EP2132389A1 - Survival device in the context of natural disasters consisting of a dwelling module and its accessories - Google Patents

Abstract

The invention concerns a set of devices of a dwelling module for meeting emergency and extreme emergency requirements for coping with submarine quakes, standard earthquakes, floods and a plurality of natural disasters. Said set consists of several subassemblies, namely a dwelling module and other elements such as a foot, a heel, a leg, an emergency anti-seismic air lock, an extensible telescopic air lock, a protective shield, a horizontal wind turbine and the like.

Description

 SURVIVAL DEVICE IN THE CONTEXT OF NATURAL DISASTERS COMPRISING A COCKPIT MODULE AND ITS RELATED ELEMENTS

WARNING

I am submitting to you the description of a complex survival device in natural disaster situations to be investigated as part of a patent application.

In this patent application, the claims relate to both the file content and methods, techniques, very specific elements at the technical and intellectual level. For a better understanding, the precise descriptions are integrated at the level of each chapter.

In the case of designs, these are also the subject of a patent application.

This device is for valid people; however, special consideration has been given to its adaptation and use by persons with reduced mobility, taking into account a "comfort of life" dimension.

In addition, the whole of an element called "module" and the grouping together with its ancillary elements must be considered as an independent or fully patentable element. WARNING 1

PREAMBLE 11

ACHILL MODEL (BOARD 4 - FIGURE 6) 11 ICARE MODEL (BOARD 4 - FIGURE 7) 12

ATLANTIS MODEL (BOARD 4 - FIGURE 8) 12

BASIC MODEL (BOARDS I, 2, 3 - FIGURES.1, 2, 3, 4, 5) 12

CHAPTER I - STRUCTURES 13

§ 1 - BASIC STRUCTURES (BOARD 6 - FIGURE 10) 13 1.1. RECEPTACLE (BOARD 6 - FIGURE 10) 13

1.2. HAT (BOARD 6 - FIGURE 10) 13

1.3. OCCULTANT SYSTEM (BOARD 6 - FIGURE 10) 14

1.4. CAR ACCESS SYSTEM (BOARD 37 - FIGURES 90, 91, 92) 14

1.5. ACCESS TO THE HABITACLE (BOARD 7 - FIGURE 11) 14 1.6. FOOT (BOARD 8 - FIGURE 12, BOARD 9 - FIGURES 13, 14, 15) 14

1.7. TALON (BOARD 10 - FIGURE 16 (2)) 14

1.8. LEG (BOARD IO - FIGURE 16 (3)) 15

1.9. SAS DEAMBULATOIRE OR SAS SURVIE (BOARD I i - FIGURE 18, BOARD 12 - FIGURES 19 AND 20) 15 1.10. EXTENSIBLE TELESCOPIC SAS (BOARD 13 - FIGURES 21, 22 AND 23) 16

1.11. MOUTH "ELEMENT B" (BOARD 14 - FIGURE 25 (I)) 16

1.12. PROTECTIVE SHIELD (BOARD 14 - FIGURE 25 (2)) 16

1.13. EXTERNAL STRUCTURE (EXTERNAL CAGE) (BOARD 7 - FIGURE 11) 16

1.14. INTERNAL STRUCTURE (INTERNAL CAGE) (BOARD V - FIGURE II) 16 1.15. FLOTATION (BOARD 15 - FIGURE 26) 17

1.16. HORIZONTAL TURBINE WIND TURBINE (PLATE 16 - FIGURES 27, 28, 29) 17

1.17. WHEEL AT DAWN (BOARD 17 - FIGURES 30 AND 31) 17

1.18. EMERGENCY LADDER 18

1.19. DOORS (BOARD 18- FIGURES 34, 35, 36 AND 37) 1.20. SUPPLEMENTARY DOOR (BOARD V - FIGURE II) 18

1.21. SPHERICAL STOPPING (BOARD 7 - FIGURE 11) 18

1.22. TANK (BOARD 14 - FIGURE 25) 19

§ 2 - POSSIBILITIES OF EXTENSION AND COMPLEMENTS OF STRUCTURE 19

2.1. SETTING UP ⁵ AN ELEVATION (FLOOR) 19 2.2. CLASSIC GATEWAY (BOARD 50 - FIGURES 224 AND 227) 19

2.3. GATEWAY / GALLERY / DEAMBULATORY / SAS DE SURVIE (BOARD 11 - FIGURE 18, BOARD 50 - FIGURES 224 AND 227) 19

CHAPTER 2 - INTERIOR DEVELOPMENT 21

1. FURNITURE: TABLES AND CHAIRS (BOARD 19 - FIGURE 38) 21 2. STORAGE 21

3. SLEEPING (BOARD 19 - FIGURE 38) 21 4. MATTRESS SUPPORT 22

5. SLEEP COVER 22

6. ROOM OF WATER 22

7. SAUNA 23 8. KITCHEN 23

9. MINI BAR 24

10. RELAXATION, CULTURE 24

11. DOME ₅ GLASS (DECORATION) (IF BOARD - FIGURE LO) 24

CHAPTER 3 - PROTECTION OF THE MODULE IN EXTERNAL SURFACE AND CONSTANT POSITION 25

1. "ELEMENT E" PROTECTION COVER (BOARD 20 - FIGURE 39) 25

2. COCON PANELS (PUMPS AND DISTRIBUTION COMPRESSORS) (BOARD 21 -FIGURE 40) 25

3. GARAGE TRACKING (BOARD 21 - FIGURE 40) 25 4. PROGRAMMING AND OPERATING MODES OF GARAGE STORAGE

PANELS CONSTITUTING THE COCON (BOARD 22 - FIGURES 41 AND 42) 25

5. SELECTION OF THE GARAGE TRACK MODE (BOARD 22 - FIGURES 41 AND 42) 26

6. SOLIDARIZATION AND DESOLIDARIZATION OF PANELS (BOARD 24 - FIGURES 48 AND 49) ..27

7. RAIL SUPPORT (BOARD 21 - FIGURE 40, BOARD 22 - FIGURE 42) 27 8. NATURAL LIGHTING (BOARD 20 - FIGURE 39) 28

9. DETECTIONS 28

10. ELECTRICAL BOX 28

11. MARKING 28

13. LOCATION ON NATURAL OR PRIVATE SITES 29 14. REVOLUTION MOVEMENTS 29

15. ANTI-BACTERIAL SCREEN 29

CHAPTER 4 - SPECIAL EQUIPMENT 30

1. CABLE AND GRAPPLE 30

2. ANCHORING RING (BOARD 28 - FIGURE 65) 30 3. EXCHANGER (BOARD 25 - FIGURES 54, 55 AND 56) 31

4. PARTICULAR HIGH PRESSURE DRIVE (BOARD 25 - FIGURES 52, 53 AND 58, BOARD 26 - FIGURES 59 AND 60, BOARD 27 - FIGURES 61, 62 AND 63) 31

5. HAND OF SUPPORT (BOARD 28 - FIGURE 64) 31

6. BALLASTS (BOARD 15 - FIGURE 26) 32 7. BALLOONS (BOARD 15 - FIGURE 26) 32

8. GOUVERNAIL (BOARD 15 - FIGURE 26) 32

9. BREAK OF BLADES (PROUE) (BOARD 15 - FIGURE 26) 33

10. PROPULSION ENGINE (BOARD 15 - FIGURE 26) 33

11. STABILIZER (BOARD 15 - FIGURE 26) 33 12. TERRACE OR GATEWAY (CONTEXT CONTEXT) (BOARD 15 - FIGURE 26) 33

13. SPECIFIC LIGHTING (BOARD 29 - FIGURES 66 AND 67) 34

14. PNEUMATIC PROTECTION POCKETS (BOARD IS - FIGURE 10) 34

15. NACELLE 35

CHAPTER 5 - TECHNICAL SUPPORT 36 § 1 - ELECTRICAL TECHNICAL SUPPORTS 36

1.1. GENERAL LOW VOLTAGE TABLE (TGVT) 36

1.2. MAIN CABINET LOW VOLTAGE 36

1.3. CABINET ELECTROGEN GROUP 37 1.4. ELECTROGEN GROUP 37

1.5. AVIATION 37

1.6. EXHAUST GENERATOR GROUP 37

1.7. INVERTER 38

1.8. INVERTER 38 1.9. IT INVERTER 38

1.10. GENERATORS 38

1.11. ALTERNATORS 39

1.12. CLASSIC AND COMMON POWER SUPPLY 39

§ 2 - TECHNICAL SUPPORT IN PLUMBING 39 2.1. EXTRACTION, VENTILATION, CONDUIT 39

CHAPTER 6 - DISTRIBUTION OF WATER 40

1. WATER DECANTED TO USE IN WATER-VALVE MODE 40

2. WATER DECANTED TO USED WATER MODE 40

3. CONSUMER WATER (DRINKING WATER) 40 4. STORM WATER RECOVERY (BOARD 27 - FIGURE 61) 40

5. SPECIFIC AND PARTICULAR PUMP (PUMPING) 41

6. WATER DETECTOR 41

CHAPTER 7 - ENERGY PRODUCTION 42

§ 1 - ENERGY SENSORS 42 1.1. SOLAR PANELS (COCKPIT MODULE) (BOARD 30- FIGURE 68) 42

1.2. SOLAR PANELS (COCON OF PROTECTION) (BOARD 21 - FIGURE 40) 42

1.3. SOLAR PANELS (MOUTH) (BOARD 14- FIGURE 25) 43

1.4. PHYSICAL PROTECTION OF SOLAR PANELS (BOARD 30 - FIGURE 68) 43

1.5. LUNAR PANELS (BOARD SO - FIGURE BONE) 43 § 2 - HEATING - AIR CONDITIONING - CLIMAREFRIGERATION 43

2.1. HEATING (BOARD 31 - FIGURES 69 TO 72, BOARD 32 - FIGURE 73) 43

2.2. AIR CONDITIONING (BOARD 31 - FIGURES 69 TO 72, BOARD 32 - FIGURE 73) 44

2.3. CLIMAREFRIGERATION (BOARD31 - FIGURES 69 TO 72, BOARD 32 - FIGURE 73) 44

2.4. FUEL CELL 45 2.5. STORER 45

2.6. LOW VOLTAGE / HIGH VOLTAGE RECEPTION (BOARD H - FIGURE 18) 45

2.7. HUMIDIFIER 46

2.8. STRUCTURE (BOARD 25 - FIGURES 52 AND 53) 46

§ 3 - CHIMNEY (BOARD 19 - FIGURE 38, BOARD 33 - FIGURES 74 TO 78) 46 3.1. HEATING BODY (BOARD 33 - FIGURE 74 (I)) 46

3.2. SMOKE EXHAUST DUCT (BOARD 33 - FIGURES 74 AND 75 (2)) 47

3.3. PENETRATION AT THE LEVEL OF THE GLASS (HAT, DOME) OF THE COCKPIT MODULE BY THE CHIMNEY DUCT (BOARD 33 - FIGURE 74 (3)) 48

3.4. EXTRACTORS (BOARD 33 - FIGURE 74 (4), BOARD 34 - FIGURES 79, 80, 81 AND 82) 48 3.5. SOUND AND VISUAL ALARM SYSTEM 48 CHAPTER 8 - SURVIVAL 49

§ 1 - TECHNICAL ASSISTANCE 49

1.1. PRESSURE (PRESSURE CONTROL) 49

1.2. SPECIFIC COMBINATIONS 49 1.3. OXYGENISATION OR OXYGENATION 49

1.4. BOTTLES OF OXYGEN 50

1.5. PERISCOPES 50

1.6. DETECTION 50

1.7. ANTI-VIRUS AND ANTI-BACTERIAL SCREEN 51 1.8. DECONTAMINATOR 51

1.9. LOCATION DETECTION 51

1.10. GUIDANCE 52

1.11 PROPULSION SONAR 52

1.12. RADAR DETECTION / NAVIGATION RADAR 52 1.13. WEATHER RADARS (BOARD 16 - FIGURE 29 (6)) 52

1.14. DETECTION MICROS 52

1.15. THERMAL CURRENT DETECTOR 53

1.16. UNIVERSAL CONVERTER 53

1.17. RESCUE BOATS 53 1.18. LIFTING VESTS 53

1.19. PARACHUTE (BOARD 15 - FIGURE 26) 53

1.20. NECESSARY OF SPELEOLOGY AND PLANNING 54

§ 2 - SURVIVAL OF THE SPECIES 54

2.1. GENETIC PROTECTION 54 2.2. GENETIC DEPARTMENT 54

2.2.1. Human Genetics Department 54

2.2.2. Animal Genetics Department 54

2.2.3. Genetic department with a vegetal character 55

2.2.4. Department of Mineral Matters 55 2.3. VIRAL AND ANTI-VIRAL BANKS 55

2.4. PARA-PHARMACEUTICAL BANK 55

2.5. MINI-LABORATORY 55

2.6. MINI CABINET DENTAL 56

2.7. MINI-OPERATIVE BLOCK 56 2.8. MINI PHARMACY 56

2.9. BLOOD HYDROLYSIS CHECKER 56

2.10. POLLEN DETECTOR 56

2.11. FOOD STORAGE 57

CHAPTER 9 - SECURITY - SECURITY 58

§ 1 - SECURITY OF PREVENTION 58

1.1. SURVEILLANCE: RADARS (BOARD 16 - FIGURE 29 (7)) 58

1.2. NAVIGATION LIGHTS 58

1.3. SOUNDBREAKERS 58

1.4. SOUND ALARMS AND ALERTS 58 1.5. REMOTE CONTROLS AND REMOTE CONTROL 59

1.6. SURVEILLANCE CAMERAS 59

1.7. EXCEPTIONAL MARKINGS 59 1.8. BEACH HEADLIGHTS 60

§ 2 - ELECTRICAL SAFETY 60

2.1. PARATONNERRE 60

2.2. EARTHQUAKES 60 2.3. LOW VOLTAGE EARTH SOCKET 60

2.4. COMPUTER GROUNDING 60

2.5. IONIZATION DETECTORS 61

2.6. PROTECTION OF THE IONIZATION PHENOMENON AND THE FARADAY HYPOTHESIS 61

2.7. WAVE DETECTORS 61 2.8. WIRE BROWSER 61

2.9. UNDERWATER WARNING 61

2.10. AUTOMATIC DISCONNECT (BOARD 35 - FIGURE 85) 62

§ 3 - MECHANICAL SAFETY 62

3.1. CREMAILLERE 62 3.2. PUMP 62

3.3. WINCH 62

3.4. UP / DOWN SYSTEM OF THE ACCOMMODATION MODULE 63

3.5. END OF RACE SAFETY 63

3.6. RESCUE CRANKSHOP 63 3.7. SPECIAL SCALE 64

§ 4 - SECURITY 64

4.1. PHYSICAL PROTECTION ANTI-EFFRACTION 64

4.2. ANTI-VANDAL SYSTEM 64

4.3. IDENTIFICATION SYSTEM 64 4.4. THERMAL CAMERAS 65

CHAPTER 10 - ANTI-SEISMIC SYSTEM 66

1. FLOOR (BOARD 40 - FIGURE 113) 66

2. ANTI-SEISMIC STRUCTURES (SEISMIC SPECIFIC CYLINDERS AND BALLS) (BOARD 40 - FIGURES 114, 115, 116, 117, 118 AND 119) 66 3. NOSE (BOARD 10 - FIGURE 17) 66

4. INTERFACE (SUPPORT HAND) (BOARD 28 - FIGURE 64) 67

CHAPTER 11 - CONTEXT OF VOLUMES AND SURFACE IN AN ANTI-DEFLAGING ENVIRONMENT 68

1. WIRING 68 2. APPARATUS 68

3. JOINTS (IN THE GENERAL CASE) AND SPECIAL JOINTS 68

4. KITCHEN EQUIPMENT 68

5. LIGHTING 68

6. NORMAL LIGHTING AND SECURITY LIGHTING 68 7. FIBER OPTIC LIGHTING 69

CHAPTER 12 - SURFACE TREATMENTS 70

1. FIRE RETENTION 70

2. MATERIAL PROTECTION TREATMENT 70 3. FIRE EXTINGUISHERS 70

CHAPTER 13 - MAINTENANCE 71

1. MINI-WORKSHOP 71

2. ASPIRATOR 71

CHAPTER 14 - CONTROLS - CONTROLS - MEASURES 72

1. GENERAL SYNOPTIC CONTROL AND CONTROL PANEL 72

2. LEVEL CONTROL (CONTROL OF PLATE ⁵⁾ 72

3. MEASURING EQUIPMENT 72

4. NAVIGATION INSTRUMENTS 72 5. TELESCOPE 73

CHAPTER 15 - MOTORIZATION - PROPULSION 74

1. PROPULSION ENGINES (PROPULSION) (BOARD 35 - FIGURES 83 AND 84) 74

2. AUTOMATIC DISCONNECT (SS BOARD - FIGURE SS) 74

3. TRANSMISSION AND COUPLING SYSTEM RELATING TO THE DRIVING OF PROPULSION MOTOR TREES AND THE ACTIVATION OF WHEELS IN DOLLS (BOARD 17 - FIGURES 30 AND

31; BOARD 35 - FIGURES 83 AND 84) 74

4. WHEELS AT DAWN (BOARD 17 - FIGURES 30 AND 31) 74

5. "GAUDILLE" WHEEL (BOARD 17 - FIGURES 32 AND 33) 74

CHAPTER 16 - TRANSPORT 75

1. SPECIFIC TRAILER (BOARD 36 - FIGURES 86 AND 87) 75

2. TRUCK (BOARD 36 - FIGURES 86, 87 AND 88) 75

CHAPTER 17- COMMUNICATION 76

1. ISSUING PHYSICAL MESSAGES IN CRITICAL AND EXTREME CIRCUMSTANCES 76

2. LASER MESSAGE 76 3. SOUND SYSTEM 76

4. TELEVISION 76

5. HIGH-FIDELITY 76

CHAPTER 18 - POPULATION ALERT PLAN 77

1. AUTOMATIC ALERT TRIP SYSTEM 77

CHAPTER 19 - SPECIAL DEVICES FOR PEOPLE WITH REDUCED MOBILITY (PRM) 78

1. INNER OR EXTERIOR PMR MOUNTING (BOARD 37 - FIGURE 89) 78 2. UNIVERSAL INTERIOR OR EXTERIOR PRIDE (PLATE 37 - FIGURES 90, 91 AND 92) ... 78

3. SPECIFIC ACCESS TO HEALTH, SHOWER ₅ SAUNA (BOARD 38 - FIGURES 93 AND 94) 79

4. SINK (BOARD 38 - FIGURES 99 AND 100) 79

5. DOUBLE TOILET (BOARD 38 - FIGURE 101) 79 6. PMR SLEEPING (BOARD 39 - FIGURES 102, 103 AND 104) 79

7. MASSAGE OPTION (BOARD 39 - FIGURES 102 TO 108)

8. TABLE AND PRESS OFFICE (BOARD 19 - FIGURE 38) 80

9. LEVES CENTRAL PERSON (BOARD 38 - FIGURE 95) 80

10. ERGONOMICS PMR 80 11. ERGONOMICS AT WC LEVEL 81

12. SHOWER AND SAUNA (BOARD 38 - FIGURES 94, 96 TO 98)

13. DEPLOYMENT OF PMR BY DETECTION AND ALARMS 81

14. GUIDANCE 82

15. SPORT AND MAINTENANCE FOR PRM (BOARD 39 - FIGURES 109, 110, 111 AND 112) 82

CHAPTER 20 - SCENARII 83

SCENARIO A: SINGLE AND TOTALLY INDEPENDENT COCKPIT MODULE (BOARD 41) .. 83

A.1. SCENARIO IN THE CONTEXT OF EARTHQUAKE (BOARD 41 - Al. FIGURES 120 AND 121) 83

A.2. SCENARIO IN THE EVENT OF SUBMERSION (BOARD 41 - A2 FIGURES 122 TO 125) 83

A3. SCENARIO IN CASE OF DERIVATIVE (BOARD 41 - A3, FIGURES 126 TO 130) 83 A.4. SCENARIO IN CASE OF FALL (BOARD 41 - A4, FIGURES 131 AND 132) 83

AT 5. SCENARIO IN CASE OF WASTE MOUNTING (BOARD 41 - A5 FIGURES 133 AND 134) 83

A.6. SCENARIO IN NORMAL TIME (BOARD 41 - A6 FIGURES 135 TO 138) 84

A7. SCENARIO IN CASE OF AVALANCHE AND SNOWFALL (BOARD 44 - FIGURE 179) 84

SCENARIO B: COCKPIT MODULE AND ITS ADDITIONAL COMPONENTS COMPRISING THE ENTIRE MAIN ELEMENT (BOARD 41 - B1, B2 AND B3 FIGURES 139 TO 141) 84

SCENARIO C: IMPLANTATION OF THE COCKPIT MODULE IN A TREE (HITCHING

BETWEEN BRANCHES) (BOARD 42) 84

C.1. LOCATION OF THE COCKPIT MODULE IN TREES FOLLOWING POSSIBILITIES

PHYSICS CORRESPONDING TO THE STRUCTURE OF THE TREE OR AT THE CATHIOPE LEVEL, IF NECESSARY (BOARD 42 - Cl. FIGURES 142, 143, 144 AND 146) 84

C.2. IMPLANTATION OF THE MODULE SUPPORTED BY ITS PLATFORM HELD IN A GROUP

THREE MINIMUM TREES (THREE ANCHOR POINTS) (BOARD 42 - C2, FIGURES 142 AND 143) 85

C.3. CUSTOMS MODULE SUPPORTED BY THE GATEWAY / POTENCY (BOARD 42 - C3 FIGURE 144) 85

C4. FOREST MODULE (BOARD 42) 86

SCENARIO D: IMPLANTATION OF THE TROGLODYTE COCKPIT MODULE (BOARD 42

- Dl FIGURE 145) 86

SCENARIO E: IMPLANTATION OF AQUATIC (MULTIPLE AGH CYLINDERS) MULTIPURPOSE COCKPIT MODULE (BOARD 42) 86

1. SUPPORT PLATFORM (BOARD 48 - FIGURE 212) 86

SCENARIO F: IMPLANTATION OF THE MODULE IN WALKING AREA (BOARD 42 - Fl.

