe This is an internal device of the pipe section 3 referred to as a slide (PDCS). Figure 1 5 And 28 show the preferred embodiment of PDCS. PDCS splashed back bulge 7, Turning slope 11, Using the padding cushion 9 and the friction assister 5, All of these extend from the walls of each segment 13 of the tube section 3 to guide the descent and slow it down. You. Bulge 7, Slope 11, Cushion 9 and friction assister 5 are each segment 1 3 systematically arranged on the wall. FIG. 5 shows a preferred embodiment of the PDCS. Diff The positions of the rectifier bulge 7 and the turning slope 11 correspond to the entire length of the pipe section 3. do it, The front part 55 of the tube part 3 is replaced with the rear part 57 of the tube part 3 in order. This configuration descends Refugees in the central zone of the pipe section 3, Keep evacuees in a virtually vertical position, Thus, the likelihood of congestion and damage is reduced. Friction assister shown in FIGS. 8-10 5 extends from the turning slope 11 and the deflector bulge 7. Evacuees are pipes When descending through 3, The evacuee collides with the turning slope 11. As shown in FIG. To be, The turning slope 11 is deformed and bent downward, Thus of tension Absorb energy through accumulation. The turning slope 11 is shown in FIG. Basically form a saddle with slope, Pass evacuees to the next level. Evacuation Then absorbs energy and guides evacuees to the next turn slope 11 Then, it comes into contact with the bulge 7. Once the evacuees are engaged with the turning slope 11 When we union, Slope 11 is not deformed in its original Bounce back into position. As shown in FIG. The wall of the tube 3 makes safe evacuation easier You can have a side deflector cushion to do so.   Preferably, Each turning slope 11 is designed with a fixed deformation / bounce ratio Is done. This means that all evacuees descend at a reasonably similar rate, Evacuees are pipe 3 Make sure you do not overtake others within.   Splashing with the inflatable turning slope 11 which constitutes the internal structure of the segment 13 of the tube 3 Each segment 13 of the tube section 3 including the back bulge 7 has a flange as shown in FIGS. The upper valve 61 is provided. The flapper valve 61 The evacuees' collision force is Errors due to congestion or structural damage that provide normal feedback within the system Releasing air when safety limits are exceeded (indicating excess weight or speed) Absorb excess energy from more descending evacuees. Air release is in front of the upper Prevent damage to turning slope 11 from overload due to turning slope failure . Furthermore, the discharge air is directed upward, Reduce the speed of evacuees, Apply to the total pressure of the tube section 3 You.   The preferred embodiment of the outdoor installation of the present invention has an irregular oval cross section. this The configuration increases the warpage of the wind and fire hose water flow to reduce distortion and damage to the pipe due to external forces. Minimize. In addition, the oval shape is used to maintain proper orientation of descending evacuees Useful.   A third feature common to all outdoor embodiments of the present invention is the use of an inflatable feeder or the like. Such an expansion outlet inclined portion 17. Inclined part 17 Is located at the bottom outlet of the tube 3. Figure 1, 12-13, 33 and 42 are inclined parts 3 shows different embodiments.   As shown in FIGS. 30 and 42, The external and internal thermal spray devices 63 are It can be easily incorporated into the embodiment. This device 63 reduces the risk of heat, Poisonous moth Eliminate the existence of It is also advantageous to increase the time available for evacuation. Figure As shown at 30, Water jet and spray nozzle 65 It is arranged on the wall of the node 13. The jet or nozzle 65 has a structure to which the present invention is attached. Connected to the distribution tower of the structure. In a preferred embodiment, The spray device 63 according to the present invention Activated automatically when is activated. In another embodiment, Dangerous toxic gas levels Alternatively, the device 63 operates when a dangerous temperature level is detected by a sensor. . The device 63 can also be operated manually.   