FIGURE 147) 87

RELATIONSHIP BETWEEN ELEMENTS BASED ON WATER, IN THE FOREST OR ON THE GROUND 87 1. PORTAGE OF THE COCKPIT MODULE (BOARD 42 - FIGURES 142 TO 154) 87

2. GUIDING ELEMENTS (BOARD 48 - FIGURE 214 (6)) 87

3. SUPPORT OF SUPPORT (BOARD 48 - FIGURE 214) 87

4. TRACTION CABLES (BOARD 48 - FIGURE 212) 87 5. TENDERING GUIDES (BOARD 48 - FIGURE 212) 87

6. MANEUVER WINCH (BOARD 48 - FIGURE 212) 88

7. FLOTATION 88

8. SECURITY BUILDERS 88 9. SECURITY OF DESOLIDARIZATION OF THE PLATFORM HABITACLE MODULE LE

SUPPORTING 88

10. HEADLIGHTS 88

11. AQUATIC UNIT WITH SINGLE GUIDE CYLINDER 88

12. AQUATIC WATER BALANCED MODULE 88

CHAPTER 21 - PRESENTATION OF MODULES OF MODULES AND

ADDITIONAL ELEMENTS CONSTITUTING THE ENTIRE DEVICE 89

§ 1 - DESCRIPTION OF THE MODULES OF MODULES AND ITS APPENDICES 89

1.1. BASIC MODELS 89

1.2. VARIANTS (PRESENTATION OF THE MODULES) 90 §2 - CHOICE OF THE FORM OF THE COCKPIT MODULE OR HABITAT OR MODULE

NANOHABITACLE OR NANOHABITAT (BOARD 50) 90

2.1. DEFINITION AND CHOICE OF THE COCKPIT MODULE 90

2.2. OBSERVATIONS AND REFLECTIONS 90

§ 3 - CHOICE OF IMPLANTATION OF COCKPIT MODULES AND THEIR ELEMENTS: COLLECTIVE OR INDIVIDUAL IMPLANTATION (BOARD SO - FIGURES 217 TO 231;

43 TO 45 - FIGURES 155 TO 199) 91

3.1. NATURE OF THE SITES 91

3.2. ADVANTAGE AND CHOICE OF THE COCKPIT MODULE (AND THEIR ADDITIONAL ELEMENTS) 92

3.3. SURFACE SOIL DOCCUPATION (LOW COEFFICIENT) 92 3.4. INSTALLING THE COCKPIT MODULE 92

3.5. UNIVERSAL IMPLANTATION 92

§ 4 - THEMES OF THE COTTAGE MODULE (DECORATIVE AND PRACTICAL ASPECT) 93

4.1. STYLE MODEL 93

4.2. MARINE MODEL 93 4.3. MODEL CHAMPETRE 93

4.4. MODEL MONTAGNARD 93

4.5. CLASSICAL MODEL 94

4.6. MODERN MODEL 94

4.7. MODEL FUTURISTIC 94 4.8. DECORATION OF EXTERNAL VOLUMES 94

NOTE: 94

CHAPTER 22 - ALL-WOOD COMPARTMENT MODULE 95

1. BEACLES (BOARD 54 - FIGURE 236 (I) ₅ FIGURE 237) 95

2. ANTI-SEISMIC SYSTEM (BOARD 55 - FIGURES 240 TO 242) 95 3. OSSATURE (BOARD 54 - FIGURE 236) 96

4. WOOD PANELS (BOARD 54 - FIGURES 236 AND 238, BOARD 56 - FIGURE 247) 96

5. PIPELINES (BOARD 57- FIGURES 248 TO 251) 96

6. THE ENTRE-TOISES (BOARD 54 - FIGURE 237) 96

7. THE ALVEOLES (BOARD 54 - FIGURES 236 AND 238, BOARD 56 - FIGURE 247) 97 8. HEATING (BOARDS 56 AND 57) 97 9. AIR CONDITIONING (BOARDS 56 AND 57) 98

10. CLIMAREFRIGERATION (HYPER-FROID) (SO AND S?

11. INDEPENDENT BLOCKS OF HEATING, AIR CONDITIONING AND CLIMAREFRIGERATION (PLANCHE

56 - FIGURE 244) 99 12. DOOR AND DOUBLE DOOR (BOARD 52 - FIGURE 233 (1), FIGURE 234) 99

13. THE DOOR (BOARD 52 - FIGURES 233 AND 234) 99

14. THE DOUBLE DOOR 100

SPECIFIC NOTES 100

FEATURES 101

1. CONFIGURATION 101

2. RANGE OF MANUFACTURE 101

3. ASSEMBLY AND DISASSEMBLY RANGES 101

4. ASSEMBLY CHAIN 101

CLAIMS 102

1. FOOT (BOARD 8 - FIGURE 12, BOARD 9 - FIGURES 13, 14 AND 15) 102

2.TALON (BOARD 10 - FIGURE 16 (2)) 102

3. LEG (BOARD 10 - FIGURE 16 (3)) 103 4. SAS DEAMBULATOIRE / SAS OF ANTI-SEISMIC EMERGENCY (BOARD 11 - FIGURE 18, BOARD 12 -

FIGURES 19 AND 20)

5. SAS TELESCOPIC EXTENSIBLE (BOARD 13 - FIGURES 21, 22 AND 23) 104

6. "ELEMENT B" MOUTH (BOARD 14 - FIGURE 25) 105

7. PROTECTIVE SHIELD (BOARD 14 - FIGURE 25) 105 8. HORIZONTAL TURBINE WIND TURBINE (BOARD 16- FIGURES 27 TO 29) 106

9. WHEEL AT DAWN (BOARD 17 - FIGURES 30 AND 31)

10. DOORS (BOARD 18 - FIGURES 34 TO 37)

11. ANTI-SEISMIC PANELS COCON (BOARD 21 - FIGURE 40) 107

12. ANTI-SEISMIC POTENCY FOOT (BOARD 23 - FIGURES 43 AND 44) 108 13. ANTI-SEISMIC POTENCY ARM (BOARD 23 - FIGURE 47) 108

14. HEAD OF ANTI-SEISMIC POTENCY ARM (BOARD 23 - FIGURE 47) 108

15. ANTI-SEISMIC POTENCY BOX (BOARD 23 - FIGURE 46)

16. RAIL SUPPORT OF ANTI-SEISMIC PANELS (BOARD 22 - FIGURE 41) 109

17. EXCHANGER (BOARD 25 - FIGURE 53 TO 56) 110 18. SPECIAL HIGH PRESSURE CONDUIT 110

19. POWER SUPPLY AND GENERAL DISTRIBUTION CIRCUIT (BOARD 26 - FIGURES 59 AND

60; BOARD 27 - FIGURES 61, 62 AND 63) 111

20. SPECIFIC LIGHTING (BOARD 29 - FIGURES 66 AND 67) 112

21. HEATING - AIR CONDITIONING - CLIMAREFRIGERATION (Cf. § 2 OF CHAPTER 7) (BOARD 31 - FIGURES 69 TO 72) 112

22. STRUCTURE (BOARD 25 - FIGURES 52 AND 53) 113

23. CHIMNEY (SECTION 3 OF CHAPTER 7) (BOARD 19 - FIGURE 38, BOARD 33 - FIGURES 74 TO 78)

24. ANTI-SEISMIC FLOORS (BOARD 40 - FIGURE 113) 115 25. ANTI-SEISMIC STRUCTURES (BOARD 40- FIGURES 114 TO 119) 115

27. NOS (point 3 of Chapter 10) (Plate 10 - Figure 17) 117

28. BLOOD HYDROLYSIS AUDITOR 117

29. SPECIFIC COMBINATIONS 118

30. HEADLIGHT MARKING DETECTOR 118 31. ⁵ 118 IONIZATION

32. AUTOMATIC DISCONNECT (SS BOARD - FIGURE SS) 119

33. MOTORIZATION -PROPULSION (BOARD 35 - FIGURES 83 AND 84) 119

1. PROPULSION ENGINES (PROPULSION) (BOARD 35- FIGURES 83 AND 84j 119

2. AUTOMATIC DISCONNECT (BOARD 35 - FIGURE 85) 119 3. TRANSMISSION AND COUPLING SYSTEM FOR TREE DRIVE

PROPULSION ENGINES AND THE ACTIVATION OF ROUESA DAWN (BOARD 35 - FIGURES 83 AND 84) 120

4. ROUESA DAWN (BOARD 17 - FIGURES 30 AND 31> 120

5. RUE "GAUDILLE" (BOARD 17 - FIGURES 32 AND 33) 120 34. SPECIFIC TRAILER (BOARD 36 - FIGURES 86 AND 87) 121

35. TRUCK (BOARD 36 - FIGURE 88) 121

36. INDOOR OR EXTERIOR PRIDE MOUNTING (BOARD 37 - FIGURE 89) 121

37. UNIVERSAL INTERIOR OR OUTSIDE RIDER (BOARD 37 - FIGURES 90 TO 92) 38. SPECIFIC ACCESS TO HEALTH ₅ SHOWER ₅ SAUNA (BOARD 38 - FIGURES 93 AND 94) 123

39. SINK FOR PRM (BOARD 38 - FIGURES 99 AND 100) 123

40. DOUBLE WC (BOARD 38 - FIGURE 101) 124

41. PRMS LODGING (BOARD 39 - FIGURES 102 TO 104) 124 42. MASSAGE OPTION (BOARD 39 - FIGURES 102 TO 108)

43. TABLE AND SEATS FOR PRM (PIOCHE 19 - FIGURE 38) 126

44. CENTRAL STAFF (PLANCI-IE 38 - FIGURE 95) 128

45. SHOWER AND SAUNA (BOARD 38 - FIGURES 93 AND 94) 128

46. ALDE FOR THE MOVEMENT OF PMR BY DETECTION AND ALARM 129 47. GUIDANCE 130

48. SPORT AND MAINTENANCE FOR PRM (BOARD 39 - FIGURES 109 TO 112) 130

49. SCENARIO IN THE CONTEXT OF THE EARTHQUAKE (BOARD 41 - Al. FIGURES 120 AND 121) 132

50. SCENARIO A.2. IN THE EVENT OF SUBMERSION (BOARD 41 - A2 FIGURES 122 TO 125)

51. SCENARIO A3 IN THE EVENT OF A DERIVATIVE (BOARD 41 - A3, FIGURES 126 TO 130) 133 52. SCENARIO A.4. IN CASE OF FALL (BOARD 41 - A4, FIGURES 131 AND 132) 134

53. SCENARIO A.5. IN CASE OF WASTE MOUNTING (BOARD 41 - A5 FIGURES 133 AND 134) 135

54. SCENARIO A.6. IN NORMAL TIME (BOARD 41 - A6 FIGURES 135 TO 138) 135

55. SCENARIO A7. IN CASE OF AVALANCHE AND FALL OF SNOW (BOARD 44 - A7 FIGURE 179) 135 56. SCENARIO B: COCKPIT MODULE AND ITS COMPONENTS COMPONENT TOGETHER

PRINCIPAL ELEMENT (BOARD 41 - B1, B2 AND B3 FIGURES 139 TO 141)

57. SCENARIO C1: IMPLANTATION OF THE COCKPIT MODULE IN TREES (BOARD 42 -

FIGURES 142 TO 144 AND 146; BOARD 46 - FIGURES 200 TO 203) 138

58. SCENARIO C4: FOREST MODEL (BOARD 42, BOARD 47 - FIGURES 207 TO 211) 139 59. SCENARIO E: IMPLANTATION OF THE AQUATIC SUBSTANCE UNIT (PLATE 42, BOARD 48 - FIGURE 212) 140

60. SCENARIO F: ESTABLISHMENT OF THE COTTAGE UNIT IN A MARKING AREA (BOARD 42, BOARD 49 - FIGURES 215 AND 216) 140

61. RELATIONSHIP BETWEEN ELEMENTS OF WATER, WOOD OR FLOOR 141 1. PORTAGE OF THE COCKPIT MODULE (BOARD 42 - FIGURES 142 TO 154, BOARD 48 - FIGURES

212; 141

2. GUIDING ELEMENTS (BOARD 48 - FIGURE 214) 141

3. SUPPORT OF SUPPORT (BOARD 48 - FIGURE 214) 142

4. TRACTION CABLES (BOARD 48 - FIGURE 212) 142 J. TENORING GUIDES (BOARD 48 - FIGURE 212;

6. MANEUVER WINCH (BOARD 48 - FIGURE 212) 143

7. FLOTATION 143

8. SAFETY BUILDERS 143

9. SAFETY OF DESOLIDARIZA TION OF THE PLATFORM COMPUTING UNIT THE SUPPORTER 144

10. HEADLIGHTS 144

11. AQUATIC MODULE WITH SINGLE GUIDE CYLINDER 144

12. AQUATIC WATER BALANCED MODULE 144

62. ALL WOOD CABINET MODULE (BOARD 5 I - FIGURE 232, BOARD 52 - FIGURE 233 - PLAN ₁ CHE 53 - FIGURE 235, BOARD 54 TO BOARD 58) 145

63. DRAWINGS 148

ABRIDGE 149 DEVICE ASSEMBLY FOR EMERGENCY AND EXTREME EMERGENCY NEEDS 149

1. HABITACLE MODULE 149

2. THE LEG 150 3. THE MOUTH 150

4. COCON 150

5. PASSENGER SURVIVAL ambulatory _{5 5} SAS 151

6. SUPPORT HAND 151

PLANKS 153

PREAMBLE

Faced with the atmospheric disturbances and in front of a nature become too sensitive and capricious by the force of the times and the men, in front of notorious cataclysms, like the earthquakes (Kobe-Japan), the tidal waves (tsunami-Asia), the cyclones (Katherina-USA), among many others, as well as floods, destructive winds, spectacular forest fires, melting ice, it becomes urgent and imperative to be equipped with adequate means to deal with these extreme events and in increasing numbers. Today, the means to implement in the face of the survival of humanity are not to be neglected and must be reconsidered. Therefore, the desire and the desire to undertake the implementation of modules to address these concerns that have become very urgent is essential.

This project aims to respond to these phenomena by proposing a complex device including a passenger compartment module and its annexes. The cabin module (set of cabin elements and technical elements), allows in a context of extreme natural disaster, the survival of an individual or group of individuals. The module described in this project represents the almost universal basic element in logistics; it presents the best criteria for the survival of people because, the most advanced and the best adapted technologically to such disasters. The module and alternative models have the same purpose, however with lesser technologies and composite or natural materials less suitable for emergency characters and with a minimum of technology. This is why the basic module is described as a whole because it can cope with all extreme situations. The basic module has three models that identify with the following names: • Model 1: Achilles

• model 2: Icarus

• model 3: Atlantis

• basic model.

Achilles model (Plate 4 - Figure 6)

The Achilles model is recommended for seismic zones. It is strictly identical to the Icarus and Atlantis model. Only the support system is different. The support of the Achille model is static, however, it pivots on its axis at 360 ° on its horizontal plane. Icarus model (plate 4 - figure T)

The Icare model is recommended for flood zones. It is strictly identical to the Achille and Atlantis models, only support differs. The support for the Icare model is animated vertically in its axis (up / down). This system allows a rise in case of rising water abundantly and abnormally. The elevation is automatically done by a system of pneumatic or hydraulic cylinders with sufficient compression thrust to withstand the constraints necessary for the proper functioning of the entire passenger compartment module.

Sensory probes are located at the receptacle, outside, and are synchronized to the visual and audible alarm system, itself being subject to the automatic control system of the rise in elevation of the passenger compartment to the desired height

(height limit according to structure and system configuration in context). A manual control device is installed in parallel with that of the automatic system.

Atlantis Model (Plate 4 - Figure 8)

The Atlantis model is recommended for cyclone zones and tsunami risk areas. The Atlantis model is strictly identical to the Achille and Icare models, only the support system differs from the Achille system and is similar to the Icare support system.

The difference is in the mouth enveloping the passenger compartment module in the low position. Once absorbed by the mouth, the module is totally safe from the cyclone (wind greater than or equal to 250-300km / h), as well as to a possible tsunami (immersion compared to the upper lips of the mouth substantially equal to 15 meters in immersion stability).

The closed module and mouth system must be completely water tight. The minimum survival system then triggers automatically (oxygen, hydrogen, communication, radio links, lighting, etc.) as well as the security system.

(location, underwater vision, periscope vision, night vision, distress beacon, etc.).

Basic model (plates 1, 2, 3 - figures 1, 2, 3, 4, 5) CHAPTER I - STRUCTURES

§ 1 - Basic structures (plate 6 -figure 10)

The structure is adapted to the mechanical needs, it is able to support certain atmospheric constraints of different nature. This can be of different shapes, colors and sizes.

The structure is made of lightweight material, preferably, able to withstand certain load constraints and adapted to the contexts envisaged, taking into account overloads (occupant, furniture, etc.). The walls of the shell (1) are hollow to allow the dual circulation of the heating or cooling solution. The constitution of the shell is made of material likely to withstand extreme temperatures in degrees Celsius.

1.1. Receptacle (Plate 6 - Figure 10) The receptacle (2) is located in the lower part of the shell and comprises virtually all technical systems to ensure the operation of the various systems providing viability of the whole. In the upper part of the receptacle, there is a floor (3) light structure and may be different in nature provided that it complies with all safety rules and technical standards in force, whether European or international.

1.2. Hat (Plate 6 - Figure 10)

The hat (4) is located at the top. It is made of material adapted to the necessary needs in order to satisfy the wishes of a good functioning. The hat must let in natural light and be treated against ultraviolet rays. Its structure is adapted to the extreme mechanical and physical needs, especially in terms of temperatures and particular and aggressive radiation of whatever nature. The material allowing the passage of natural light has a thickness adapted to the different types of radiation existing and known to date. Under the hat or on the side parts receiving natural light, a concealment system is set up (5). The material used for the passage of natural light is mounted on a specific anti-seismic system (plate 33 - figure 74 (5)). 1.3. Blackout system (plate 6 - figure 10)

The blackout system (5) is made of light and strong material. This system conceals the natural light and thus plunges the whole interior in total darkness. It is driven by a system allowing the automatic closure of the eye accompanied by a complementary manual system. A mesh (6) mesh resistant to shear and at certain temperatures is placed under the existing shutter.

1.4. Cargo access system (Plate 37 - Figures 90, 91, 92)

The access to the cabin is made using lightweight material and suitable to withstand certain physical loads and extreme temperatures. The entire access or exit of the cabin is achieved by an automatic system accompanied in parallel with a manual system. It also consists of automatically foldable body guards that are an integral part of the system. This system may be either stair-type or vertically swinging door type or fixed or mobile carpet type.

1.5. Access to the passenger compartment (plate 7 - figure 11)

Direct access to the passenger compartment consists of the opening (1) cut at the shell. It can be of different shapes and dimensions sufficient to allow the passage to all individuals, whatever they are. At the opening, a leaf adapted to the same physical characteristics as the hat is set up. A watertight door, which may be different, is put in place (plate 7 - figure 11, plate 18 - figures 34, 35, 36, 37).

1.6. Foot (Plate 8 - Figure 12, Plate 9 - Figures 13, 14, 15)

The foot is constituted (1) of a physical medium of light material that can withstand all temperatures and physical constraints, atmospheric subject to the module.

1.7. Heel (Plate 10 - Figure 16 (2)) The heel (2) is made of lightweight material that can withstand all temperatures and physical, chemical and atmospheric constraints, subject to this set and overall elements. 1.8. Leg (Plate 10 - Figure 16 (3I)

The leg receives the foot; it consists of coolers and heaters.

1.9. Ambulational airlock or survival lock (Plate 11 - Figure 18, Plate 12 - Figures 19 and 20)

The ambulatory chamber (1) allows the connection between itself and the mouth. It allows emergency evacuation and as a last resort, the passenger compartment module through the airlock (2) which allows the evacuation to the outside, or in the opposite direction, the access to the passenger compartment. coming from the outside. An airlock with an eye of beef (3) allows evacuation even in the context where a body of water hinders the orifice. The manhole allows the passage of two people in front (evacuation PMR). A ladder (4) adapted to the emergency evacuation is placed vertically in the airlock. The airlock consists of hollow walls (5) for cooling the whole, through coolers (fluid or gas) adapted to the situation. The cover (6) of the lock of the eye of beef allows a vertical opening, either upwards or downwards. The openings and closures are automatic and are subject to a manual system.

All the operation of the whole is controlled by a visual or sound security system which is subjected to the computer in order to control all the differences of temperatures and the various degrees of alert, in connection with the chemical, atmospheric and various radiations.

A bellows system (7) of materials and composite elements placed at the corners respecting the radii of curvature and uniformly distributed in horizontal and vertical linear part ensures a perfect seal between the coupling elements (8). This system also allows the absorption of seismic waves by the deformation of bellows sinusoidally in amplitude, vertically and horizontally, and linearly, in tension and compression. An automatic system associated with a manual system allows the vertical projection towards the outside of the lock chamber by extensible jack of identical variable geometry and narrowed each time the element is raised to the outside, in order to reach a sufficient height. facilitating the exit of the module or its access in the case where an individual is in a critical situation. According to the survival lock, it may not have an emergency evacuation outlet (plate 12 - figure 19), or only an evacuation cover without extension or telescopic lock (plate 12 - figure 20). 1.10. Expandable telescopic airlock ( ^" plate 13 - figures 21, 22 and 2Tι

An extendable telescopic airlock is installed on the upper part of the ambulatory survival chamber.

1.11. Mouth "Element B" (Plate 14 - Figure 25 QY)

The mouth (1) is the system that allows to "swallow" the entire cabin.

1.12. Protective Shield (Plate 14 - Figure 25 (2))

The protective shield (2) protects the passenger compartment module and is fixed at several points of the mouth, in elevation.

1.13. External structure (external cage) (plate 7 - figure 11)

An external structure (2) enveloping the passenger compartment module is produced. The structure is made of lightweight material and resistant to all atmospheric agents, pressures and extreme temperatures. The external structure is fixed to the outer walls of the module using spacers fixed by rivets or welded using specific welds. Sufficient space allows the passage of any pipes and a mixing of air for natural ventilation or cooling. This external structure thus produced makes it possible to fix the solar panels and the suspended mobile peripheral terrace which is actuated by a system of jacks.

The external structure remains the support of all the fixing complements relating to the various elements that can occur in complementarity of the necessities of natural and technological comfort in the passenger compartment module.

1.14. Internal structure (internal cage ^" ) (plate 7 - figure 11)

An internal structure (3) is formed inside the module in the passenger compartment. The structure is made of lightweight material and resistant to all atmospheric agents, pressures and extreme ambient temperatures. The internal structure is fixed to the inner walls of the module using spacers fixed by rivets or welded using specific welds. Sufficient space allows the passage of air for additional ventilation and the passage of special cables and pipes. This structure allows to fix the "partitions" or interior walls of the passenger compartment. Sleeping supports as well as the hydraulic system or pneumatic are fixed on the wall support, on the one hand in the vacuum, between structures supporting the cylinders, on the other hand.

This structure also makes it possible to support the beds in vertical position (inactive) or in horizontal position of sleep (active). The structure supports elements that can be added to the needs of natural and technological comfort in the habitat.

1.15. Flotation (Plate 15 - Figure 26) A peripheral float ensures the floatation of the entire passenger compartment module. The float is placed under the side guards provided under the protection elements and is controlled automatically. The flotation system is made of material capable of withstanding certain pressures; it is relatively deformable to absorb lateral shocks of medium intensity and to accept the limits constraints of the context. The floats are of two different types: the first type of float is placed at the upper periphery of the receptacle (1). The second type of float (2) is placed on the one hand in the lower part of the shell, on the other hand in the upper part of the shell. The latter thus prevents possible shocks of certain natures that can survive. The lateral protections are in action or not according to the context of the operation. The floats are in the capacity of special gases, compressed air or other compositions providing the most reliable flotation means possible and best adapted to the context. The whole is managed by an automatic system associated with a manual system. The floats in the rest position are in peripheral boxes, protected by closed elements with a magnetic base. When the context requires it, the floats inflate automatically and release, by pressure, the protection elements.

1.16. Horizontal turbine turbine (Plate 16 - Figures 27, 28, 29)

The entire wind turbine is constituted by a blade (1) and turbine system associated with a heating system (2) adapted to the context and the structure of the wind turbine.

1.17. Paddle Wheel (Plate 17 - Figures 30 and 31)

Paddle wheels can be attached to the sides of the passenger compartment module, in opposition. 1.18. Emergency ladder

An emergency ladder placed judiciously in the cockpit allows in case of extreme necessity and urgency to evacuate the passenger compartment module by the hat. This ladder is made of strong and lightweight material.

1.19. Doors (Plate 18- Figures 34, 35, 36 and 37)

The doors are characterized by their type of design and structure. These doors are double-profile assembled by rivets, screwed or welded using welds adapted to the composition materials of the element. These doors include inside their volume space a number of elements:

• a main compressor injecting the compressed air through 4 to 6 cylinders placed diagonally at the 4 corners of the door;

A double peripheral tubular circuit containing air under pressure intended to simultaneously push the pistons which in turn actuate the shoe which then plates the periphery of the door, thus ensuring a perfect seal in a normal situation but also in a pressure or explosive depressurization. The pressures being equal (depending on the context) on one side of the door and on the other side, the force remains stable by the effect of the outer and central groove.

The door has a possibility of manual opening via a specific linkage

1.20. Supplementary Door (Plate 7 - Figure 11)

At the level of the passenger compartment module, a complementary door (5) located in a lateral plane or in affixation with the main access door is necessary in the case where a group of interior modules would be formed or produced according to the wishes. This second door is of the same type as the main door and the same structure in design.

1.21. Spherical stop (plate 7 - figure 11)

A spherical positioning stop (4) of the passenger compartment module allows the descent and the rise of the latter in conditions relating to the proper positioning of the assembly. An abutment is placed at each guide angle (top and bottom) of the module, to ensure stability and placement during up and down operations. 1.22. Tank (Plate 14 - Figure 25)

The tanks (8) (9) are adapted to each specific need and each located at locations allowing their accessibility and functionality. The tanks can be grouped, grouped or independent. They are treated against all bacterial and chemical attacks as well as against radiation. The tanks are of sufficient size to meet the requested needs. Each type of tank is provided with the necessary safety devices for its proper functioning as well as the safety and security of the passenger compartment module and its ancillary elements (water, waste water, pressurized water, drinking water, water in reserve, filtered water , hydrogen, oxygen, gas, etc.).

§ 2 - Possibilities of extension and complements of structure

2.1. Setting up an elevation (floor)

An additional stage can be added above the passenger compartment module to create an additional volume; in addition, it also allows central or lateral access to the main volume. A PMR riding system is put in place, if accessibility to the upper level of the high floor (floor) is desired. The system can be mechanical pneumatic or hydraulic and is adapted to the security and safety of the context. This elevation has an internal and external technical aspect similar to the passenger compartment module as well as the same electrical and detection, communication, safety and security technical characteristics.

2.2. Classic Footbridge (Plate 50 - Figures 224 and 227)

In order to communicate between the different surface cabin modules, one or more gateways of conventional type and special character provide interconnection at the desired elements and modules.

2.3. Footbridge / gallery / ambulatory / survival chamber (Plate U - Figure 18, Plate 50 - Figures 224 and 227) Gateways / galleries (1), of the same type of material and with characteristics identical to the outlet or entry tube emergency room and the cabin module, can be implemented to ensure the interconnection and interconnection modules between them. They can be either fixed and independently buried, aerial or on the ground, or mobile in the horizontal plane; in this case, the entire gateway / gallery is supported by a special anti-seismic support, adapted in the vertical plane by a set of jacks allowing the assembly to be raised or lowered.

This bridge / gallery is adapted to the needs of extreme urgency. The configuration of its envelope can be covered with panels or solar films adapted to the context.

The walkway / gallery / ambulatory has all the technical characteristics identical to the passenger compartment, regardless of electrical, protection, communication and integration in the context of the moment

CHAPTER 2 - INTERIOR DEVELOPMENT

1. Furniture: tables and chairs ( ^" plate 19 - figure 38)

A set of furniture consisting of a table (1) and chairs (2) (or chairs) is arranged in the center of the cabin module. This assembly moves vertically from the base of the floor to their respective housing from top to bottom and from bottom to top, in order to take the recommended position to reach the seating point (for chairs or armchairs) and to the recommended position relating to the taking of meals. The chair or chair backrest (3) has a double envelope so that it can also be embedded in the floor element (4) (bearing surface) and thus allow, when the assembly is at rest, to walk on the backs chairs or armchairs, or even on the table (then again floor).

The assembly being recessed (at rest) in the floor surface, the activation of the working surface is done by means of hydraulic or pneumatic cylinders (5) thus allowing the vertical displacements with possibility of rotation. The table and chairs are made of light and strong material; they can also be in traditional material (wood, for example).

2. Storage

The additional storage space is located at all horizontal or vertical places that can be arranged, especially in the corners, corners, corners of the passenger compartment. Storage space is provided for module repair or troubleshooting tools, as well as for mobile measuring and sensing devices. Similarly, there is provision for independent storage for old oxygen cylinders or other types of containers, necessary for survival or different types of interventions (harpoon, flare, distress rocket, light weapon, others).

3. Sleeping (Plate 19 - Figure 38)

The coating (6) is laterally and peripherally of the passenger compartment. Each side part, with the exception of the access and distribution passages, has three beds, the base bunk of which is at a relative distance from the low floor, thus allowing storage of various belongings. The beds consist of mattresses, dressed in non-slip material and materials adapted to sleep comfort. The mattresses are water or air. In the latter case, a compressor placed at the receptacle, in technical area, allows their supply. Only the bench seat remains fixed to ensure a comfortable seating.

4. Mattress support

The mattress support consists of a lightweight material structure, supporting the mattress and the load or overload (with inertia or inert). Folding of the beds is done by automatic, pneumatic or hydraulic system. The beds are folded vertically along the peripheral walls of the passenger compartment (the control of tilting or folding of the beds is individual or collective), so once the operation is carried out, the walls of the passenger compartment remain smooth and free thus a larger area and a larger volume. Special and sustained attention is given to the specific PMR berth.

5. Sleep coverage

A light cover made of thermal material to protect against high or low temperatures (hypothermia, ...) is available.

6. Shower room The shower room consists of a shower enclosure (integral), a thermoformed washbasin, a natural composting toilet (no flushing water, no water tank). Natural compost disintegrates organic matter. It is expected, however, in parallel a toilet mounted on cylinder allowing its descent or its rise automatically. The dimensions of these elements are characterized by a minimum size. The materials used are of the light type.

The water room part is waterproof on the one hand, and waterproof on the other hand. A water tank is only for showering and hand washing. A particular design is realized for the sanitary appliances themselves but also for the furniture or the support to integrate them or to support them. The structures are light and resistant. 7. Sauna

The sauna consists of an integral cabin made of composite or traditional material

(wood, etc). This cabin is equipped in the context of a particular stove, a special spoon for pouring on the stones giving off steam and a water bucket. Operation management is associated with the on-board computer that manages the temperature of the sauna and thus controls the emergency opening of the appropriate safety system. A clock is programmed to prevent any potential life risks. A telephone particularly adapted to the sauna is set up inside it. A direct emergency stop contact is placed inside this volume. Inside the sauna, a safety bracelet must be placed either on the wrist, ankle or the user's belt. This bracelet controls the heart rate, the skin temperature, the temperature inside the sauna area, the degree of hydrometry, the frequency of pulmonary ventilation and the vertical stability of the balance. In case of emergency, the systematic information is taken into account and depending on the degree of intervention, a transmitting TV informs the specialized services of the type of external information. A visual and audible alarm is triggered at the passenger compartment module. By double security, a signal by physical action of the user is transmitted every two minutes. The computer then manages the constancy of the activity through the security system.

8. Kitchen

The kitchen has all household appliances or industrial ensuring the proper functioning of the culinary context. Low density, the kitchen elements are sizing reduced to the minimum (mini equipment) and recessed in furniture adapted to the needs. The equipment includes at least:

• an electric plate,

• a steam cooking vessel,

• a traditional mini electric oven,

• Microwave oven • Washing machine

• a clothes dryer

• a dishwasher

• fridge, freezer, • a coffee machine

• kettle, ...

All devices requiring this are subject to the visual and audible control panel (shutdown, operation, fault alarm). A particular design is realized for the household appliances themselves but also for the furniture to integrate these. The structures are light and resistant.

9. Mini-bar A mini-bar is installed in the passenger compartment module. The request and the distribution are made according to the agreement or the refusal of a card reader coded and decoded in a specific way, authorizing or not the source of the requested drink. This authorization allows distribution adapted or discouraged for each type of individual; minors are not allowed to consume drinks other than those adapted and desired in the context of their maturity and health.

10. Relaxation, culture

A general library, a general directory, etc. can be consulted on compression discs that can receive a maximum of data capacity.

11. Dome, canopy (decoration) (plate 15 - figure 26)

The dome or the canopy (16) is constituted according to the presented case of anti-reflective glass.

Regarding the decoration theme of the domes or windows, painted patterns or stained glass can be made according to the chosen choice. The dome or the canopy is of the anti-seismic type.

CHAPTER 3 - PROTECTION OF THE MODULE IN EXTERNAL SURFACE AND

CONSTANT POSITION

1. Protection cocoon "Element E" (Plate 20 - Figure 39) The module is protected by sliding panels resting either on a group of rails (1) or on a single rail. The panels can be of the same type as the panels of the passenger compartment module, either of composite material or of wood. As a result, each panel can be either internally reheated or internally cooled. They can also be made more conventional without cooler or heater. In the upper part of the panels is a natural lighting (2) made anti-seismically.

2. Cocoon panels (pumps and distribution compressors) (Plate 21 -Figure 40) At the bottom base of each panel constituting the cocoon, in the plane slightly greater than that of the traction wheels of the panels, nipples (1) with multiple ducts (hot, cold, hydrogen, oxygen, water, air, etc.) allow the distribution at the entire surface of the panel through various pipes and inner pipes (2). One or more compressors (3) and pumps (4) adapted to each circuit allow the distribution under pressure of fluids or gases appropriate to each need. This system thus put in place makes it possible to maintain a temperature in an extreme situation of natural disaster.

3. Sowing (Plate 21 - Figure 40)

The panels are put in sidings when the cockpit module must be in the open air. The siding (rest) is performed by motors acting on wheels that actuate gear wheels or friction. The wheels are on a fixed vertical axis or on an axis of revolution allowing the gear wheel or the friction wheel to perform the necessary rotations on their own axis to allow the siding of all the panels , and thus ensure the smooth running of the whole.

4. Programming and operating modes of the siding of the panels constituting the cocoon (Plate 22 - Figures 41 and 42)

The panels are controlled by automatic systems allowing the cocoon to be parked in the garage. The system consists of nipples; he understands the main nipple (general), the main nipple (master), the secondary nipple (slave). When passing the first panel (panel # 1), after being detected and recorded by the general main pin, the first main pin called master detects the first panel, thus the first wheel of the first panel is directed to the channel assigned to the first one. sign. The secondary nipple called slave detects the second wheel of the first panel and directs it on the same assigned lane. Thus, the first panel is put is placed in siding on the first track (lane No. 1). When passing the second panel (panel No. 2), after being detected and recorded by the main stud, the second main stud (master) detects the second panel, thus the first wheel of the second panel is directed to the path assigned to the second sign. The secondary stud (slave) detects the second wheel of the second panel and directs it to the assigned channel. Thus, the second panel is set up in the siding on the second lane (lane 2). The operation then takes place until the completion of the installation at the sidings.

Regarding the replacement of the panels to provide protection in the form of a cocoon, the operation is carried out in the opposite direction of the siding (put to rest) and paradoxically a contrariori, the function of the nipples is also reversed in the order of repositioning cocoon. The main nipples (masters) become secondary nipples (slaves) and the secondary nipple (slave) becomes the master nipple.

Functions and inverse functions of the nipples, the main general nipple being named 0

Basic functions Reverse functions

0 = l <0> 2 P6 = 14 <0> 13

Pl = 3 <0> 4 P5 = 12 <0> ll

P2 = 5 <0> 6 P4 = 10 <0> 9

P3 = 7 <0> 8 P3 = 8 <0> 7

P ₄ = 9 <0> 10 P2 = 6 <0> 5

P5 = 1 <0> 12 Pl = 4 <0> 3

P6 = 13O14 0 = 2 <0> l

5. Siding Mode Selection (Plate 22 - Figures 41 and 42)

The siding mode selection is made by choosing the panels to move and park. An automatic selection system assigns the position and performs the setting place of the desired panel in a logical and functional order relative to the logistics implementation.

A main pin takes into memory by reading coding, electronic decoding, the number of the panel to select and to position. Similarly, the decoding of the first wheels give the position to be attributed to the siding. A secondary nipple ensures the positioning of the second wheel at the level of exchanger, the operation is repeated in the same way until the total implementation of the assembly siding. The operation is performed in reverse when redeploying the panels in the passenger compartment protection position.

6. Solidarization and separation of the panels (plate 24 - figures 48 and 49)

The fastening for the circular placement of the panels is in the opposite direction of uncoupling. The joining is done automatically or manually. A vertical cylinder (1) on which are fixed parallel blades (2) in the form of a hook, controls the support of the panels (3) (coupling) or the disconnection (siding) when the master panel is activated. Two gears (4) driven by two independent motors (5) (front and rear) are decoded by the secondary nipples, the traction cylinder (1) is then in revolution movement by the toothed wheel (6) and hangs the blade vertical (2) of the other panel (secondary panel or slave). The main nipple then records the passage of the second panel and the operation is repeated until the panels are all in protection at the passenger compartment module. The system is managed by the on-board computer. A manual safety system is subject to the automatic system. A block diagram of parking makes it possible to understand the operation of the taking into account of the panels (plate 22 - figure 42).

7. Rail support (Plate 21 - Figure 40, Plate 22 - Figure 42)

The rails are supported by an anti-seismic and anti-vibration system. At the top end, each panel is supported by an anti-seismic system. A holding bracket is made of composite material ensuring on the one hand the elasticity of the system, and the rigidity on the other hand. The holding bracket can be single or double. It is made of rigid and lightweight material. Anti-seismic systems are put in place at the base of the stem and at the end of the latter. The assembly thus produced is capable of absorbing all the seismic waves without damaging the whole. 8. Natural lighting (Plate 20 - Figure 39)

A natural lighting system is put in place on the upper periphery of the protection panels. The openings are protected by appropriate anti-burglar grilles. An access door is integrated at one of the panels to allow accessibility to the passenger compartment module. The panels can be coated with a support adapted to receive solar panels. It is also possible to adapt and support in the upper part of the panels, a wind turbine system.

9. Detections Detection and security systems (theft, intrusion, fire, etc.) are put in place at the level of all the panels inside the volume protecting the module. They can also be installed outside the volume of the set of protection panels as well as around accesses within a radius of about fifty meters (infrared detectors, etc.). Protection is thus guaranteed day and night and in all weathers.

10. Electric box

An independent electrical box manages and provides electrical protection for energy needs and remote controls. The cabinet can also be associated with the specific controls at the cabinet level concerning the control of the passenger compartment module. As a result, the onboard computer inside the passenger compartment module can also automatically control all electrical, mechanical and other technical suggestions. A visual, sound, olfactory security is put in place.