The invention also has some indoor applications. One such indoor application is shown in FIG. It is an elevator shaft Example shown by 1-42. This embodiment is an exit feed Two independent oval descent chute 71 leading to the platform 17. The deflated tube segment Elevator shaft, Preferably, it is mounted on the top of the shaft. This invention When it works, Elevator 73 returns to its lowest point either manually or automatically. The passengers of the elevator 73 are evacuated. Once the elevator 73 is at the bottom or When you reach the parking position, The gas generator is activated, causing the tube 3 to expand. Swelling The inflated segment 13 is shown in FIG. Turning slope 11, as shown at 35-37, Day Flector bulge 7 and inflated padding It has a wide internal structure including a plug 9. In a preferred embodiment, Turning slope 1 1 is a deflector inclined portion 77 and a deflector car extending from the inclined portion 77 Ten 79. The two independent tubes 3 As shown in FIG. Elevé The cable 81 is made to have one tube on each side. FIG. Of the present invention installed on an elevator shaft having a cable 81 FIG. This design is changed to an elevator shaft with a non-core cable 81. Can be The shape of the pipe section 3 and the number of pipe sections depend on the elevator shaft design. Can change. However, in all embodiments, Cable 81 and elevator -Other obstructions on the shaft are outside the inflation tube section 3 to eliminate evacuee contact and injury. Placed on the side. The complete interior of the tube section 3 provides a barrier or hand Designed to not provide Thus accidental or planned in the pipe Limit typical congestion.   The evacuees, as shown in FIG. Entrance to the existing elevator door The tube enters through the mouth opening 85. When the system is activated and tube 3 expands, entrance The opening 85 opens. Each floor has an entrance opening 85 that goes to the pipe section 3. To the tube section 3 The entrance is clearly visible. The cold light emitting edge 87 is Evacuees can look closely around Be placed around the entrance opening 85 to assist evacuees in situations where Can be. In a preferred embodiment, The opening 85 in the elevator door is Only when the floor temperature does not exceed certain fatal levels, Opening opening (limited manual override is possible is there). The evacuees grab a horizontal bar 89 extending across the entrance opening 85, Body Shake and go a few feet ahead of the tube, Release stick 89. FIG. 36 shows the evacuees of the present invention. 4 shows the path of one embodiment of the descent. In the embodiment shown in FIG. All di The reflector inclined portion 77 and the curtain 79 are connected to the pipe 3 closest to the entrance opening 85. On the side. The deflector bulge 7 and the padding cushion 9 are provided on opposite walls of the tube 3 Line up. Another embodiment is a modified version of this configuration. Evacuees are required to enter the deflector -Collide with the inclined portion 77. As discussed earlier, The deflector slope 77 Because it is inclined and flexible, Absorb the evacuee's energy. The evacuees then Colliding with the reflector bulge 7, It absorbs extra energy and Following evacuees To the deflector curtain 79. Deflector curtain 79 is Enel Absorb ghee, The evacuees are pushed downward towards the next deflector bulge 7. This This process continues until the evacuee reaches the bottom of the tube 3. The inflatable exit ramp 17 An evacuee is placed at the exit of the tube section 3 so as to ease the descent of the evacuees and direct them to a safe exit It is.   FIGS. 37 and 38 have a deflector curtain 79 and a deflector ramp 77. The preferred embodiment of the turning slope 11 is shown. Curtain 79 is a deflector -A honeycomb structure cushion connected to the front edge of the inclined portion 77. Direction change The rope 11 is covered with the friction assistor 5. Preferably, Turning slope 11 Is designed to have a separating edge, When the pipe is crowded, it hits the wall and shrinks . In a preferred embodiment of the present invention, The turning slope 11 then descends Under evacuees Has a noise maker that alerts individuals.   43-46, A preferred embodiment of the deflector bulge 7 is shown. Bulge 7 Does not catch Hard to catch, Also creates friction. Bulge 7 is an inflatable safety A and a separation cushion hollow shaft 95 extending from the core 93.   As shown in FIG. 48, each hollow shaft 95 has a friction strand 97, Inflatable cushion 99 And a separation holding expansion point 101. Preferably, Each friction assister 5 Is Made from nine separate cushion hollow shafts 95 as shown in FIG. You. As shown in FIG. One-way valve 61 is for elevator shaft Is located at the expansion holding point 15 of the tube 7 [same as the original]. Valve 61 is for evacuees Allows necessary air release in the event of a collision.   As shown in FIG. The side of the tube 3 has a padding cushion 9.   In a preferred embodiment, The entire inner surface of the tube 3 is covered with a friction assistor 5. Friction assister 5 varies in size to compensate for real-time descent.   The elevator shaft embodiment of the present invention ensures the system in the event of a partial failure. Has safety redundancy to operate. If the elevator 73 stands in the shaft Stuck, If you cannot descend to the parking position at the bottom, Elevator with exit ramp 17 Only the segment 13 of the tube 3 below the heater 73 expands. Once segment 13 expands When, The safety device suddenly operates, A warning is given to passengers in elevator 73, Elebe Data floor 105 opens, passenger Is sent to the lower part of the pipe section 3.   FIGS. 49-50 When evacuation using this system, stop elevator Indicate The protection cushion 107 includes an elevator cable 81, Elevator Extends around car and elevator walls. Opening of elevator floor 105 The section activates the expansion of the segment 13 of the tube section 3 located at the top of the elevator 73 . The safety device of the elevator roof door 109 is released, Roof door 109 automatically Or when the first evacuees collide. The elevator is like this It serves as a segment 13 of the pipe 3 and does not prevent evacuees from descending.   A second safety redundancy in the preferred elevator shaft embodiment is a double tube design. You. By having two individual evacuation routes, The failure of one unit can damage the system Do not inactivate. Variations that address structural differences are possible. Similarly for each pipe segment The structure increases the reliability of the system. At one or more levels One or more segments fail, with or without burning (sudden flame) If It is not possible to prove that a few functional segments in front of the exit ramp are suitable. Not in.   Additional fail-safe redundancy is shown in FIGS. Non-pressurized water nozzle 65 An occlusive ring is located just above the outlet ramp 17. Nozzle 65 is remote Coupled to the sensor. When a sensor detects an evacuee descending at an unsafe speed , The high-pressure water nozzle 65 operates. In conjunction with the exit ramp, the water jet Helps block descent.   Low-level emergency evacuation light source, Audio alert device, And splice Many other features, including the Nklar system, Elevator of this system Can be incorporated into the rotor shaft embodiment.   FIG. 32 and 34 are views of the exit end 17 of the elevator shaft embodiment. Includes preferred embodiments. Preferably, Exit end 17 is designated on the first floor of the building. The rear wall of the elevator shaft (that is, the wall opposite the normal exit of the elevator) The blowdown wall 115. Replaceable solid, Liquid or gas 117 31, Arranged behind the blowdown wall 115 as shown at 35 and 36 You. Preferably, Crushable inert solids, Liquid or gas Arranged behind. When the system works, Exit ramp 17 expands, Broader The wall 115 is broken. The exit ramp 17 passes through the opening 119 resulting from the collapse of the wall. Extend outward, Replaced solid, Depending on the liquid or gas So far Occupy the raised space. This can result in personal injury and damage to the building due to operation. Eliminate and create fire protection material safety zone. The exit ramp is preferably In FIGS. 35 and 36 As shown, it is a waveform ramp.   FIG. 42 shows a preferred embodiment of the outlet ramp 17. Slope 17 blowdown It extends outwardly through the opening 119 left by the wall 115. Inflatable pendulum The barrier 121 is It extends downward from the bottom of the tube portion 3 toward the inclined portion 17. Penju The ram barrier 121 swings outward to allow evacuees to go outside. Spraying equipment 63 is also provided as a safety measure. As shown in FIGS. 40 and 41, End braking Jet 65 is the evacuee's descent speed To reduce It is installed from the end of the turning slope 11. Desirably Jet 65 Dangerous descent speed with remote sensor, For example, 30 feet per second It operates only when the above speed is detected. FIGS. 51 and 61 illustrate all implementations of the present invention. 1 shows a typical gas generator device conforming to the example. Generator device 1 25 is a monopropellant generator 127, Control for controlling generator 127 Device 129, Automatic valve 1 for connecting monopropellant generator 127 to pipe 3 31, And a gas bag having a transient expansion pressure device 133 connected to the valve 131. G generator. Normal, Only one generator device 125 is Needed to operate and maintain the system. Backup is usually installed in case of failure Is done. As shown in FIG. The device 125 may be an elevator shaft or It can be placed on top of other structures.   FIGS. 52-55 show another preferred embodiment of the present invention; Shows the sea transport version. Grain The pipe 3 is connected to the side of the ship 139. Details of the interior of tube section 3 were discussed earlier. It is the same as the one given. The upper end 141 extends near the deck 143 of the ship 139 You. The lower end 145 of the pipe 3 is 6 m from the side of the vessel 139 to avoid underwater 12m outside. The evacuees may be rescued directly into the water or You can go on a life boat. In a preferred embodiment, Lower segment 13 of tube 3 Adapted to the evacuees' evacuation of low ships to the workbench, Evacuate beyond the wake area of the ship It can be selectively inflated to divert refugees. In a preferred embodiment, Ship 1 Gas piston 147 extending from the side of 39 Is used to inflate the tubing. Guide rails can be used.   