11. Tagging

The markup is able to trivialize and debanalize the passenger compartment of the module by the fact of all the panels ensuring the protection of the latter. This markup is in principle similar to the airport and / or port marking.

12. Communications

The communications system is identical to that defined in the passenger compartment module (transmission, reception, detection, frequency, etc.). An ultra-sensitive device is set up at the level of this protection in order to demodulate, reconvert, to parasitize or de-tamper all communications in the context of exceptional event related to the natural context in extreme situation.

13. Implantation in a natural or special site The implantation and integration of the module and its protection must be adapted according to a specific wish to the colors and pigments of the natural or considered site. The module and its protection can then display the desired colors or remain in the original natural state. The cocoon of protection can also, according to the wish, be totally translucent in a certain context. This is to view by transparency and to bring maximum natural lighting to the passenger compartment module.

14. Revolutionary movements

Rotation of the entire cocoon may be effected by means of a drive system (toothed wheel, friction) or drive chain or by any other physical means, mechanical, allowing this operation. The rotation of the protective cocoon makes it possible to achieve optimal reception of waves and radiations necessary for the operation of the assembly and thus to obtain maximum efficiency when the solar panels or films are subject to active radiation. The rotation takes place at the level of the era with the help of an automatic tracking of a sun chart, following the sun from sunrise to sunset.

In parallel, an infrared detection clock supports the operation. Thus, in cloudy weather and filtering, the solar radiation remains effective through the receiving surfaces of the solar panels. Moreover, this operation can be done manually.

15. Anti-bacterial screen

An anti-bacterial screen provides protection against bacteria and possible viruses.

An internal coating adapted to the needs is put in place at the level of the internal and external walls on all their surface. In complementarity, a double cocoon can be put in place to reinforce safety and security according to the context. The detection and alarm are adapted to each situation and managed by the central computer of the passenger compartment module. CHAPTER 4 - SPECIAL EQUIPMENT

1. Cable and grapple

The cable (rope) and the grapple are made of a light and solid material, adapted to the physical, chemical and atmospheric constraints encountered. The cable has a sufficient length allowing the component of the passenger compartment module to be drifted in order to subtract any harmful aggressive and abrupt physical elements at a limit state that can destroy the stability of the assembly. The anchor or grapple is attached to one end of the cable allowing a physical grip thus stabilizing the assembly. The cable and the grapple are housed in the cable box, located at the receptacle and managed by an automatic system associated with a manual system.

2. Anchor Hoop (Plate 28 - Figure 65)

An anchoring hoop is distributed only on the periphery and in the basement of the mouth of the mouth, under the supporting hand. The mass of the mouth and the mass of the supporting hand constitute the mass of the anchoring hoop to which is added its own mass. The anchoring hoop makes it possible to compensate for the suction "bubble effect" between the mouth and the supporting hand, if pneumatic delivery occurs and thus avoids the accidental raising of the mouth / cockpit assembly due to a possible lack of waterproofness that can occur during context of simultaneous events and natural phenomena (wind, water, earthquake, extreme warming of the ground, extreme cooling of the ground).

The anchoring hoop (1) is connected to the mouth (2) by composite cables (3) stretched so as to allow certain deformations to their limit states in the context. The cables are connected to automatic special elements (4) (jacks, springs), providing additional security deformation and managing the tension and elasticity of the latter. In this way, the cables can be either stretched or relaxed, depending on the degree of the natural phenomenon and thus allow a certain compact stability of all the elements module, mouth, facing the deformation of the natural ground and the components of the hand support (5). In case of absolute necessity, a control device makes it possible to undock the mouth, in order to separate the mouth from the supporting hand and thus to protect the passenger compartment module that has become completely independent of the other elements. The entire hoop is managed by the on-board computer associated with a manual control, the set of audible and light horns being subject to the control computer.

3. Exchanger (Plate 25 - Figures 54, 55 and 56)

The exchanger is an element ensuring the diversion of a circuit in order to allow the continuity of operation of this single circuit or group of circuits, as the case may be. For example, a manhole being made, derivations and circuits perpendicular to this hole, must then be deflected. This derivation is done by contour adapted to the physical form of the continuity and the hole. Depending on the case, the cables and conduits carrying fluids, or the hollow walls circulating gases or liquids, are diverted in the same way. This particular part can be implemented by specific welding or any other physical means to ensure imperative operating reliability. A perfect seal keeps the system in operation, whether permanent or permanent, at high pressure.

4. Particular high-pressure duct (plate 25 - figures 52, 53 and 58, plate 26 - figures 59 and 60, plate 27 - figures 61, 62 and 63)

The particular high-pressure ducts ensure either the cooling or the heating of the structure of the passenger compartment module and / or of the various structures attached to the other elements to an extreme degree. Hollow ducts in line (1) or hollow alternatively

(7) carrying a fluid or a liquid adapted to the need for heating or cooling are adapted to the same principle as the exchanger. These same ducts can also be designed to convey, simultaneously, several ducts (2) into each other in a hollow duct (1), and thus convey liquids, gases, different fluids resulting in perfect operation in hyper warming and hyper cooling.

The sources and source groups of these conduits, their contents are located at the origin and / or end of areas and technical premises provided for this purpose. The entire system is provided in the character of explosion-proof elements.

5. Support Hand (Plate 28 - Figure 64)

The support hand of the cabin-mouth assembly, rests on a support called hand. It is able to partly absorb the seismic waves and to compensate and stabilize some parts of the deformable soil, on the other hand, some notorious deformations. Different composition elements are essential in this configuration, and are divided into a number of layers, the system relating to the interface consists of a set.

6. Ballasts (Plate 15 - Figure 26)

The ballasts (3) are placed in the receptacle and under the float. Their function is flotation balancing or stable emergency immersion, if the context is suitable and for a dive capable of reaching a certain number of meters (instant tsunami). The ballasts are filled or emptied by pumping or discharge, either in a closed system or in an open system (water recovery in the surrounding environment and in the context). The pumps (4) are of submerged type and completely sealed. Their flow capacity remains adapted to the most extreme natural criteria and phenomena.

7. Balloons (Plate 15 - Figure 26) Balloons (5) are placed at the peripheral base of the cap. They ensure on the one hand, the rise of immersion in case of failure of the ballasts, on the other hand, the sensitive displacement of a few meters in the air, or on the surface of the water, to ensure a rescue on purpose, allowing for a mini emergency navigation. The gas used for inflating the balloons is, on the one hand, the oxygen for the immersion lift balloons, on the other hand, the helium for the parallel balloons, for example, making it possible to double or triple the volume of the balloons. these and thus to obtain an easy lift in the air and atmosphere ensuring the substantatory and kinetic movement of the passenger compartment module.

Compressors adapted to the needs are placed in the receptacle in the technical zone or at a suitable location other than the technical zone allowing it, and protected from any possible constraints.

8. Rudder (Plate 15 - Figure 26)

A rudder system (6) of material adapted to the needs is placed or fixed at the receptacle. It consists of a sufficient surface to respond to various maneuvers and thus allow to move the whole. An automatic system associated with a manual system manages the rudder control. At the level of the floats, a space is created in order to place the rudder. 9. Broken blades (bow) (Plate 15 - Figure 26)

The breakage of blades (7) consists of a blade automatically moved in its movements (placement, removal of the blade). This blade is placed at the receptacle under the outer and lower part, in opposition to the location of the rudder. It is made of lightweight material that can withstand atmospheric, physical and chemical aggressions. An automatic system associated with a manual system manages the placement of the blade break which is synchronized with the rudder. At the blade breakage, a space is created to place the blade break.

10. Propulsion Engine (Plate 15 - Figure 26)

The propulsion of the assembly (cockpit) is done by means of a motor (8) adapted to the needs and wishes. The motor is placed outside under the receptacle. The propulsion is carried out directly by a sealed system. An automatic system associated with a manual system manages the propulsion control. A second possibility is to provide a propulsion axis (9) on which is fixed the propulsion propeller (10)

11. Stabilizer (Plate IS - Figure 26)

The stabilizer (11) is located under the passenger compartment at the receptacle. It is part of the receptacle element and is removable according to the wishes. It softens pitching movements in its vertical axis.

12. Terrace or walkway (according to context) (plate 15 - figure 26)

An outer peripheral terrace is arranged along the structure of the passenger compartment module. It consists of narrow, light gratings, on which can be placed at least a translucent floor (12) with high mechanical strength. A circumferential guard (13) provides protection against tipping. A veranda (14) can be placed on the terrace surface, possibly constituting a complementary volume of approval. The terrace is folded at rest, which then leaves the cabin module free of any changes, if necessary. This terrace is used as such and may eventually become a gateway in the context where the passenger compartment module is in extreme natural disaster, or state of emergency. A jack (15) allows the deployment or folding movement of the platform. 06 000482

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13. Specific lighting (Plate 29 - Figures 66 and 67)

Specific lighting can be installed in the passenger compartment module and its ancillary elements. This equipment is implanted in a horizontal plane according to the envisaged localization, with physical and electrical protections necessary for the security. In a general case, the luminaires are of rotary type with multiple luminance and are implanted in this case at the false ceilings or at certain floors adapted to receive them. These luminaires are capable of producing a number of light sources with different and different colors. When one wants to obtain a different diffuse luminance color, it is sufficient to rotate on its axis or its support the device itself. It is the same, if one wants to obtain a Harlequin color.

The light sources may be different at the base (incandescent, fluorescent, halogen, very specific, etc.). These luminaires can be equipped with protective grilles according to the context and the atmosphere sought. These luminaires may also form a "ceiling" or "raised floor" surface whose structure is capable of supporting their lift surface. This lift system consists of hydraulic or pneumatic cylinders to adapt the illumination surface to the desired requirements (variable illumination coefficient and texture).

The control of these lighting devices can be manual or automatic. The composition of the colors (mixed colors in the plane of the ceiling or mixed colors / Harlequin at the level of an independent device) is managed by computer. A cooling system of the luminaires is put in place (judicious ventilation of the parts requiring it).

A friction wheel, toothed wheel or belt allows the luminaires to rotate in their axis. Circuits record the position of the color of the luminance source, so the automatic remote control allows this rotation to infinity and adapts to the type of the chosen source. The program of the computer managing the system is able to meet every need of implementation.

14. Pneumatic protection pockets (plate 15 - figure 26) In order to protect the passenger compartment module against unexpected and violent shocks, in an extreme context, pockets distributed over the entire outer surface of the module deploy uniformly and instantaneously. The air pockets are shaped to the environments and the best impact receptions. The materials used are elastic and resist all atmospheric and chemical aggressions, as well as the different extreme temperatures. Similarly, several air pockets judiciously distributed inside the passenger compartment volume inflate, during a very violent shock, to ensure the safety of people.

15. Nacelle In order to allow the climbing or the descent of people in substationation wanting to access the cabin module or its platform, a nacelle is provided to satisfy the wishes.

CHAPTER 5 - TECHNICAL SUPPORTS

§ 1 - Electrical technical supports

1.1. General Low Voltage Table (TGVT)

This table manages in energy the various distribution cabinets in normal tension and in voltage relieved by load shedding and inverters of source / generator. It takes into account the urgency of the context, so it distributes a maximum of energy and a minimum of energy (in the context of survival). The set is managed by a PLC which is itself in computer connection and also subject to a manual system. The distribution is also done by needs of alternating current and direct current. The choice of voltages varies from the low voltage (12/24/48 volts) to the choice of a three-phase voltage 220/380 volts. This cabinet is made of durable and lightweight material, completely waterproof. All equipment is explosion proof.

1.2. Main cabinet low voltage

The main low voltage cabinet includes all the departures and all the protections necessary to ensure on one hand the protection of materials and materials (circuit breakers, ....), and on the other hand the protection of people (inter-differential) . Each protection is calibrated according to the current intensity to be transported. The transport cables respond to the intensity to be conveyed. All cables are fire-resistant and some have special shielding in an explosion-proof context.

The head protection of the TGBT includes a general-purpose differential circuit breaker of suitable size for this general protection. This general departure can be rescued. The main cabinet type supplies all the necessary secondary cabinets in the passenger compartment module in the technical zone or on any other interior volume that can be adapted to receive this type of enclosure.

The secondary boxes supply other, alarm reports, remote controls, specific power supplies TBT, very low voltage cabinet that manages all protections and supplies necessary for low voltage requirements. 1.3. Generator cabinet

The generator set cabinet allows the emergency power supply as well as the relative power supply to start the generator. The protections ensure the magneto-thermal safety of the cables according to the intensity called.

1.4. Generator

The emergency power supply is made by one or two generators independent of each other. The power of each group is close to an electrical power capable of supplying electrical energy with a certain number of needs (rectified voltage, cosine φ and stabilized). The generators are controlled at startup independently. The controls are located at the general control panel with ignition control and generator set fault. In case of lack of normal voltage, the generator (s) take over and the group is energized by an inverter without voltage and automatic locking. The set of operation is done automatically with the possibility of manual recovery. The generators must guarantee an excellent quality of soundproofing and are mounted on antivibration system.

1.5. Refueling Refueling is by tank on the generator. In addition, a safety and survival tank allows refueling of both groups instantly. The refueling system is adapted to the structure of the receptacle with all the security measures scrupulously respecting the context. Fuel tanks and lines are of the explosion-proof type. The capacity of the tanks is able to ensure a relative operating autonomy in a context of extreme survival.

1.6. Exhaust generator

The exhaust of the generators is ultra silent; it is independent, and is not in direct contact with the walls or materials at risk of heating or expansion. The structure of the tube or the exhaust compartment consists of a double structure cooled by air or by water. The perfect insulation of the exhaust is ensured by the implementation qualities adapted to the context (quality of materials, radii curvature, single elbow). The exhaust can be on the one hand in the air, on the other hand in the water. Highly sensitive filters located at the level of the exhausts (entry / exit) allow a rejection of the gases in the atmosphere or in the water with special physical system anti-return, thus ensuring a filtration of very high quality. The system is subject to a visual and audible alarm (gas not evacuated, carbon monoxide (CO2)). Check valves ensure the rejection of gases.

1.7. reverser

The inverter acts at the level of the general and / or secondary cabinet and on the generator. The source switching is done by "inverter" in order to resume a supply of energy at the group in emergency or normal recovery (group stop). A visual and audible alarm signals the operation either in normal source (normal distribution voltage) or in emergency source (emergency supply voltage by the generator).

1.8. Inverter

An uninterruptible power supply allows continuous and permanent supply of stabilized low voltage energy requirements. This power supply allows the backup of safety and emergency safety systems in context.

1.9. IT inverter

The computer UPS is dedicated solely to powering and backing up the on-board computer and the memories required for the proper functioning of the system in particular degrees of urgency and stress.

1.10. generators

The generators allow DC power supplies via cabinets provided for this purpose. The necessary protections ensure the good safety of operation. A set of generators implanted at the level of axes of revolution ensure the energy intake and the needs of food according to the wished wishes. 1.11. Alternators

The alternators allow AC power supplies via cabinets provided for this purpose. In the same way, the necessary protections ensure the good safety and the safety of the operation. A set of alternators is implanted at the level of rotating bodies according to the need of energy supply needs and wishes.

1.12. Classic and current power supply

In parallel with the renewable energy context, an installation in conventional low-voltage and low-voltage power supply (220 V / 380 V) is taken into account in the passenger compartment module. A specific and waterproof orifice is recommended for this type of installation. The water supply (valve water) as well as the wastewater discharge are part of the same type of location and spaces related to each connection. The supply of these types of collective or public power supply is the subject of an express request for supply at the level of each dealer concerned.

§ 2 - Technical support in plumbing

2.1. Extraction, ventilation, ducts

An extraction and ventilation equipment system is installed in the passenger compartment module and its ancillary elements related to the context of the operation. Plans and schematics are established for each discipline.

CHAPTER 6 - DISTRIBUTION OF WATER

1. Water decanted for use in water-valve mode

Water is distributed from a system of recycling and filtering water. The recycling system can treat saline water (seawater), stagnant fresh water, fresh river water, sometimes relatively polluted, but once processed to be consumed in chemical criteria and acceptable and authorized by the Ministry of Health according to the standards in force. This water, stored is contained in an independent tank located under the floor of the passenger compartment module, at the receptacle. It is distributed by this tank with a pump whose flow is sufficient to supply water to the bathroom (shower and sink) and the kitchen part (kitchen and dishes).

2. Decanted water for use in the wastewater mode In the case where a chemical or mechanical toilet is installed in addition to the natural compost mode WC, an auxiliary settling system then takes over and is completely independent of other settling systems. (tank, duct and tubing). A recycling system adapted to this use is put in place in the receptacle.

3. drinking water (drinking water)

Clean water for consumption is distributed from a recycling and filtering system. It is also collected by the rainwater recovery system or by the snow water recovery system or by external condensation. Drains located at the cap of the external structure recover, filter and store the water in a second tank. A visual and sound chemical system, supported by microscopic analyzes of the water and subject to computer control, gives permission to consume the water to be drunk.

4. Recovery of rainwater (plate 27 - figure 61) The recovery of rainwater is done by a system placed at the periphery of the roof (hat). At the base of this periphery are drainage pipes storing rainwater (1) and storing it in one or more tanks provided for this purpose. In order to keep the stored rainwater drinkable, a mechanical mixing is planned in the middle of the tank in order to ventilate and oxygenate this water in the best possible conditions of conservation.

5. Specific and special pump (pump / auger)

A particular and specific pump is capable of using the specific support that can be attached occasionally to the passenger compartment module, to drill a moderately hard soil and that to a certain depth, in order to be able, if necessary, to have access to a pocket of water or an underground water table. The specific pump then makes it possible to pump and filter, after analysis of the water by the specific internal system of the mini-laboratory of the passenger compartment module, to obtain all the water necessary to replenish the tanks.

6. Water detector A water detector is responsible for detecting the presence of water, material and various fluids by echoes of determined frequencies and coded according to the type of fluid or material. For example, it allows by hyper-frequencies to detect water present in a tree, a plant, etc.

CHAPTER 7 - ENERGY PRODUCTION

§ 1 - Energy sensors

1.1. Solar panels (passenger compartment module) (plate 30 - figure 68)

The solar panels (1) are fixed vertically on the one hand on the external structure of the passenger compartment module, and partly on the hat. The solar panels are driven by a system of articulated arms or jacks (2). They are orientable horizontally and parallel to the level of the passenger compartment module, but can also be on the cob, like the sunflower flower. Solar panels are capable of capturing sufficient solar energy to meet the needs necessary for the proper functioning of the demand and the expected requirements.

Their sizing and the compound and used materials are able to satisfy the latest technology. With each solar movement, the panels respond to an inclination controlled by the on-board computer in order to capture a maximum of energy. Similarly, the passenger compartment module is automatically rotated against a point of constant optical concentration, thus the solar radiation is thus used to its maximum and the vision of the landscape changes for the observer at the same time. interior of the passenger compartment module. The solar panels are double sided, which allows them a performance capacity much higher than conventional panels. The quality of their coating at the level of the sensors is light in mass and ensures an exceptional concentration. Thus, with each rotation of the passenger compartment module, the energy captured remains relatively constant. The panels are adapted to receive the energy even in foggy and rainy weather.

1.2. Solar panels (protective cocoon) (plate 21 - figure 40)

At the level of the protective cocoon, on a suitable and determined surface, solar panels (5) are put in place. On the one hand, they ensure the energy supply of the cooling and heating systems of the cocoon panels; on the other hand, the additional energy captured is either distributed and used immediately in the passenger compartment module, or stored in the technical spaces provided for this purpose. At night, the sensitivity of the panels is able to receive light radiation from vehicles passing through the area. The reception of this light radiation can then also be stored or used directly in renewable energy.

1.3. Solar panels (mouth) (plate 14 - figure 25)

The solar panels (mouth) (5) are moved from the inside to the outside and vice versa by jacks (6) placed inside the mouth.

1.4. Physical Protection of Solar Panels (Plate 30 - Figure 68) The solar panels (1) are protected by composite panels that cover them in case of emergency. They are thus immune to aggression and radiation of any kind, including chemical, physical. The protections can be united or perforated to capture, even closed, solar energy. The curtains are housed at the level of the curtain supports (4). An opening or closing system is set up along the passenger compartment module and in the upper lateral part. Their order is subject to the on-board computer and the warning and detection systems guaranteeing the safety of the whole. The protective curtains are driven by a motor (5).