As shown in FIGS. 56-60, This invention should be installed primarily in emergency situations Can be. In a preferred embodiment, Lifting gas bag 151 such as hot air balloon Carry part 3 to the top of the structure. The present invention further relates to an aircraft capable of ascending and descending movements, helicopter, It can be installed using other transportation means. Guidance fixing cable The cable 153 extends downward from the lifting gas bag 151. One or more tubes Section 3 expands along cable 153 as lifting gas bag 151 rises.   In the preferred embodiment shown in FIG. Wall Walker Unit (ya Outer wall climbing unit) 155 is used as the primary transient stabilizer for tube section 3. You. Preferably, The wall walker unit 155 includes a gas bag 151 and an attached pipe. Used to manage the ratio and direction of three. Unit 155 has a smooth surface For structures or structures fitted with smooth wallwalker unit strips Most suitable for use with The unit 155 has a vertical guide rail 153. A movable suction pad 157 is arranged on each guide rail 153. 1st suction pad Is always attached to the structure wall, On the other hand, the second suction pad is used until the movable pad operates. Extends up and down the length of the guide rail 153. The first suction pad is then released , The cycle repeats itself. This unit is for fixing the lift gas bag 151 Provide a direction lift, Also, the pipe section 3 can crawl on the side of the building. Suction The pad 157 leaves vertically from the building surface Or you can move towards it, Can avoid injury . The unit can be pre-programmed or remotely controlled.   The use of the invention is simple and secure. When the gas generator is activated, Oh Dio and visual management begins. Evacuees are at the descent entrance openings on each floor You will be instructed to get together. When there is no entrance opening on a floor, Evacuation Is guided to the next closest entrance opening. One inlet opening 1 per pipe Only one person is allowed at one time. This reduces the likelihood of panic congestion. Lose it. Each evacuee grabs the entrance rod and shakes his body forward. If there is no stick, Ah Or if the evacuees are afraid, Refugees can sink themselves into the pipe it can. Evacuees immediately encounter a turning slope. This slope is flexible and Absorbs some of the incoming energy. Once on the slope the evacuees leave themselves to descend You. For the slope to bend, A warning signal such as a rattle (night watch alarm) And This keeps the grip on the evacuees just below, At that point Warn you not to enter the shaft with. In a more advanced embodiment of the invention, And Once the evacuees enter the pipes, they take a shower of cooling water spray and are exposed to heat and toxic gas hazards. The steepness is reduced. Evacuees are guided from the turning slope to the deflector bulge It is. Evacuee collisions with deflector bulges absorb additional acceleration energy , Guide evacuees down. The evacuees then hit the lower turning slope. One The turning slope is the deflector ramp and / or the deflector casing In At some point, Evacuees collide with the deflector curtain. Turning slope Or the evacuee's collision with the deflector curtain will again have more acceleration energy Absorb Guide the evacuee down to the next guidance [sic] bulge. Direction change Contact with ropes or deflector curtains further prevents shaft congestion Help. Because the collision temporarily backs off the slope or curtain, This shuts off the entrance opening at that level, Also two people are in the shaft This would prevent them from occupying the same place at the same time. This cycle is Repeat everywhere down to the bottom. In a preferred embodiment, With deflector bulge The turning slope reduces evacuees' descent by 15 to 23 feet per second, is there Or, roughly, it is arranged to slow down to one floor per second. Last diff On reaching the rectifier bulge or turning slope, Evacuees need pipes Deflected horizontally to traverse horizontally to the exit ramp. Evacuees then lean Slide down the slope to the evacuation center. In the preferred embodiment of the present invention, high speed (i.e., Any evacuees entering the final segment of the pipe at a rate of more than 30 feet per second Detected by a sensor that triggers the suppression jet. Jets are too much for evacuees Absorbs acceleration energy.   As an additional safety precaution, Deflector bulge 7 and turning slope 11 Is designed to shut off excess pressure when applied. Slope a Or the weight of the evacuee captured by the bulge may be To separate or separate This property prevents congestion, Take over the descent Will be continued.   The invention is simple and easy to use. Driving use explanation as shown in FIG. 62, for example. As shown in FIG. 63, the panel 161 Convenient, such as walls near elevator doors Posted at the correct location. To facilitate the public disclosure and acceptance of this invention, Shi An example of a stem is an entertainment system with suitable audiovisual equipment and longer descent in a theme park It can be built as a fun attraction.   The features of the different embodiments discussed above are interchangeable.   Although the present invention has been described in connection with specific embodiments thereof, this Modifications and alterations of the invention depart from the scope of the invention as defined by the following claims. It can be built without having to.

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), OA (BF, BJ, CF) , CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (KE, LS, MW, SD, S Z, UG), EA (AM, AZ, BY, KG, KZ, MD , RU, TJ, TM), AL, AM, AT, AU, AZ , BA, BB, BG, BR, BY, CA, CH, CN, CU, CZ, DE, DK, EE, ES, FI, GB, G E, HU, IL, IS, JP, KE, KG, KP, KR , KZ, LC, LK, LR, LS, LT, LU, LV, MD, MG, MK, MN, MW, MX, NO, NZ, P L, PT, RO, RU, SD, SE, SG, SI, SK , TJ, TM, TR, TT, UA, UG, US, UZ, VN [Continuation of summary] Changes depending on the needs of the attached structure You. The invention has fixed internal and external equipment, ground and air It has many configurations including a medium movable rescue unit, It has a similar configuration for marine applications.

Claims (1)

[Claims] 1. An emergency evacuation system, with inner surface, outer surface, top edge and open bottom An inflatable tube section with an end, an inflatable exit feedthrough located at the open bottom end of the tube section, A gas jet connected to the tubing and cradle to inflate the tubing and cradle to optimal pressure A plurality of connectors arranged on the tube to connect the tube to the structure At least one inlet opening leading to the tube, the tube, and inward from the inner surface of the tube Emergency evacuation system that includes multiple inflatable structures extending to the shore. 2. The system of claim 1 wherein the tube section comprises a continuous downcomer section. A cis system characterized by comprising multiple tubular segments connected together to form Tem. 3. The system of claim 1, wherein the connector is a bolt, Select from the group consisting of adhesives, pitons and through-holes filled with solidifying compounds System. 4. The system of claim 1, wherein the optimal pressure is 30 psi. A system characterized by: 5. 2. The system according to claim 1, wherein the structure is a building. The tube is connected to the exterior of the building, where at least one entrance opening is A system characterized by being placed on the roof of an object. 6. 2. The system according to claim 1, wherein the structure is a building. The tubing is connected to the exterior surface of the building, the side of the building has an exit and At the exit on the side of the building A system having multiple inlet openings positioned. 7. 2. The system of claim 1, wherein the tubing together with the outdoor rim. Connected to the exterior of a building with window space, where the pipes are located in the window space Located entrance openings, each entrance opening further around the outdoor edge of the window space Window combing adapter and the side of the adapter And a membrane that extends with the tubing when the tubing expands. And a system characterized by the following. 8. 8. The device according to claim 7, wherein the membrane comprises an outer layer, an inner layer and an intermediate layer. With layers, and with expansion compartments between the three layers of membrane allowing individual expansion of the layers An apparatus characterized by being a three-layer expansion membrane. 9. 8. The apparatus according to claim 7, wherein the membrane comprises multiple layers and the individual layers are separated. Device having an expansion compartment between adjacent layers to enable expansion . 10. 8. The apparatus according to claim 7, wherein each inlet opening of the tube section is a membrane. After the first shield connected to the structure protecting the membrane, The arm has a first arm and a second arm, which are used when the tube stops working. Lie on a straight line and separate from each other when the tube operates and swing outward from each other An apparatus characterized by the above. 11. 11. The device according to claim 10, further comprising: between the edges of the window space. A second shell that stretches so that the membrane is sandwiched between the first and second shields A device comprising a field. 