1.5. Lunar panels (plate 30 - figure 68) The lunar panels make it possible to receive the lunar radiations and are able to store a certain percentage of energy in order to collaborate to the partial restitution of this same energy. This energy is complementary to solar energy. Lunar sensors are positioned at the periphery of the solar panels. Their capturing surface is equal to about a third of that of the solar surface. The texture and the capturing pigmentation is light in color to receive this lunar energy.

§ 2 - Heating - air conditioning - climaréfrigération

2.1. Heating (Plate 31 - Figures 69 to 72: Plate 32 - Figure 73)

The heater is designed to distribute heat throughout the entire room. H is diffused horizontally either by the vertical walls of the shell, or by the part of the receptacle vertically, or both ways. An automatic system ensures the management and regulation of heating. The heat principle is either radiant or ventilated and laminated by a system adapted to the habitat context. The outer and inner probes give the information to the automatic control system.

The heating is performed by heating turbines with a resistance to rotating electric energy, with fins that can roll the heated air and ventilate, draw or brew. The air source can be reduced or increased by means of a flow and pressure regulator located at the outlet of the compressed air supply head, which must be expanded for rolling, the pressure heads are distributed along the periphery of the system adapted to compression heating. The structure is formed at the base by one or more peripheral tubings. A coil system can convey the hot fluid over longer lengths than linear lengths. The entire system is mounted on vertical cylinders to allow the rise or fall of the heating plane, so we obtain a hot air volume rolled more or less important in compression and temperature. The circuits are provided at their distribution base for hyper-heating or hyper-cooling pumps. The low floor can also be equipped with the same system.

2.2. Air Conditioning (Plate 31 - Figures 69 to 72: Plate 32 - Figure 73)

The air conditioning is performed to air the entire volume. It is diffused horizontally either by the vertical walls of the shell, or by the part of the receptacle, vertically. An automatic system manages and regulates the air conditioning. The principle of air conditioning is either radiant and ventilated, or blown; it is associated with a system adapted to the habitat context. The inner and outer probes give information to the automatic control system.

2.3. Climaréfrigération (plate 31 - figures 69 to 72, plate 32 - figure 73)

Climaréfrigération is the first method tested and adapted to the cabin level. The air conditioning is carried out so as to cool the entire ambient volume by reconstituting it in a volume of air mixed in a suitable manner and according to the wishes and needs requested. It works almost similar to a cooling principle of a refrigerator, but is adapted with specific additions that ensures the regulation of cooling and cooling. Probes forming the new system must regulate a quality of cold in the enclosed cabin, sealed and in a current atmosphere. Climaréfrigération is diffused from the side walls of the shell as well as side walls of the receptacle. A special and special coating is integrated in the inner envelope of the passenger compartment module. An automatic system of internal and external management and control indicate the order of the operating context to the central computer.

2.4. Fuel cell

The fuel cell is the major element of the production of electrical energy. The heart of the cell consists of fuel elements generating energy production that can be consumed (and / or stored) and provides the necessary needs for the proper functioning of the whole. The type of system thus ensures the total independence of the passenger compartment module with the outside or other elements operating with the same battery or a fuel cell independent of the first.

2.5. Storage The storages consist of a set of elements capable of storing electrical energy in order to redistribute it according to the needs of the moment. This energy is transported to specific cabinets through a general low voltage switchboard. Storagers have sufficient autonomy to ensure the distribution of energy called and desired and thus maintain a state of emergency and survival as long as the human body can support. They are made of lightweight material and adapted to their energy storage characteristics (acid, special gases, etc.) and to a small volume of space. Locations provided for this purpose are at the receptacle in technical area and respond to any chemical attack.

The energy supply of the storers is through the combination of the fuel cell and the entire solar panel system, as well as the contribution of the turbo-wind turbine and vertical impellers that can be physically secured. , directly or indirectly, to a system of transmission of electrical energy.

2.6. Low voltage / high voltage reception (plate 11 - figure 18) An appropriate space, possibly to receive a particular auxiliary power supply (9), makes it possible to receive a certain admissible intensity on a terminal box. This box is of sizing appropriate to the desired and requested needs. The Connection terminals placed in the space (9), called X1, X2, X3, X4, X5, XR, have a high power of connection for the connections of the specific electrical cables.

An appropriate cabinet of dimensionings adapted to the needs is located near these terminals. This cabinet is delivered to adapt the necessary protections to the needs of power supply and energy distribution.

2.7. humidifier

Humidifiers placed in certain places allow humidification of the air by ensuring the hydrometry rationally and uniformly at the passenger compartment module and its ancillary elements.

2.8. Structure (Plate 25 - Figures 52 and 53)

The structure of the passenger compartment module and that of the elements or set of elements consisting of simple structure, double structure, multiple structure, allow the operation and ensure the heating, cooling or coupling of the two oppositions of temperature to always stabilize the whole cabin module. Its interior volume has a constant temperature adapted to that of the ambient ambient temperature that can be supported by the human body.

§ 3 - Chimney (Plate 19 -Figure 38, Plate 33 -Figures 74 to 78)

3.1. Heating element (plate 33 - figure 74 (I))

A specific chimney is placed in the center of the passenger compartment module. Its shape and volume are adapted to the configuration of the module and its space. This fireplace can be of relatively varied shape and size. It is made of lightweight materials resistant to very high temperatures. Ventilation orbits for the pressures and depressions of heat are uniformly and judiciously distributed. Under the base of the chimney to rest on the central table provided in the passenger compartment module, a thermal insulation system and a shock absorber made of composite material are installed. The chimney can also rest on the floor of the passenger compartment module, at the bottom. The chimney (heating body) can receive one or more doors adapted to the desired geometric shape emphasizing its practical side of operation and its aesthetics. The body of the chimney is constituted a hollow and empty double wall allowing the circulation of hot air by its own base heat.

The ventilation elements placed at its internal hollow base and half of the heating body, accelerate and regulate the pressure of the hot air delivered. Thus one can get more or less heat ventilated or controlled. The ventilation elements are uniformly distributed at their maximum efficiency. Opening and closing tabs substantially regulate and complement the desired hot air flow at the volume of the passenger compartment module. The internal ventilation elements in the heating body are electric and thermostatic.

3.2. Smoke exhaust duct (Plate 33 - Figures 74 and 75 (2)) A specific smoke-tight and antimicrobial-resistant telescopic duct is installed in the center of the passenger compartment module volume. The duct is composed of several elements: on the one hand, the fixed elements of the duct ensuring the protection of the central cylinder, on the other hand, its own elements intended for the rise or the descent of the passenger compartment module in the vertical plane. All of these elements consists of a thermal insulating conduit for the recovery of special cables strong current or low current, an air gap, a honeycomb duct for ventilation elements between them, a conduit ceramic high temperature, an air gap allowing ventilation and ventilation between the ceramic duct and the mantel heater, a space for the evacuation of the exhaust gas generator.

The chimney flue is telescopic and double-walled to prevent burns by accidental contact. The ducts respect the angles and the number of bends at the flue gas outlet to avoid the presence of carbon monoxide. A carbon monoxide detector is subject to a visual and audible alarm.

The mobile and telescopic chimney duct is constituted by appropriate dimensioning elements that fit into each other; thus, if the chimney rises, the duct moves with all of its elements that fit into each other. Conversely, if the chimney descends, the duct follows the movement, all the elements are disengaged from each other and slide on a vertical plane. The elements constituting the main duct of the chimney are impervious to combustion materials, fumes, water, etc. 3.3. Penetration at the canopy (hat, dome) of the passenger compartment module through the flue (s) (Plate 33 - Figure 74 (3))

The penetration at the dome of the canopy of the cockpit module is made by reservation at the time of molding of the retained material (specific glass for example, etc.). The tightness is particularly neat at these penetrations. The duct must withstand extreme temperatures and pressures in the outdoor context of the interior volume. The penetration of the conduit may be central to its penetration at the level of

"Dome", is central just before the penetration of the "dome" and derived by two or four ducts perpendicular to its axis, then opening in two or four parts at the "dome". The configuration of the "dome" and its structure is then adapted to the context

(shift of the higher structures of the "dome" for adaptation of this circumstance, etc).

3.4. Extractors (plate 33 - figure 74 (4): plate 34 - figures 79, 80.81 and SZ) Extractors ensure the flow of fumes evacuation according to the needs and wishes requested. The fumes extracted by the flue of the chimney are smoke-wood type since the adopted heating base is the wood material in its pure state (absence of chemical and other, ...), with the exception of gas Generator exhaust system that has its own exhaust and exhaust duct, parallel to the chimney flue.

3.5. Sound and visual alarm system

An audible and visual alarm system signals any anomalies in the operation or malfunction of the whole. Likewise, a specific alarm signals a general combustion fault or the defect of combustion of foreign elements other than the wood supplied to the heating body of the chimney.

CHAPTER 8 - SURVIVAL

§ 1 -Technical assistance

1.1. Pressurization (pressure control)

A pressure sensor is installed in the passenger compartment to prevent a lack of pressure or atmospheric pressure to be normally adapted to the individual. The detector is associated with a visual, auditory and olfactory alarm system immediately establishing the alert level and thus acting according to the emergency in the automatic operation of the pressurization or depressurization system adapted to the needs of the moment. The pressurization or the depressurization possibly allows to its limit state of the mini deformations of the structures. The entire cabin and structures are perfectly airtight, water and altitude pressures above 6000 meters and compression pressures that can be encountered at least 10 meters below the level of the fresh water and also adapted to the saline environment.

1.2. Specific combinations

At the volume of the passenger compartment module, in a spacing provided for this purpose, specific combinations are housed in reserve.

1.3. Oxygenation or oxygenation

The oxygenation is carried out so as to oxygenate the whole of the ambient volume at the level of the passenger compartment in sufficient quantity and quality in order to ensure the life and / or the survival at the level of the ambient volume and for a sufficient time adapted to the wishes and needs considered in critical physical and atmospheric situations. Oxygenation is done automatically in addition to a manual system. The oxygen is diffused either by the vertical walls of the shell, or by the part of the receptacle, vertically.

The source of oxygenation emission is located in the technical space. An automatic system ensures the management and regulation of oxygenation. A computer system ensures control. 1.4. Oxygen bottles

A storage compartment located in a space or furniture at the passenger compartment module is provided in order to accommodate mobile and independent oxygen cylinders for individuals in critical survival situation. A relatively larger volume oxygen cylinder is also provided. The latter provides for a while a survival diet for a small group of individuals.

At the main outlet of the bottle, a distribution nurse provides an individual diet of at least 4 departures, for 4 individuals. Hoses at the nanny will be connected. At the end of these hoses, a Y-branch is made. It allows following the need of the moment either to breathe with the nose, or to breathe with the mouth. At each branch, a non-return pressure valve provides a seal if one of the conduits is not used. Thus, if the individual breathes with the nose (lack of pressurization in the passenger compartment, accidental immersion, waterway), the conduit to ensure breathing with the mouth is closed automatically and vice versa. A bottle is provided in reserve following the same principle. Nevertheless, the gas used is of a nature other than oxygen to meet the needs relative to a large depth.

1.5. Periscopes A periscope system is attached to one of the parts of the receptacle, giving visual information in a 360 ° area. Its structure is adapted to chemical agents, extreme atmospheric and resists very high temperatures. It is able to support also important mechanical constraints. It is controlled at the cockpit level by an automatic system accompanied in parallel by a manual system.

1.6. Detection

Sensory sensors and probes, detectors of gases, smoke, flames, heat, infrared, waves, water (inside / outside) pressure, oxygen, ozone, hydrogen , vibrations, bacteriological, carbon monoxide, chemical, dust, luminance, noise, sound (underwater sonar), temperatures (indoor / outdoor and underwater ambient), electromagnetic movements, gasoline { fuel), essences (wood, flowers ...), pollen constitute the detection unit. Each detector has its predefined role and comes into operation as soon as the physical context recommends it. Detectors and probes are able to withstand extreme temperatures and known chemical and bacteriological agents. Detectors and probes are able to withstand high mechanical stresses. They are subject to an automatic control and safety system accompanied by a parallel manual control system.

1.7. Anti-virus and anti-bacterial screen

An anti-virus and anti-bacterial screen is set up. The composition of this screen allows the physical protection of the entire habitat. Absolute and imperative sealing is required. The automatic association of the system is subject to the pressurization and oxygenation system. The decontamination system can be activated either by a liquid, by a powder or powder vapor system, or by ionizing, disinfecting and decontaminating gas. The rotary airlock system provides habitat protection.

1.8. Disinfector

At the level of the anti-virus and anti-bacterial screen placed in the volume of the passenger compartment module, a specific decontamination system is put in place. It provides prevention and gives the degree of contamination according to the type of contamination by visual and sound system. The on-board computer then assumes the management of the operation in terms of the degree and the position to be taken in front of the treatment mode to be adopted, whether preventive or curative.

1.9. Location detection Detection of the location of the passenger compartment is done by radio frequency and / or by electromagnetic waves of a different nature. The location of the position is also by GPS system, or even more powerful. The location is done as soon as possible and with extreme precision. An individual emergency backup beacon, independent of the cabin, is positioned in a compartment provided for this purpose at the module. The frequency is connected to the satellite corresponding to the desired needs. 1.10. guidance

The guidance of the assembly (module) is automatically done by satellite according to the course to follow which is programmed by computer on the frequency of the satellite. With the computer in the cockpit, it provides the diagrams and map plots to present the route to follow. A navigation dial and a compass provides parallel guidance.

1.11 Propulsion Sonar

A propulsion sonar is placed at the receptacle in the longitudinal axis. It is capable of detecting any solid or liquid element different from that of freshwater or seawater at a sufficiently good distance to avoid any possible clashes with immersion elements. The system is connected to the on-board computer and is subject to a visual and audible alarm security system.

1.12. Detection Radar / Navigation Radar The system has a detection radar placed outside the hat, it gives the necessary azimuths for a quality detection (heavy obstacle, light, cold, hot). The navigation radar is placed on the outside of the hat, it gives the route of movement.

1.13. Weather Radars (Plate 16 - Figure 29 (6)) The weather radars are placed on the cockpit hat. They take into account the formation of clouds and their altitudes. The information is transcribed and the onboard computer provides the context of pressure or depression depending on the weather (rain, snow, storm formation, etc.). The computer then provides the graph at the appropriate weather maps and centralizes possibly, through the computer, the display on a synoptic panel.

1.14. Detection microphones

The pickups are of different types, one of the microphones ensures the awareness of the ambient atmosphere outside the cabin, the other type of microphone provides sensitization under fresh or salt water. All information is transmitted to the onboard computer. 1.15. Thermal current detector

A thermal fluid current detector is placed under the receptacle. It detects the favorable current for an advantageous navigation in the context with respect to the temperature of the different currents.

1.16. Universal converter

A universal converter allows the storage of universal data (knowledge data, universal and global technological data including the sciences of civilization and ethics). The storage of universal data is contained in an embedded complex device. It is small in size and capable of managing and communicating any data requested in any domain in any language and dialect. The apparatus is capable simultaneously of producing a visual or audible message. It is also suitable for the deaf and dumb and the PMR. The language and the decoding are established by a usual and instantaneous converter. His order is connected to the main computer and is subject to manual control. A playback screen allows playback and decoding visual and sound.

1.17. Lifeboats

Lifeboats with instant inflation are stored in a space provided for this purpose in the volume of the passenger compartment module. The canoes are two in number and are equipped with the necessary for the minimum survival (food, distress rocket, harpoon, etc.). Canoes are equipped with automatic beacons to locate their position anywhere in the world.

1.18. Life vest

Lifejackets are stored in a specific place in the passenger compartment. These vests are of mixed character: the lower part of the vest is composed of an automatic air inflation system, the upper part of the vest is composed of solid and light elements adapted to the circumstance of indefinite flotation.

1.19. Parachute (Plate 15 - Figure 26)

In an extreme and particular case, parachutes (15) allow the "fall" of the passenger compartment module in order to maintain its durability and survival. A certain number of parachutes is placed at the periphery of the passenger compartment module, in the upper part, under the protective covers provided for this purpose. When absolutely necessary, the parachutes are opened automatically by the control of the opening of the protective covers. The size of the parachutes, their shape and the materials used are adapted to the context.

1.20. Necessary for speleology and mountaineering

In the cockpit module, specific equipment for speleology and / or mountaineering are stored in the storage space provided for this purpose.

§ 2 - Survival of the species

2.1. Genetic protection

A very sophisticated preservation system relating to genetic conservation is set up at the level of the passenger compartment module. A genetic repertoire recorded doubly at the level of knowledge heritage in the database is integrated into the universal converter according to a specific section, the DNA codes being recorded specifically.

2.2. Genetic department An IT department manages each genetic department, the variety of departments is relative to each species, whether human, animal, plant, or other.

2.2.1. Human genetic department

The Department of Human Genetics is developed following a logical sequence of codings and encodings; he is able to decipher all elements and to equate all problems in order to arrive at a solution corresponding to each wish requested.

Each genetic trait is physically preserved and integrated into a compartment called "regeneration space".

2.2.2. Animal genetic department

The animal genetic department is adapted according to the same principle as that of a human nature: each animal species can be reproduced entirely according to the level of the natural disaster criterion. 2.2.3. Plant genetic department

The plant genetic department is adapted according to the same principle as the human one. The plant department includes the areas of plants, plants, trees, flowers, etc .: each species can be reproduced in almost irreversible natural disaster criteria.

2.2.4. Mineral Department

Similarly, the natural elements (fresh water, salt water) and certain types of minerals can be reproduced according to the need of the moment.

2.3. Viral and anti-viral banks

At the level of the passenger compartment module, a viral and antiviral "bank" must meet the needs of prevention and cases of extreme urgency, in a particular context. Each antidote sample responding to each type of virus or bacterial medium is adapted to meet the requirement of the moment. A functional storage space and particular storage meets this recommendation.

All samples are listed at the databank level and registered at the central computer, coupled with the viral, antiviral and bacterial and anti-bacterial management computer. The energy memory of this viral and antiviral bank is coupled in power supply with a complementary inverter battery thus ensuring a double security.

2.4. Para-pharmaceutical bank

In the passenger compartment module, a "para-pharmaceutical bank" must meet the requirements of the care of the diseases, according to the urgency and the context, according to the critical degree engaging the anti-viral field. The para-pharmaceutical bank also ensures the degree of urgency of less importance. It is able to provide all the elements necessary for a pharmaceutical preparation.

2.5. Minilab

A mini laboratory is located at the passenger compartment module on a relatively small work surface. At the volume level of the work plan, partly lower, a set of mini drawers and shelves provides storage of basic products used to develop the desired drugs.

2.6. Mini dental office At the level of the passenger compartment module, in a space of its interior volume, a set of equipment related to dental care is set up. This equipment offers the possibility of minimum care such as decay treatment and tooth picking, with the possibility of anesthetic sedatives, in cases requiring it.

2.7. Mini operating theater

A mini-operating room is set up in the passenger compartment module. It allows small surgical procedures, for example at the level of an arm or a leg, which can be treated by the means of surgery and asepsis, or even through nanosurgery.

2.8. Mini pharmacy

At the level of the passenger compartment module, a mini pharmacy is located in a storage cabinet located at height and for which a suitable layout is provided to store the stored drugs.

2.9. Blood hydrolysis checker

A blood hydrolysis checker is placed inside the passenger compartment module. It allows a relatively efficient and fast blood test without the absolute necessity of blood collection.

2.10. Pollen detector

According to the evolution of the seasons and particularly that of the natural regeneration of the flora, detectors inform of the notorious presence of pollen in an ambient environment. Sensitive filters placed at the level of the vents, aerators and specific ventilation circuits ensure an efficient ventilation at the filtration level of the particles. 2.11. Food storage

A compartment provided for storing food adapted to each conservation feature is located in a location in the passenger compartment. It allows a sufficient supply for a period of time recommended and adapted to a condition of extreme survival.

CHAPTER 9 - SECURITY - SECURITY

§ 1 - Safety of prevention

1.1. Surveillance: Radars (Plate 16 - Figure 29 (7))

Surveillance radars are placed at the shell, hat and receptacle. The radar is positioned to detect day and night movement in total darkness. It is able to detect the eventual element at a defined distance according to the needs and wishes requested. Radars are controlled by passive laser beams. The system is managed automatically in parallel with manual management.

1.2. Navigation lights

Navigation lights are automatically controlled from the passenger compartment module. In an extreme context, the navigation lights direct the beams of light to allow navigation of the passenger compartment module reliably. The optics are equipped with anti-corrosion and anti-vandal protection gates. In addition, they are made of special material to allow the sliding of the water. These navigation lights have a range sufficient to ensure vision in extreme fog.