12. 11. The device according to claim 10, wherein the first shield is further provided automatically. Include an override lock located on the first shield to prevent opening An apparatus characterized by the above. 13. 8. The system according to claim 7, wherein the system is used once more. When energized, the interlayer of the membrane to aid in membrane expansion and to provide membrane morphology and stiffness A system comprising a cross beam located at a side of the vehicle. 14． 14. The system according to claim 13, further comprising vertically coupled to the cross beam. A reinforced panel connected to the cross beam for operation. 15. 14. The system according to claim 13, further comprising retaining the membrane and cross beam. A system comprising a wall channel located in a window space for: 16. 14. The system according to claim 13, further comprising a cross beam. Includes a spring loaded ratchet lock mechanism, where each cross beam is Rocket to capture the joint and spring loaded ratchet lock mechanism in the heart A system characterized by having a groove. 17． 14. The system of claim 13, wherein the tubing, membrane, and traverse. A system wherein the beam has an oval cross section when fully expanded. 18. The system of claim 1, wherein the inflatable structure comprises a tube. The evacuees, which extend inward from the inner surface of the vessel and descend, stay along the central area of the pipe Further arranged to reduce the speed of the descending evacuees, wherein the inflatable structure Things are splashing Includes back bulges, turning slopes and padding cushions, and here Baby bulges, turning slopes and padding cushions provide friction assistance A system characterized by having. 19. 20. The system according to claim 18, wherein the configuration comprises: The first side of the tube section with the change slope, facing the first side with the splash bulge The second side of the pipe section, and the side of the pipe section between the rebound bulge and the turning slope A system that has a cushion that extends along the surface. 20. 19. The system of claim 18, wherein the turning slope is The bulge alternates from the front wall of the tube to the rear wall of the tube over the entire length of the tube A system characterized in that it exists in. 21. 19. The system according to claim 18, wherein the evacuees who descend further are overrun. Inflatable structures to absorb excess energy and release air from the structure A system comprising a flapper valve disposed. 22. 19. The system of claim 18, wherein the turning slope is Extends from the deflector slope connected to the pipe and the deflector slope. A system characterized by having a deflector curtain. 23. 2. The system according to claim 1, further comprising a plurality of tubes arranged in the tube. A spraying device. 24. 2. The system of claim 1, further comprising: To deliver a jet of water to the central area of the tube so as to slow the evacuees Including a plurality of high pressure water nozzles located throughout the inner surface of the tube at intervals. Features system. 25. One emergency evacuation system for elevator shafts, with inner and outer surfaces At least one inflatable tube having a surface, a top end and a bottom end, an open bottom of the tube Inflatable exit slide at end, tube and slide to inflate to optimum pressure A gas generator connected to the pipe section and the outlet feedway, at least one leading to the pipe section Multiple inflatable structures extending inwardly from the inner surface of the inlet section and the tube section. Emergency evacuation system for elevator shafts including. 26. 26. The system according to claim 25, wherein the tube is each of the buildings. It has entrance openings located at multiple elevator entrances on the floor, The multiple elevator cables placed on the elevator shaft were removed from the pipe section at A system characterized in that: 27. 26. The system of claim 25, further comprising an elevator shuffle. A second tube section connected to the port. 28. 26. The system according to claim 25, further comprising the step of: A release rod extending from the tube at the inlet opening for ease of use. System. 29. 26. The system of claim 25, further comprising an elevator cable. Includes an elevator connected to the floor, where the elevator Rooftop, inflatable stuffing, And placed on the roof and floor to prevent inadvertent opening of the roof and floor A system comprising a plurality of safety devices. 30. 26. The system according to claim 25, further comprising an upper portion of the outlet ramp. The annulus of the high-pressure water nozzle connected to the bottom of the pipe and the speed of evacuees A sensor connected to the annulus and located in the tube at the top of the annulus. The nozzle emits a high-pressure water flow when the sensor detects high speed. System. 