1.3. Sound horns

The audible alarms have the possibility of being audible or not, depending on the desired programming. They are associated with a visual alarm that can also be activated automatically by synchronization. The sound frequency of the moment indicates the degree and the context of the alert to be taken into account.

1.4. Audible alarms and alerts

The audible alarm indicates according to the degree of the frequency, the level of alert to take into account and which alert is thus engaged (seismic, tsunami, radiant, chemical, etc). The buzzer is placed judiciously at the level of the module in order to emit the sound in the best conditions and spontaneously in the context of the emergency. The assembly is associated with an automatic system controlling the emergency systems to be activated in priority order. Manual control is associated with the automatic system. 1.5. Remote controls and remote controls

An ergonomic, portable housing forms the remote control. The range of this remote control is consequent to the needs and wishes requested. The box allows to control all the existing orders. Thus, all the information is transmitted or retransmitted to the remote control unit at different frequencies and adapted to each incident or information character. Different LEDs light up according to the context.

In addition, a sound system gives the information associated with a visual system. In addition, a video screen with high-performance resolutions stores and sends the video signals via the remote control to the adapted system. The assembly is transmitted and transcribed according to the decision of the technical management of the surveillance located at the cabin level to record all necessary information on a high-capacity compressed disk associated with a digital printer.

1.6. Surveillance cameras

A set of remote monitoring is set up. H comprises a group of cameras coupled to a thermal infrared system necessary for monitoring. The active system consists of a mini digital recorder including a mini integrated multiplexer. All operation and control is by frequency (wireless) adapted to the system. In addition, and in parallel security cabling is implemented to ensure continuity of operation in a defined context.

1.7. Exception markup

Exceptional markup of the passenger compartment module is realized whether it is fixed or moving. The markup of the presence of the module is done by means of inadvertent illumination system flash type high frequency and appropriate color according to the context. The devices are explosion-proof and waterproof. These devices are fixed either above or below the module, or at the outer periphery.

Markers are visible at a sufficient distance in the context of heavy fog and very low visibility. 1.8. Beacon beacons

A beacon beacon adapted to the passenger compartment module can be placed at the upper level of the module in the axis thereof or in its peripheral axis.

§ 2 - Electrical safety

2.1. Lightning rod

A trident-type lightning rod with spherical balls is placed high enough to allow the flow of a natural charge due to lightning. It is positioned upstream of the passenger compartment module as well as upstream of all sensitive equipment. The continuity of the flow circuit through this lightning rod is carried out deep underground and by means of belts and earth stakes distributed uniformly under the supporting hand and independently of the current earth ground or the computer earth ground.

2.2. Earth sockets

Earth sockets are put in place according to the needs necessary for the protection of people and equipment.

2.3. Low Voltage Grounding A low voltage grounding that meets the needs for equipotential bonding

(220V / 380V) ensures the continuity of the equipotentiality by bare or insulated copper cable, at clean and imperative distances to the correct functioning of the protections, in relative time of flow to the computer earth ground.

2.4. Computer grounding

A computer grounding adapted to the desired value is put in place at the bottom of the excavation, under the support of the hand. A respective distance between the computer grounding and all other earth connections is adapted to this potentiality. Earth connections of the same nature are interconnected with each other, except for specific and non-compatible earth connections. 2.5. Ionization detectors

Ionization detectors are conveniently located at the specific locations of the passenger compartment module.

2.6. Protection of the ionization phenomenon and Faraday's hypothesis

The passenger compartment space is protected directly by the Faraday system.

The relatively closed and tight space of the passenger compartment and its structure promotes the electrostatic protection system, etc.

2.7. Wave detectors

Wave detectors are distributed at the volume level of the passenger compartment module. The nature of the waves received is subject to sound frequencies characterizing the different waves received. A visual alarm signals the nature and degree of urgency and its influence in the context.

2.8. Wave jammer

In the case of harmful, parasitic or undesirable waves, a wave jammer acting directly on these phenomena protects the proper functioning of the original transmission and reception system. All frequencies are able to be recognized and decoded using specific devices.

2.9. Underwater horn

A horn underwater horn warns of the presence of the module in an extreme context and a sufficient distance to avoid possible collisions. The underwater probes are subjected to an amplification system against sea water containing sodium crystals. The underwater horn is capable of sending calibration-type massages calibrated on the Morse system. The variations of water temperature are automatically taken into account by the amplifier. 2.10. Automatic disconnection (plate 35 - figure 85)

In case of very serious problems and according to the context, an automatic disconnection is carried out with all the supply and evacuation circuits (electricity, telephone, computer, water-valve, waste water).

§ 3 - Mechanical safety

3.1. rack and pinion

A rack is fixed along the cylinder support so that the cockpit module can be raised or lowered. The rack is the means of relief although at limited heights in this case, but nevertheless effective and necessary, facing a possible failure and total hydraulic and electrical system. The rack is driven by two independent motors having on their axis a gear of identical diameter and teeth suitable for proper operation. The first motor acting in the lower plane and perpendicular to the axis of the passenger compartment module, the other acting in the upper plane and perpendicular to the same axis.

The motors are reversing the direction of rotation. Safety pawls maintain the passenger compartment module according to its position at a standstill and in relation to its level and that of the rack. A manual system is subject to the automatic system.

3.2. Pump

Pumps adapted to each need are installed in the passenger compartment module and ancillary elements. The pumps are able on the one hand to extract water volumes according to the wishes, on the other hand to repress the same flows, in the same contexts. The pumps will be placed judiciously according to their characteristics and their specific objectives.

All pumps have capacities suitable for prolonged and total immersion, in no way affecting their operational use. The pumps physically guarantee the desired flow rates. All pumping lines are adapted to the specific needs of the pumps themselves and to an extreme context.

3.3. Winch

A winch placed in the technical area of the passenger compartment module allows maintenance in an emergency in a flexible way to provide some elasticity of movement to the module. Different scenarios can arise, either in case of total and sudden submersion, or in a context of rapid drift and unexpected surface.

In the case of a submersion, an anchor is released and sufficient and necessary slack is synchronized via the winch. In the case of a sudden drift in surface water under serious attack, a grapple is launched by a mobile harpoon to allow temporary securing fortunes. It allows the winch to follow the physical meander movements with flexibility to avoid any shock and sudden pull on the winching cable thus avoiding irreversible damage to the passenger compartment. In the case where too great physical constraints act on the cable, automatic unstacking is done (either disconnecting the anchor, or disconnecting the grapple). The assembly is controlled automatically by the on-board computer and subject to manual control.

3.4. Emergency system for raising or lowering the passenger compartment module

A backup system for raising or lowering the passenger compartment module is made in the vertical part of the normal and automatic system. A rack with manual crank system is installed, thus ensuring the continuity of operation in the face of any failures of the automatic system.

3.5. End of race safety

End-of-travel safety is ensured at the level of each system that requires it.

The limit system is suitable for every use, be it manual, automatic, electronic, hydraulic, pneumatic, electric, ... The end of the race is a device capable of stopping net and in a very short time, almost spontaneous, any apparatus or organ in movement whatever it is and whatever is their limit state of movement.

3.6. Emergency crank The passenger compartment module and the ancillary elements have their own manual equipment to allow the opening or closing of the safety access doors (main door of the module and additional doors of the other elements). A universal hand crank is provided at the passenger compartment module to ensure the necessary emergency and safety functions in particular at the level of the rise, descent and rotation of the passenger compartment module in the case where the electrical system of the rack is no longer able to ensure its operation.

3.7. Special scale

A special ladder is set up at the 'emergency shelter - ambulatory' element in order to access the telescopic emergency evacuation module.

§ 4 - Security

4.1. Physical protection against burglary

Peripheral physical protection is implemented at the passenger compartment module and its ancillary and related elements that are part of the entire complex. The protections are mesh sufficiently narrow to prevent access to the surface and volume by a relatively low mass hand. This structure resembles the structure of a net composed of lightweight materials and resistant to shear, extreme temperatures and the most aggressive bacteria, ... This protection ensures the safety and security of people in relation to harmful facts that may occur from the outside caused by foreign physical bodies and thereby causing a number of damages.

4.2. Anti-vandal system

For the sake of safety and security, the anti-vandal system is systematically applied to all equipment requiring it; including, screw, nut, connection, specific fixings, etc.

4.3. Identification system

An identification system at the level of one or more persons to use the volumes of the passenger compartment module as well as the volumes of the ancillary elements is possibly achieved by means of an electronic chip, or even a nanobip, in order to identify the person of absolutely. Another detection system can be set up to read the fingerprint and to decode at least three fingerprints on both hands. 4.4. Thermal cameras

In the passenger compartment module and its ancillary elements, thermal cameras are judiciously placed in order to detect any movements defined by temperature differences. These cameras are highly sensitive. All information is transmitted to the computer to take into account and support the degree of alert and intervention to implement.

CHAPTER 10 - ANTI-SEISMIC SYSTEM

1. Floor ( ^" plate 40 - figure 113)

The floor level of the passenger compartment module and the ancillary elements is constituted by an anti-seismic system. The system consists of a floor resting on the bases of the peripheral structure of the receptacle. A first fixed floor in medium mesh gratings is realized. A second uniform and homogeneous floor rests on the fixed slatted floor. At the periphery and at each place where it is needed, seismic stops are put in place, which makes this same floor semi-mobile in the event of a very violent shock and in the context of opposition of various physical constraints.

On this floor, balls (or balls, depending on the context) are put in place, having to support the third floor element that is rendered anti-seismic fact. This third floor is provided at its periphery and at the places requiring it anti-seismic stops. At this floor, one or more inspection doors allow access to technical areas or tanks. Cutouts or reservations adapted in the context are planned. In order to prevent the penetration of certain particles, a peripheral lip of composite and flexible material is placed all along the perimeters requiring this operation, especially in perimetry of the mobile floor.

2. Anti-seismic structures (cylinders and specific seismic balls) ( ^" plate 40 - figures 114, 115, 116. 117. 118 and 119)

Cylinders with return springs are put in place where required, elements internal to the structure may comprise compression gases or fluids adapted to the pressure and the relief of the return spring, during the effort in the context of 'an extreme situation.

The specific balls are provided with flexible and elastic membranes on their periphery to make possible the deformation of the moment and then resume their initial position spontaneously and adapted to phenomena of a certain seismic nature.

3. Nose (Plate 10 - Figure 17)

The nose is the system on which the leg and the entire passenger compartment module rests. 4. Interface (support hand) (Plate 28 - Figure 64)

The anti-seismic system relating to the interface consists of a set.

CHAPTER 11 - CONTEXT OF VOLUMES AND SURFACE IN A MEDIUM

ANTI DEFLAGRANT

1. Wiring In any case, the wiring of the power supply, remote control, transmission, signaling, etc. is of the shielded type and corresponds to the contexts of the explosion-proof volumes and spaces.

2. Apparatus All equipment (switch, push button, remote control contact, motion detector, etc.), whether in the high current or weak currents domain, is of the type corresponding to the contexts of the anti-current surfaces and volumes. - flagrant.

3. Seals (in the general case) and special seals

Special seals and seals are able to withstand extreme compressive and mechanical stresses. They are adapted to each specific need.

4. Kitchen equipment The type of kitchen electrical equipment is of the explosion-proof type. No kitchen equipment runs on gas. The cooking gas is totally prohibited.

5. Lighting

All lighting fixtures, even decorative, as well as outdoor lighting and emergency lighting are of the explosion-proof type.

6. Normal lighting and security lighting

The lighting is evenly distributed in the passenger compartment module and in all types of additional or complementary elements of the passenger compartment module. Emergency lighting and markup are installed and implemented according to the risk zone context. 7. Optical fiber lighting

Fiber optic lighting can be put in place. A certain number of fiber optic conduits with diameters sufficiently adapted to the transport of natural light in the dark zone provide low intensity luminance in order to obtain a minimum of lumens in the extreme case of natural disaster.

During strong thunderstorms, a higher light concentration is channeled, a converter then establishes a distribution of this light energy and redistributes it through the circuits of secondary optical fibers. Flash lighting can then be noticed, because of this, the constancy of the luminous intensity is a function of the luminous period radiated by that of a flash. At this moment, the whole can be illuminated instantly and in all its parts.

CHAPTER 12 - SURFACE TREATMENTS

1. Fireproofing

Fireproofing is performed on all materials and materials that require it and imperatively. Very important resistance to fireproofing must be ensured for all elements that are very easily flammable and combustible or that emit toxic fumes through their combustion. A very strong precaution is taken into account in particular concerning very sensitive materials and materials.

2. Protective treatment of materials

Each type of material is protected against oxidation, corrosion, luminance, particular radiations, fungi of any kind, peculiar insects, etc.

In the case of "all wood" construction, special attention is paid to fungicide and insecticide treatments that must be very suitable for surface protection and in the fibers themselves (indoor / outdoor). Special high impact and ultraviolet varnishes are recommended.

3. Fire extinguishers Fire extinguishers are distributed in the passenger compartment module and its ancillary elements. Fire extinguishers are sufficient in number and capacity and adapted to each type of intervention. An automatic system can be put in place to ensure maximum safety and security in the context.

CHAPTER 13 - MAINTENANCE

1. Mini workshop

A mini-workshop located in a volume space of the passenger compartment module is installed. It includes the tools necessary for repairing or making makeshift mechanical, electrical, electronic, etc. parts requiring intervention.

2. Vacuum cleaner

An aspirator allowing the aspiration of particles at the passenger compartment module is installed. A circuit of peripheral tubes and plugs (suction ports) is distributed evenly along the perimeter of the passenger compartment module. The aspiration of the system is carried out at its base by extractors having a power adapted to this operation.

CHAPTER 14 - CONTROLS - CONTROLS - MEASURES

1. General synoptic control and control table

A general synoptic command and control table indicates all physical malfunction functions for all devices and devices, both inside and outside the passenger compartment module. All control and remote control information is perceived in parallel by a special transportable housing; it can also control through it the control of all the information on the general synoptic control panel of the passenger compartment module.

2. Level control (trim control)

The general level control ensures the stabilization of the passenger compartment assembly.

The control is ensured by visual and sound field, the control device ensures the stabilization of the module during a possible failure of the stability of the cabin on the vertical and horizontal plane.

3. Measuring devices

The specific measuring devices are placed in the passenger compartment module at the level of the ancillary elements of the module, in particular, the pressure, vacuum, altitude and all the specific devices according to each discipline and context of use. They are subject to a characteristic visual and audible alarm.

4. Navigation instruments

Basic measuring instruments, manual and magnetic, are housed in reserve in the passenger compartment module in the space provided for this purpose. This storage space can accommodate the basic navigation devices, measurement (sextant, etc.) in the event that a severe or unforeseen incidence would subtract any means of tracking.

Navigation charts (paper) or general maps are in a map slot located at a suitable storage space. These cards make it possible to give the heading or any position. They are varied in character (land, sea, sea depth, river, air, galaxy, etc.). 5. Telescope

A telescope of average power according to the desired needs is put in place at the level of the passenger compartment module. This telescope makes it possible to take stock very precisely in a difficult situation. Moreover, its observation invalidates or confirms a relatively imminent danger that may arise from the atmosphere or the space itself.

This telescope can also be used as a long view in a context of observation of physical drift of the cabin module in a critical situation.

CHAPTER 15 - MOTORIZATION - PROPULSION

1. Propulsion (propulsion) engines (Plate 35 - Figures 83 and 84)

At least one propulsion motor is installed inside the passenger compartment module. The engine allows the physical movement of the passenger compartment module on a liquid surface when the need for exception.

2. Automatic disconnection (plate 35 - figure 85)

In the event of a serious problem with the general external power supplies, or when separating the cabin module from its foot, an automatic disconnection system comes into action.

3. Transmission and coupling system relating to the drive of propulsion shafts and the activation of paddle wheels (Plate 17 - Figures 30 and 31, Plate 35 - Figures 83 and 84)

A central system allows the angular variation of the shafts to drive either the propellers or the paddle wheels.

4. Paddle wheels (Plate 17 - Figures 30 and 31) The paddle wheels and paddle wheels with "gaudille" have the specificity of being able to bend in compression transversely.

5. "Gaudille" Wheel (Plate 17 - Figures 32 and 33)

The "gaudille" consists of the structure and elements identical to those of the impeller, nevertheless, the central part is different. It is adapted to the periphery of the passenger compartment module and is maintained peripherally by a suitable support support. CHAPTER 16 - TRANSPORT

1. Trailer specific (plate 36 - figures 86 and 87)

A specific trailer is provided for the transport of the passenger compartment module. This trailer has the particularity of being equipped with anti-seismic and anti-vibration systems. positioned at the wheel support axes and the towing arm of the trailer which rests on the towing part of the vehicle performing the function of movement of the passenger compartment module.

Anti-seismic elements are positioned at the periphery of the trailer (either by anti-seismic cushions or by anti-seismic crown). An anti-seismic annex system located at the bottom of the trailer, and in the axis of the passenger compartment module, ensures the protection of the latter during transport on roads, roads or access routes difficult and chaotic.

This transport is based on the possibility of moving the module from his place of departure to his place of arrival. The module must then be separated from the transport note with the aid of a suitable hoist and associated with the transport trailer. This hoist is balanced by cylinders ensuring the stability of the maneuver (lifting and lowering the passenger compartment module). Depending on the case and the context, a transport vehicle more extensive than the possibilities that can be offered by the transport trailer of the passenger compartment module, such as a truck can be offered for transport. Depending on the volume, the surface area, the sizing and the mass of the passenger compartment module, any other means outside its transport may be considered in particular, high capacity truck (exceptional convoy), air route, rail or sea, so to guarantee a delivery in conditions of optimal satisfaction.

2. Truck (Plate 36 - Figures 86, 87 and 88)

The truck is equipped with anti-seismic systems at its wheels and its axis of traction. CHAPTER 17- COMMUNICATION

1. Emission of physical messages in critical and extreme circumstances

In the case of a very critical situation of the last degree occurring in the natural context, physical communication systems whether they are visual or sound (or mixed), must allow a minimum of communication, in particular by telegraph, by telegraph of Chappe (traditional and bright), by direct hearing (tam-tam, dialect, ...).

2. Laser message A laser beam message can be made from the passenger compartment module. A grid containing all the alphabets of the current civilization can be projected in the sky with composition and variation of words or sentences. Thus, the message may be read on a large scale by individuals outside the passenger compartment module and at relatively large distances during distress in a particular context. Similarly, a large-scale projection of a filmed or photographed event can be projected in the sky or on the water.

3. Sound system

A sound system is set up in the passenger compartment module and at the level of the various complementary or additional elements. The sound system consists of uniformly distributed loudspeakers. They must respond at an audible frequency to desired points and locations. The active material (amplifier, ...) is of exceptional quality. The wiring and the equipment are of the explosion-proof type.

4. Television

A TSC (flat screen) television is installed in the passenger compartment module volume. A wide reception program ensures the quality of audiovisual communication (film, documentary, multi-character information, etc.).

5. High fidelity

A mini-channel ensures the reception quality of radio broadcasts, CDs, cassettes, MP3s, etc. 82

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CHAPTER 18 - POPULATION ALERT PLAN

1. Automatic warning trigger system

An automatic warning triggering system is paralleled with an automatic satellite matching system associated with the GPS system and the latest advanced system (Galileo). The general central security system manages completely, with its own systems, the totality of the security whatever the degree of the nature of the phenomenon of alert. It is able to protect the cockpit as quickly as possible and thus to act on the functions of the electronic and manual controls thus ensuring physical protection functions of the passenger compartment. This alert can also, but not necessarily, be an obligation given the total independence of the module and its security systems.

The relay between its own systems and the satellite systems gives the information in real time, in particular, during a tsunami or other important natural phenomenon.

The information is then captured and received by the existing detection system at the passenger compartment. This information is stored and transcribed in order to start all the automatic or manual protection of the module, in order to channel and guarantee the prevention in a very short time relative to the security as well as the life of the concerned individuals. whatever their position at the level of the globe, and according to the correlation of the whole system.

CHAPTER 19 - SPECIAL DEVICES FOR PERSONS A

REDUCED MOBILITY (PMR)

1. Inside or Outside PMR Ride (Plate 37 - Figure 89) A removable indoor or outdoor PMR lift is recommended. Outside the module, a PMR is installed if the need arises. This PMR is characterized by a cylinder supported in part by one of the panels of the passenger compartment module. The person lift consists of either a pulley system or a chain system for lifting the person with reduced mobility to the desired height. An arm of rotation allows positioning to the axis of access to the passenger compartment module.