31. 19. The system according to claim 18, wherein a bulge is provided. Is connected to the inner surface of the tube and has an inflatable safety core and a point of friction extending from the core. A system characterized by the following. 32. The system according to claim 1, wherein the friction assistor includes a plurality of friction assistors. It has a heavy separation cushion hollow shaft, and here each cushion hollow shaft In addition to friction strands, inflated cushions connected to the strands, and inflated cushions A system comprising a connected detached holding expansion point. 33. 2. The system of claim 1, wherein the outlet ramp is a waveform table. A system comprising an inflatable exit ramp having a surface. 34. 2. The system of claim 1, further comprising exiting from a bottom end of the tube. A system comprising an inflatable pendulum barrier extending to a mouth ramp. 35. A system according to claim 1, wherein the system is For the generator to control the monopropellant generator, generator Control unit connected to the monopropellant generator, monopropellant generator Automatic valve connected to the valve and tubing, and transient expansion connected to the automatic valve A system comprising a pressure device. 36. 20. The system of claim 18, wherein the inflatable structure is A system characterized by being movably attached to the inner surface of the tube. 37. An emergency evacuation system, with an inner surface, outer surface, top edge and opening Inflatable tube section with bottom end, inflatable exit feedthrough located at the open bottom end of the tube section Gas connected to the tubing and outlet feed to inflate the tubing and feed to the optimum pressure. Generators, and a plurality of tubes arranged in the tube to connect the tube to the structure Connector, at least one inlet opening leading to the tube, and from the inner surface of the tube Includes multiple inflatable structures extending inward, and further having a tube on the side of the structure. Includes a wall walker unit for raising The kit further includes a vertical guide rail and multiple suction pads connected to the rail, and This can be moved up, down, and away from the side of the structure Emergency evacuation system including inflatable tubing with them. 38. An emergency evacuation system for use with elevator shafts, Gas generator located at the top of the elevator shaft, top and bottom ends Section, a first tube section having an inner surface and an outer surface, a second top end, a second bottom end, a second inner table Face and A second tube having a second outer surface, wherein the first tube and the second tube are each adjacent The elevator cable of the elevator shaft is placed on the outside of the pipe Surface, where the tube is connected to the elevator shaft wall and the Extends along the entire length of the beta shaft, with an inflatable exit ramp below the bottom end of the tube The outlet ramp expands and pressure is applied to the blowout wall to cause the outlet ramp to Blowout wall on elevator shaft at level occupying position to fall down A deployed and inflatable structure guides evacuees down the tubing and speeds of evacuees Elevators including these extending inward from the inner surface of the tube to reduce -Emergency evacuation system for use inside the shaft. 39. One method of evacuating structures, where pipes are installed and gas Activates the nerator, activates the pipe and the inside connected to the pipe, and the structure and exit ramp Inflated with the gas sent from the gas generator, through the inlet opening in the pipe Internal structure that enters the pipe part, descends the pipe part, and extends inward from the inner surface of the pipe part Systematically collided with an object, evacuated the pipe section, slid off the exit slope, and retreated to the evacuation center A method for evacuating a structure that includes the step of: 40. 40. The method according to claim 39, wherein the installation of the tube is an elevator. Including placing the tube at the top of the turbine shaft, and further inflating the tube Characterized by including guiding the elevator to the bottom of the elevator shaft before how to. 41. 41. The method according to claim 40, further comprising the step of positioning an outlet ramp. Including knocking down blowout walls located on the elevator shaft with a bell A method characterized by the following. 42. 40. The method according to claim 39, wherein the entry into the tube section includes opening the inlet. A method comprising gripping an approach bar extending across a mouth. 43. 40. The method of claim 39, further comprising in the tube and near the outlet ramp. Actuating a plurality of spraying devices located at the same.