All these operations are operated either by manual system or by means of motorized and automatic systems (pneumatic or hydraulic cylinders, motor, etc.). In this type of context, the PMR is supported by the PMR. A translational arm provides movement outward or inward (outside or inside access PMR). A PMR chair support tray is placed at the base of the cylinder to support the load and move it.

2. Universal indoor or outdoor PMR rides (Plate 37 - Figures 90, 91 and 92)

A second PMR said principal is set up and allows the rise or fall of not only the PMR but also of anyone wanting access to the passenger compartment module. On the other hand, the PMR has the obligation to borrow this PMR. The latter is characterized by a conveyor belt system driven by chain drive sprocket wheels, however another system can be developed by toothed belt driven spline wheels. A fingernail allows easier access to the PMR at the level of the carpet then supporting their chair. A support hook for the PMR chair is driven by a link chain. This hook is tied to a return spring. Once the desired maneuver is completed, the hook then merges in the same plane as that of the carpet, so the movement can be renewed without problems. The bodyguards fold back on themselves. This universal PMR package is retractable and automatically slides into the passenger compartment module (under the floor) above the technical surface. 3. Specific access to sanitary, shower, sauna (plate 38 - figures 93 and 94)

Specific accesses other main access are access to sauna, shower and WC.

4. Washbasin (plate 38 - figures 99 and 100) In the passenger compartment module, a PMR washbasin is installed in the shower room between the sauna and the shower enclosure.

5. Double WC (plate 38 - figure 101)

The toilets are universally accessible.

6. PMR Sleeping (Plate 39 - Figures 102, 103 and 104)

The PMR coating is characterized by either an automatic system (compressor cylinder), or either mechanical and manual. It is recommended an automatic system that allows the height adjustment on the horizontal plane with double shelf to support a main mattress with water or air, or other materials ensuring a certain ease of comfort. This double shelf moves in the horizontal and transverse plane; it doubles the width of the berth according to the context and the moment of the desired operation. Thus the user having acquired more surface and a certain volume of maneuver can sit and lie more rationally at his own reflection. Similarly, if the need arises, a second-person assisted person may wear the PMK and place it horizontally under relatively more affluent conditions. As a result, the PMR transition pain is reduced as appropriate, and some maneuvers remain effective.

The vertical part is also subject to automatic control by a cylinder system (hydraulic or pneumatic). The berth folds in two or three parts if the need is desired. A cylinder in the vertical plane lifts the first part on a relatively thin system of wheels and rails. This part then forms a berth. The other cylinder placed in the longitudinal horizontal plane pushes the same part constituting the horizontal plane and gives it the desired force, for example, buttocks and leg rest / calves. Thus, one obtains, according to the context, the lying position, backed accordion, etc.

An automatic guard provides protection against tipping (falling) in all PMR positions and in all berth positions due to longitudinal protections in the horizontal and transverse direction of the plane of the berth. The cockpit or the room can then be equipped with the desired number of berths.

7. MassaRe option (Plate 39 - Figures 102 to 108)

The PMR coating makes it possible to obtain, in horizontal position or in other positions, characteristic and relatively effective massages via a set of massaging elements.

8. PMR Table and Seat (Plate 19 - Figure 38) In order to facilitate maximum meal intake with some relaxation for PMR, it is planned to reinforce easy movements in a relatively small area and volume. .

9. Central lifter (Plate 38 - Figure 95) A person lifter PMR is placed discreetly and aesthetically at the upper level of the passenger compartment module, in the lower part of the concealable canopy. What characterizes the system is the part of rotation and substationation of this set. This system has an arm mounted on a rail itself in peripheral substation of the canopy. At these ends, wheels provide rotational movements equal to 360 °. At its end (arm), a partially horizontal cylinder ensures the horizontal movement, and a partially vertical cylinder ensures the vertical movement. Both movements can be simultaneous and synchronized. At the end of the vertical arm, a plate attached to the latter is able to lift either the PMR sitting in the chair or the PMR person itself. A complementary system makes it possible to lift, supported in part lateral, the PMR vertically. Many functions are stored in the on-board computer and adapted to the PMR housing that can transport these people to act according to their wishes and to the extent of their ability.

10. Ergonomics PMR The ergonomics PMR is particularly flexible and adapted to each user. An ergonomic system for PMR is implemented in all cases. Ergonomics for PMR is present wherever it is needed, physical systems are at their disposal reach, to allow their sitting or lifting with a grip to the effort best suited to their needs.

11. Ergonomics at WC level Ergonomics at WC level is ensured by two independent bars fixed on each side of the WC. Protection against tilting to the right or left of the PMR retains it if necessary; it ensures a large protection surface. In addition to this protection, a vertical bar of its axis and transverse at its upper end, serves as a fall barrier in the transverse axis of the PMR to prevent a fall of the body falling head first at the floor.

This system is automatic to the desired command (either by infrared or by contact, etc.). The anti-fall support rises or descends and lodges in the floor of the passenger compartment module in technical space. The system is driven by a 180 ° swiveling cylinder once the physical protection of the PMR is in position.

12. Shower and Sauna (Plate 38 - Figures 94, 96 to 98)

The protection in the shower and sauna includes an ergonomic bench and a tilting chair with a ring foldable in the vertical plane and rotatable in the horizontal plane, in order to surround the PMR and give it a relatively easy position by compared to the needs of the least painful positions and the best adapted ones. At the access points or inside the shower and sauna, vertical bars are installed in order to ensure either the maintenance of the PRM on the vertical plane, or a sitting or the lifting of the PRM by itself, if this remains possible or by the accompanying person, if necessary.

13. PMR motion aid by detection and alarms

In order to facilitate the mobility of PRM, visually impaired, hearing impaired, hearing impaired and blind, a system is set up on the one hand inside the passenger compartment module, on the other hand and partially to the exterior of the passenger compartment module, at the level of the surroundings and certain routes designed for them. 14. Guidance

What characterizes the guidance of PMR is a system based on the detection and reception of any frequencies and their encoding and decoding.

15. Sport and maintenance for PMR f plate 39 - figures 109, 110, 111 and 112)

An apparatus located inside the passenger compartment module and located at a specific surface area is used for the use of physical expression by the PMR. This device allows the muscular and articular work of its lower and upper limbs. This equipment is provided with safety systems, ensuring the constant balance to prevent any fall; these systems are connected to the on-board central computer.

CHAPTER 20 - SCENARII

Scenario A: Single and totally independent cockpit module (plate 41)

In the case of natural disasters and extreme natural disasters, a number of scenarios are considered depending on the context.

A. L. Scenario in the context of an earthquake (Plate 41 - Al. Figures 120 and 121)

If we consider an earthquake of significant amplitude on the Richter scale, the module and its ancillary elements must each be able to maintain their own stability.

A.2. Scenario in case of submersion (Plate 41 - A2, Figures 122 to 125)

In the case of submersion, the passenger compartment module must be able to withstand certain types of flooding, depending on the context of the moment.

A3. Scenario in case of drift (plate 41 - A3, figures 126 to 130)

Once the module completely independent and floating on the water through the main float, it can occur a sudden storm at sea or in fresh water, which creates currents sometimes dangerous and may destabilize the passenger compartment module, making it fragile to potential shocks waves or unexpected obstacles that may occur.

A.4. Scenario in case of a fall (plate 41 - A4, figures 131 and 132)

In case of imminent fall of the passenger compartment module in a void and consequent space, for example during a drift can no longer be controlled and leading it to the limit of the waterline, whose outcome is a cascade.

AT 5. Scenario for rising lava (Plate 41 - A5, Figures 133 and 134)

In the most difficult case that can be encountered in this hypothesis, probably that of a lava flow that can not possibly be diverted. A.6. Scenario in normal times (plate 41 - A6, figures 135 to 138)

In the case where the worst has passed and where navigation has become possible to its limit, the propulsion engines are started and navigation of the module becomes effective.

A7. Avalanche Scenario and Snowfall (Plate 44 - Figure 179)

At the level of regions and sites with avalanche risks of type 5, the passenger compartment module and its ancillary elements are capable of protecting people.

Scenario B: Passenger compartment module and its ancillary elements making up the set of main element (plate 41 - B1, B2 and B3, figures 139 to 141)

The main element is the intimate passenger compartment module of its ancillary elements which are closely related to each other. Nevertheless, the hand of support remains an element in secondary appendix because it can be adapted to each nature of ground.

Scenario C: Implementation of the passenger compartment module in a tree (attachment between branches) (plate 42)

Cl. Implantation of the passenger compartment module in the shafts according to the physical possibilities corresponding to the structure of the tree or at the level of the cathode. where applicable (plate 42 - Cl, figures 142. 143. 144 and 146)

Depending on the case requiring it by extreme natural disaster context requirement, the passenger compartment module can be implanted in one or on trees. A holding device at the trunk or branches to support the passenger compartment module is put in place. At the level of the trunk itself, a mini platform provides support for the passenger compartment module and is provided with a peripheral protection adapted to the context.

At the level of the shafts, the passenger compartment module is supported by a set of systems allowing the maintenance and the constant balance of the latter in all safety and security. A system adapted to this context can then be put in place. It is a composition of a set subject to an anti-seismic and anti-vibration system. At the center of this system, anti-seismic elements are put in place. At the end of the same system, an element called 'finger' maintains the fastenings of the passenger compartment module. A longitudinal system called an arm meets the imperative requirements of operation, particularly level of basic stability search in the horizontal plane and in the vertical plane. This system is driven by hydraulic cylinders.

C.2. Implantation of the module supported by its platform maintained in a group of at least three trees (three anchor points) (plate 42 - C2, figures 142 and 143)

In the case requiring it and according to the physical possibility of implantation of the entire passenger compartment module, a platform is maintained by limited traction in its horizontal plane. This traction is achieved by means of tensioned cables. The snap bracelets are located at the level of tree trunks or branches whose spacing between the latter (or last) is known or sufficient in terms of the robustness of the support of the entire bridge and passenger compartment module (in charge and additional overhead).

Fangs at the other end of the cable are attached to the portion of the bridge to be maintained. These fangs are easy to move thanks to the structure of the peripheral edge of the bridge. Thus the possibility of attachment is variable at will, which facilitates the establishment of the platform. A safety device guardrail is put in place.

C.3. Cockpit module supported by the bridge / stem (plate 42 - C3, figure 144)

In this case, the platform suspended by cables is replaced by a platform hooked and adapted to support the entire passenger compartment module by a support arm. At the end of one of the parts of the platform, an attachment arm allows attachment to the trunk of a relatively large shaft diameter, mass and mass support. The arm supporting this platform is reinforced at its base by ribs designed to withstand mechanical stresses (moment of transport). A double-opening collar is provided at its inner peripheral part with stabilizing anchor studs guaranteeing adhesion under the best conditions (humidity, temperature difference, foam, abundant rain, sliding of resin, etc.). A manual system allows the installation and closure of this necklace. An electric motor allows the automatic adjustment of play of the collar with respect to the volume of the tree or the branch with the greatest respect and treatment in the context. This operation is carried out from the volume of the passenger compartment module by the computer through the touch probes located at the clamping collar. C4. Forest Module (Plate 42)

The passenger compartment module can be supported in the same way as the aquatic model equipped with the three guide cylinders, and described in scenario E. Under the platform, a pneumatic damper corresponding to the shape and the volume to support the passenger compartment module as well as the support of its gateway is put in place. The latter inflates in case of extreme urgency and thus a possible accidental fall or a descent recommended.

This forest module is similar to the aquatic tag module unlike its base support. Only at the base of the guide cylinders supporting the platform on which the passenger compartment module rests, anti-seismic systems are installed in continuity of the cylinders penetrating into the ground to a suitable depth.

Scenario D: Implementation of the passenger compartment module in troglodyte environment (plate 42 - Dl figure 145)

Faced with external attacks of natural disasters, it may be considered to provide a suitable solution related to the environmental environment, for example, the installation of the passenger compartment module "troglodyte" in a natural interior volume.

Scenario E: Installation of the cabin module in the aquatic environment (with multiple guide cylinders) (plate 42)

The cabin module outside the models and systems presented in the project, can also be adapted in a context of implantation in the marine environment and in the aquatic environment. The passenger compartment module has the same interior and exterior appearance, only the support system and the port of the module differs.

1. Supporting platform (plate 48 - figure 212)

The platform (1) on which the passenger compartment module (A) is guided is guided by guide handles (2) consisting of a cylindrical piece containing a set of ball bearings (3), enclosed by the cover (4). ). Scenario F: Implementation of the module in marshy zone (plate 42 - Fl. Figure 147)

A surface maintenance palm in a marsh zone is necessary to support the passenger compartment module.

Models (plates 43, 44 and 45 - figures 155 to 199).

Relations between elements based on water, forest or soil

1. Port of the passenger compartment module ( ^" plate 42 - figures 142 to 154)

The passenger compartment module is carried by a mini platform of shape that can vary and always adapted to the specific context of natural disasters phenomenon.

2. Guiding elements (plate 48 - figure 214 (6 ^* ))

The guide elements (6) are constituted by various geometric figures that can be adapted to the mechanical constraints and to the aesthetics required.

3. Support of bracket (board 48 - figure 214) A system of brackets (3) can circulate on the periphery of the cylindrical support holder (1) of brackets, a wheel (2) ensures its rotation.

4. Traction cables (Plate 48 - Figure 212)

The traction cables (19) placed longitudinally and vertically along the guide tubes (25).

5. Tensioning Guides (Plate 48 - Figure 212)

The tensioning guide (24) consists of a central pulley and two small cylinders free and rotating under the effect of friction of the cable. 6. Maneuvering Winch (Plate 48 - Figure 212)

An operating winch (18) placed and fixed on the platform (1) of the passenger compartment module

(A) allows for all maneuvering operations.

7. Float

Peripheral inflators, placed under the platform on which the cockpit module rests, allow the natural maintenance of the floating system.

8. Safety Inflators

Safety inflators placed under each part of the arms of the platform ensure the safety of the latter.

9. Security of separation of the cabin module of the platform supporting it A security system allows the separation of the passenger compartment module from the platform / bridge supporting it.

10. Lighthouses

A beacon beacon can be set up.

11. Aquatic module with single guide cylinder The single guidance system of the passenger compartment module in the aquatic environment is based on the same basic system as that of the multi-cylinder guide.

12. Water Module with Aquatic Beacon

The water beacon system is based on the same principle as that of the aquatic module with a single guide cylinder. CHAPTER 21 - PRESENTATION OF MODULES OF MODULES AND

ADDITIONAL ELEMENTS CONSTITUTING THE ENTIRE DEVICE

§ 1 - Description of model modules and its annexes

1.1. Basic models

The models (in addition to the file) are presented at boards 43, 44 and 45.

This presentation shows the anti-seismic model (s) and / or equipped with technological equipment related to the production and distribution of renewable and independent energy. Similarly, one can see in the figure 160, the anti-seismic models with or without possibility of automatic elevation in the case of flood of average or big importance, even extreme flood. These models are equipped with technological equipment for the production and supply of renewable energy (Figure 166). The passenger compartment module can also be covered by an auxiliary element called

"Cocoon" (Plate 43 - Figures 167 and 168, Plate 44 - Figures 184 to 186). The cocoon covers the module and protects it in the case where it remains in place, without being inhabited, for a relatively long period. It is a visual protection against external curiosity and against certain bad weather. Moreover, we consider one of the ancillary elements called "mouth" (plate

14) for receiving the passenger compartment module resting on the specific anti-seismic cushions (7). The annex can be provided with technical rooms (8), water tanks, technical tanks at the lower level (9).

There is also another different auxiliary item called "survival lock - ambulatory" (plate 44 - figures 181 to 183) which makes it possible to receive and evacuate individuals in great difficulty or to maintain them for a certain period of time in their home. space, thus ensuring their survival. The survival or ambulatory lock can also be equipped with a telescopic escape or emergency entry locker, depending on the context (boards 44 - Figures 183 to 185). It is also possible to complement the upper part of the mouth member, a complementary protective element called "cocoon" (plate 44 - Figures 184 to 186). Thus the ancillary elements and the passenger compartment unit joined together, allows to obtain a perfect safety and security in the context of very critical situations. 1.2. Variants (presentation of modules)

Alternatively, the passenger compartment module may be either not equipped with the anti-seismic system, or not equipped with renewable energy production and supply systems, or not equipped with both systems. In addition, it may also be not equipped with anti-flood systems for mounting the module. In addition, alternatively, the passenger compartment module can be of very different type of material (composite, wood, totally wood). The choice of each solution must be appropriate to the wishes sought and to the results expected or resulting from this same choice, in the face of the easy and complete enjoyment of the passenger compartment module or in a situation that guarantees the minimum of comfort and vital protection, and consequently , of relative enjoyment.

§2 - Choice of the shape of the passenger compartment module or habitat or nanohabitat or nanohabitat module (plate 5θ)

2.1. Definition and choice of the passenger compartment module

The definition of the module by itself is to be able to modulate an element in its surface, its volume, its forms and consequently its dimensioning. The name "module" seems to be quite suitable for one or more building elements that can be modulated and customizable. Given the name 'habitat' and its fundamental definition, it appears that the association of the two names corresponds to the name related to the context of the project, namely: passenger compartment module or habitat module. In the general context, the term 'cabin module' is used and used. The possibility of association and distribution of modules between them at the level of the general configuration resulting in a certain number of possible presentations limited and infinite at the same time (plate 50 - figures 217 to 231).

2.2. Observations and reflections

By carefully observing the nature that is very close to us, always but very often ignored and badly treated, or even almost non-existent for some, we can notice certain phenomena or activities that seem simple or complicated and vice versa. This is why the logic or the illogical of complicated things are relatively simple and simple things are relatively complicated and vice versa, and so on. In short, at the end of these observations, if they are sufficiently attentive and thoughtful, one can conclude certain hypotheses and probabilities, until the final realization, in the case of a concretization that has become realistic enough in its logic of realism and can thus lead to a concrete materialization, that is to say to the materialization of its realization which can then be a figure, a surface, a volume, etc.

From this observation and reflection flows the present project. It is based especially on the principle of the bee; this is why the choice of the cabin module shape is a relatively functional geometric figure (hexagon). We will then denote a number of examples of composition recommended and adapted to each medium, for example, the configured modules can be arranged in the form of letter, flower, face, caricature, logo, acronym, etc. This configuration can also be handled by architecturally identical upper levels (floors), but nevertheless able to receive a slightly different composition but appropriate in the context. Similarly, the structures are technologically identical to the passenger compartment module.

The passenger compartment module can be used and recommended when setting up a retirement home, a village of various kinds, etc. It can be used and adapted to a character of approval in order to reconcile the useful with the pleasant, nevertheless, its particular priority must respond to the phenomena of natural disasters.

§ 3 - Choice of layout of the passenger compartment modules and their elements: Collective or individual installation (plate 50 -figures 217 to 231, plates 43 to 45 -figures 155 to 199).

The passenger compartment module can be installed either individually or accompanied by ancillary elements. This implantation can be multiple at will on different sites whatever their surface to cover. The choice remains totally free and is chosen according to the context and the nature of the sites.

3.1. Nature of the sites

The nature of the sites is variable. It can be of a country nature (hilly or flat), near rivers, rivers, ponds, seas, deserts, etc. This implantation can also be carried out at the plot level in the countryside in a village, in a city, etc. This implantation can be carried out on all types of ground and according to the nature of its constitution (deformation of important ground, pebbles, sand, relatively rough ground). The implementation remains of universal type and is universal. 3.2. Advantage and choice of the passenger compartment module (and their ancillary elements')

In addition to the systems described at the document level, the passenger compartment module, in addition to the technologies and the safeties with regard to the protection of natural disasters characterizing it, offers notorious additional advantages; that is to say, the tiny area of land occupation, the installation of the passenger compartment module on a small surface, satellite implantation and independent of the module in all possible locations around the globe and universally.

3.3. Land occupation area (low coefficient)

The surface occupation of the ground is a very small area because the support of the passenger compartment module is of small size and does not exceed, moreover, a relatively large depth. The structure in infra-structure is not heavy in physical constraint as well as their dimensioning compared to traditional constructions. As a result, the terrain can accept a number of modules in one or more relatively small or greatly reduced areas.

3.4. Installation of the passenger compartment module

In addition to the benefits of the passenger compartment module, a particular advantage is that of its implementation. The installation at the reception of the module is done on his foot and legs (according to description above). The advantage is that this leg or foot can be left in place mfinately, taking care to cover with special shutters this element left in place to protect the entire support of the passenger compartment module. Thus, the passenger compartment module can be transported at will on any place and site, and this, at the level of the whole planet. It will then be sufficient to program and choose the mode of transport of the passenger compartment module (specific trailer, air, river, road and other possible means to ensure its routing) as well as its delivery at its final or provisional location. Only the foot or the leg remains indefmiment and with desire on the primary site, the exchanges of implantation of module in the world can be thus carried out while keeping the own support of module.

3.5. Universal implementation

Universal "satellite" implantation anywhere in the world can be achieved. The layout of the passenger compartment module must be possible at the level of the globe and almost in all the places and contexts that may arise. He can be implanted in the middle of the driest and warmest to the middle of the most humid and cold, and thus undergo extreme temperature changes, depending on the type of model.

§ 4 - Themes of the passenger compartment module (decorative and practical aspect)

The cabin module presents in terms of its interior and exterior aspects of decoration signs adapted to the wishes of each request. There are different models: the standard model, the style model, the country model, the marine model, the mountain model, the modern model, the futuristic model, the model can be exotic, ...

4.1. Style template

The style model is adapted to the desired artistic needs in quality and decoration with a particularly neat finish. These colors tend towards honey and cherry varnish is predominant. Breasts have one of the first places. In addition, a white color is also retained at the level of the decoration in the bottom volume of the passenger compartment

4.2. Marine model

The marine model in terms of its interior volume is composed of composite materials including wood of very good quality, stained and varnished in the best finishes and according to the desired applications. The brass and brass are dominant in the decoration (door handles, pendulum, etc.)

4.3. Country style

The rural model merges with the surrounding environment of nature, fields and flora. Its interior is decorated with a heavier decorative influence in general appearance. Forged steels have an appropriate place for aesthetics and functionality.

4.4. Mountain model

The mountain model presents in interior volume, at the level of its decoration and bottom of sensitivity, the mountain atmosphere: light or dark tinted fir wood, decorative and functional elements in slate panels (kitchen furniture, etc). The copper chimney and the kitchen utensils accompany the mountain character. 4.5. Classic model

The classic model is the most common model in terms of decoration. The decorative elements to be made and made to measure. The elements are fixed on the floor or in any other part of the structure (the background colors at the level of the decoration are adapted to the selected furniture).

4.6. Modern model

The modern model is the model that can receive the modern elements of the moment. Decorative colors can be bright and uniform or bright and composed. The materials used are in a general case, laminated panels (with the exception of specific orders for the general decoration of the interior volume).

4.7. Futuristic model

The futuristic model gives free rein to the imagination a little more pronounced, a general composition of decoration can be proposed and subjected to an appropriate reflection. Specific materials accentuating this decoration such as stainless steel, aluminum, etc. are integrated into the volume of the passenger compartment module.

4.8. Decoration of exterior volumes The exterior volumes of all these models of the passenger compartment module can be optionally decorated according to their natural context and their location.

NOTE :

Why is the comparison and description of the passenger compartment module and its ancillary elements carried out according to that of the human body?

The description of the passenger compartment module is made according to that of the human body because physically a certain number of elements (in external configuration) are similar in a distant way but in concomitance with those of the human body. Indeed, certain elements provide positioning functions in a specific volume of the descriptive geometry in parallel with the natural and physical constraints that the human body can undergo. CHAPTER 22 - ALL WOOD CABINET MODULE

In parallel with the composite passenger compartment module and the other ancillary elements mentioned above, it is necessary to consider a passenger compartment module whose configuration is identical but whose mechanical, bacteriological, atmospheric, etc. constraints are inferior to the desired technological characteristics. Nevertheless, the technological effort sought will be the closest and the most advantageous in order to respond as closely as possible to the demands, despite the material used which is wood (plate 51 - figure 232, plate 52 - figure 233, plate 53 - figure 235 ).

The entire structure constituting the passenger compartment module and the ancillary elements are made of wood. The anti-seismic elements are made of a different type of material although, nevertheless, they can also be made of wood (multiple wood and different in terms of mechanical resistance). The assemblies are made by pegging with previously drilled holes. A large part of the elements is glued and pegged.

The whole wood cabin module consists of different elements.

1. Crutches (Plate 54 - Figure 236 (D, Figure 237 ~)

At the level of the assembly and helping the rigidity of the structure, crutches are put in place. They are made of wood, pegged and glued. They are placed at orifices or reservations intended to receive them. These parts are placed at the periphery of the passenger compartment module, in the upper part and in the lower part of the latter.

2. Anti-seismic system (plate 55 - figures 240 to 242) Only the anti-seismic system differs in this passenger compartment module and in the passenger compartment volume itself. An anti-seismic system at the bottom of the volume of the passenger compartment module is identical to that located at the top of the volume of the passenger compartment module. The system consists of wooden elements assembled together, glued and pegged. It surrounds the perimeter of the passenger compartment module at the top and bottom. Inside these anti-seismic elements, other elements of the same nature are complementary, they are elements of compression and decompression at the vertical plane which allow a certain oscillation on the horizontal plane. They recover most of the seismic stresses that can occur during an earthquake that can reach a significant amplitude. The second type of complementary anti-seismic element ensuring compression and decompression on the vertical plane allows this function. A third complementary anti-seismic element allows the maintenance between them, independent elements to the passenger compartment module, thus responding to the seismic waves by keeping the solidarity between each element in deformation movement. As a result, the oscillation of the module makes it possible to simultaneously receive the composition of the three seismic results at the vertical plane, the horizontal plane, the vertical and horizontal plane at the same time.

3. Framing (Plate 54 - Figure 236) The framing consists of assembled wooden elements, glued and pegged to each other.

The frame can also be mono-block (cut and cut in the mass of wood material). It consists of vertical elements and horizontal elements. The assembly of these elements together constitute the framework of the wood cabin module.

4. Wood panels (Plate 54 - Figures 236 and 238, Plate 56 - Figure 247)

Wood panels consist of assembled, glued and pegged elements to form the appropriate interfaces to the requested wishes. The structure of these panels is very different from that of other structures of different material. Wooden boards at certain levels of their surfaces require the removal of a mini-surface. This ablation is performed using a punch of shape and size adapted to the wishes requested. The wood falls recovered during the ablation of these minisurfaces and corresponding to the operation performed by the punch are assembled, glued and pegged according to the desired thickness, thus constituting the spacers required for the spacing of interior panels between them at the level of each panel.

5. The pipes (plate 57 - figures 248 to 251)

The pipes are distributed in the panels of the passenger compartment module so as to provide maximum efficiency.

6. The spacers (Plate 54 - Figure 237) The spacers allow the modularity of the panels and the choice of interior dimensions, the number of compartments, the number of cells, etc. 7. The cells (plate 54 - figures 236 and 238: plate 56 - figure 241)

The cells thus produced allow the diffusion of air volumes between them. The circulation of the air is thus equitably distributed and distributed inside the panels themselves. This operation should result in a uniform distribution inside the volume of the passenger compartment module. This distribution is done under the influence of static or kinematic heating.

8. Heating (boards 56 and 57)

Complementary to the heating mode relative to another model (see above), a heating block with thermal and acoustic insulation is installed at the periphery along the inner perimeter furthest from the center of the module. cockpit (last inner peripheral panel). The heating consists on the one hand by rotating heating resistors of reinforcement, on the other hand, by turbines with ventilation effecting the mixing of the air and its insufflation on the parts of the heating tubes placed in the axes of the cells ensuring a rise in pressure of hot air and its redistribution at best through the wood panels constituting walls and partitions of both the passenger compartment module.

The tabular duct heating circuit is traversed by a suitable fluid and sent by pressurized pumps to a certain temperature that can be variable and regulated on demand. The pumps are subject to the computer system, their regulation can be taken into account at each panel independently or panel group simultaneously. The circuits are arranged in a vertical, parallel or staggered line according to the technical needs sought.

Thus the cabin module or its ancillary elements can be heated to the minimum or the maximum of its possibilities. Similarly, the distribution of heating can be made at the side panels of the upper and lower parts or oblique side panels (false ceiling level / floor level), or all three parts simultaneously. Hoses provided for this purpose, allow the passage and continuity of heating circuits at the level of anti-seismic systems, maintaining a quality of operation even in a case of significant seismic stress. At each main circuit, at the tank outlet, specific heaters are installed (Gch). 9. Air conditioning (boards 56 and 57)

Complementary to the air conditioning mode for another model

(see above), an air-conditioning unit with thermal and acoustic insulation is installed on the periphery along the inner perimeter farthest from the center of the passenger compartment module (last inner peripheral panel). The air conditioning is constituted on the one hand by a rotating system with reinforcement cooling, on the other hand by ventilation turbines mixing the air and blowing it on the parts of the air conditioning tubes placed in the axes of the cells. ensuring a rise in pressure of the fresh air and its redistribution at best through the wood panels constituting the walls and partitions of both the passenger compartment module.

The tubular duct air conditioning circuit is traversed by a suitable fluid and sent by pressurized pumps to a certain temperature that can be variable and regulated on demand. The pumps are subject to the computer system, their regulation can be taken into account at each panel independently or panel group simultaneously. The circuits are arranged in a vertical, parallel or staggered line according to the technical needs sought.

Thus the passenger compartment module or its ancillary elements can be conditioned according to the minimum or the maximum of its possibilities. Similarly, the distribution of costs can be made at the side panels of the upper and lower parts or oblique side panels (false ceiling level / floor level), or three parts simultaneously. Hoses provided for this purpose, allow the passage and continuity of air conditioning circuits at the level of anti-seismic systems, maintaining a quality of operation even in a case of significant seismic stress. At each main circuit, at the outlet of the tank, specific coolers are installed (GcI).

10. Climaréfrigération (hyper-cold) (boards 56 and 57).

Complementary to the cooling mode relative to another model (see above), a climate-cooling unit with thermal and acoustic insulation is installed at the periphery along the inner perimeter furthest from the center of the passenger compartment module. (last inner peripheral panel). Climaréfrigération consists on the one hand by a rotating system with reinforcement hyper-cooling, on the other hand, by ventilation turbines mixing the air and its insufflation on the parts of the air conditioning tubes placed in the axes. cells ensuring a rise in hyper-cold air pressure and its redistribution at best through the wood panels constituting the walls and partitions of the passenger compartment module.

The tubular duct cooling circuit is traversed by a suitable fluid and sent by pressurized pumps to a certain temperature which can be variable and regulated on demand. The pumps are subject to the computer system, their regulation can be taken into account at each panel independently or panel group simultaneously. The circuits are arranged in a vertical, parallel or staggered line according to the technical needs sought. Thus, the passenger compartment module or its ancillary elements can be cooled in air according to the minimum or the maximum of its possibilities. Similarly, the distribution of hyper-cold can be made at the side panels of the upper and lower parts or oblique side panels (false ceiling level / false floor level), or three parts simultaneously. Hoses provided for this purpose, allow the passage and continuity of air conditioning systems at the level of anti-seismic systems, maintaining a quality of operation even in a case of significant seismic stress. At the level of each main circuit, at the outlet of the tank, specific hyper-coolers are installed (Ghf).

11. Independent blocks of heating, air-conditioning and air-cooling (plate 56 - figure 244 ^* ) Blocks distributed on the outer periphery of the last interior panel of the passenger compartment module, at the level of the wood panels, allow a complementarity of heating, air conditioning and climaréfrigération .

12. Door and double door (plate 52 - figure 233 (ï), figure 234) In the context of the passenger compartment module, in the present context of the all-wood module, the installation of a door and a double door.

13. The door (plate 52 - figures 233 and 234)

The main wooden door is fixed along the frame provided for this purpose. This door is provided with a single glazing on a certain surface, and with double glazing thick adapted to withstand relatively severe external temperatures. 14. The double door

The double door has the same characteristics as the door described above. It has the particularity of forming a single door capable of isolating as much as possible harmful constraints coming from outside (noise, heat, cold, rain, etc.). It also ensures the opening of one of the doors outward, the other inward. The door is indeformable and rot-proof.

Special notes

With the exception of these appropriate features, the entire cabin interior and all its ancillary elements is similar and identical in terms of its equipment to those described above and for basic passenger compartment module and its annexes, according to the definition corresponding upstream of the file, during the technical description. The interior layout is identical to the basic module (boards 53 and 58).

FEATURES

A particularity is to retain as an option and alternatively if necessary. This is to make possible almost spontaneous penetration in the volume of the passenger compartment of all the equipment located outside the module and in its upper part (weather radar, parabola, wind, etc.). In this case, an automatic system will allow the ascent and descent of the assembly. Protective panels located in the upper structure of the passenger compartment module then make it possible to protect these elements underlined by an absolute seal when they are closed.

1. Configuration

If the configuration of the cabin module supports may be different from each other, the security system, detection, etc. is identical to that set up at the cabin and in a general case.

2. Range of manufacture One or more manufacturing ranges, whether in specific and varied manufacturing

(various mounting, explosive forming, stamping, welding, brazing, gluing, machining, etc.) is subject to special technical attention.

3. Assembly and disassembly ranges

At the level of the construction of each set, whether individual or collective, a mounting range is established to proceed to a mounting of each piece to be a set or subassembly of elements, very methodically. Similarly, a disassembly range is established in the same rigor and conditions as those of the mounting range but in the opposite direction.

4. Assembly line An assembly line is set up according to the assembly or assembly groups constituting the passenger compartment module. Each specificity is controlled, assembled according to a rigorously established order of assembly that is mechanical, electrical, electronic, structural. At the end of the assembly line, each element is subject to particular logistics and destinations appropriate to each type of endings.

Claims

1. Foot (plate 8 - figure 12; plate 9 - figures 13, 14 and 15)

The operating system of the passenger compartment module foot is:

The foot is made up of (1) a physical support made of lightweight material that can withstand all temperatures and physical and atmospheric constraints subjected to the module. To meet the desired wishes and needs, the foot is moved vertically (elevational movements) in order to allow the raising or lowering of the entire supported passenger compartment, as well as horizontally (rotational movements), in order to be able to perform at least one rotation equal to 360° on the horizontal plane, with compensatory stabilizer. The foot has an automatic system allowing physical movements. It is subject to a manual system. In contrast, physical phenomena can conversely be appropriated to the shell of the passenger compartment or to the foot itself. The foot also consists of extendable cylinder bodies (1), comprising ball bearings and spacer rings, upper and lower supports (2) of the module, two toothed wheels (3) to enable rotation of the module. The foot returns to the descent position by the passenger compartment module's own mass, automatically and at a reduced speed.

A physical end-of-stroke safety system is placed at the ends of the foot (maximum rise and fall). A visual and audible system signals movement to ensure personal safety. A double cylinder system exerts vertical pressure, one upwards, the other downwards. They are physically controlled by a powerful hydraulic or pneumatic pump adapted to their operation, taking into account loads and overloads. The actuators are independent of each other, but can be synchronized if necessary in the context. The hydraulic tanks are independent of each other to ensure the emergency function. They are placed in the technical area, in the receptacle on the floor of the passenger compartment module.

2.Heel (plate 10 - figure 16 (2))

The operating system of the passenger compartment module heel is:

The heel (2) is made of lightweight material capable of withstanding all temperatures and physical, chemical and atmospheric stresses, subjected to this assembly and assembly elements. The heel is the intermediate support between the foot and the receptacle receiving the entire cabin. The heel is made of composite materials and absorbs the majority of possible vibrations that may occur in a natural context, at variable frequencies up to a certain scale (in this case, Richter scale) or following a substantial shock wave (horizontal shock wave). The heel is fixed to the foot (or to the base in certain cases) using a tightening and fixing system adapted to this element. In the event that a serious event occurs (wave and/or submersion), the heel will instantly separate from the foot. This separation would be carried out in parallel by a complementary system of retractable claws and jaws on the support or using a specific cylinder (X).

3. Leg (plate 10 - figure 16 (3 ^* ))

The operating system of the passenger compartment module leg is:

The leg receives the foot; it is made up of coolers and heaters. The leg has geometric shapes that can be different and variable in size. It is made up of an assembly enclosing tungsten balls or other materials whose diameter is sufficient to stabilize the rise and fall of the foot. In its axis and at the base, a “diamond” ball is adapted to the system to be supported. The balls are enclosed in the leg, they also ensure 360° rotation. The function of the balls is to extremely reduce the coefficient of friction between the walls (leg on foot) and to absorb vibrations in the case of seismic phenomena. To ensure easy movements, a beveled tip at the end of the foot is made and a tungsten ball is implanted at its base, thus ensuring all the desired movements. The balls must take or return to their position and location, in the operating position or in the rest position. The leg is made of double wall, and a cooling or heating system ensures its effectiveness in extreme contexts.

4. Ambulatory airlock/anti-seismic emergency airlock (plate 11 - figure 18; plate 12 - figures 19 and 20)

In addition to the descriptions in point 1.9. of chapter ¹ , the entire operating system of the ambulatory airlock/anti-seismic emergency airlock (plate 25 - figures 57 and 58) is:

An anti-seismic system is set up at the level of the ambulatory survival airlock (the same system can be configured at the level of the 'mouth' element instead of the compact element defined in the project. In this case, the elements considered would then be found in a horizontal plane and not in a vertical plane in order to allow vertical sinusoidal movements of the 'mouth' element assembly).

A high temperature seal is pressed on the part of the ring piece (2) which presses a high temperature seal (3), which is compressed by the ring piece (4). A ring (5) compresses the high temperature seal (6). A ring (7) compresses the high temperature seal (8), which is also compressed by the ring (9). A ring (10) compresses the high temperature seal (11). A ring (12) compresses the high temperature seal (13). A high temperature composite bellows (14) ensures the sealing and movement of the assembly. A cylinder body (15 and 16) is fixed on the rings (5, 7 and 8). The cylinder bodies (15 and 16) move longitudinally in their axis of translation. A jack (17, 18, 19 and 20) provided with a compression ball (21 and 22) allows seismic compressions in the horizontal plane and on a sensitive inclination axis between - 15 to - 20° and + 15 and + 20°. High temperature flexibles (23) allow the continuity of the high pressure and high temperature circuits in the hollow conduits (24) of the structure. The structures (25 and 26) are thus connected to each other and accept seismic deformations. Lower grooves (27) and upper grooves (28) make it possible to guide the compression head of the cylinder (17, 18, 19 and 20).

5. Extendable telescopic airlock (plate 13 — figures 21, 22 and 23)

The operating system of the extendable telescopic airlock of the ambulatory airlock is:

An extendable telescopic airlock is placed on the upper part of the ambulatory survival airlock. The airlock made up of anti-seismic elements (1) allows emergency and ultimate evacuation through the double cover (2) which opens either outwards or inwards. A system of jacks (3) makes it possible to mount the PMR using its chair which is supported by the plate (4). A system of jacks (5) allows the elevation of the telescopic airlock (6) thus lifting the elevation elements constituting it. A stop (7) limits the elevation of the cylinder (5). An automatic extendable ladder (8) allows exit from or access to the airlock. This ladder unfolds automatically using a winch placed at the base of the survival hatch. It is driven at its upper part by a specific attachment at the base of the cover (2). This ladder is made of composite material which makes it both flexible and rigid. Once the airlock is lowered, the ladder rolls up simultaneously. The walls of the airlock are equipped with heating and cooling elements.

6. Mouth “Element B” (plate 14 - figure 25)

The functioning system of the mouth is:

The mouth (1) is the system which allows the entire passenger compartment to be “swallowed”. It is made of material to meet extreme physical, atmospheric and chemical needs. The mouth is provided in the upper part with a concealable part constituting a diaphragm which ensures the physical protection of the passenger compartment module. This set is perfectly waterproof against runoff and water, even under a certain pressure. The structure of the mouth is made up of double walls capable of ensuring either the heating of the whole or its cooling. The mouth receives in its upper part, a shield (2) made up of waterproof panels.

7. Protective shield (plate 14 - figure 25)

The operating system of the protective shield is: The protective shield (2) protects the passenger compartment module and is fixed at several points of the mouth, in elevation. An arm system allows the deployment of the protection assembly on itself which is moved automatically at the level of the upper part of the mouth and over its entire surface. The materials constituting the shield are composite materials resistant to extreme temperatures and chemical and biological agents as well as certain radiation. Just like the other materials used, they have very sustained mechanical resistance (traction, flexion, compression). Each blade is fixed to one another by a suitable elastomer or composite material allowing the entire rotational movement, thus closing the shield 360° horizontally. A safety locking clip is then engaged for locking. The arm is moved by a motor on which is located its shaft, a toothed wheel whose rotation ensures the circular path on a rack. A special cable doubles the system to ensure additional security in the event of an extreme emergency.

The sealing of the shield is ensured by lower lips and by upper lips placed along the periphery of the mouth, in the upper part and puts pressure on the brushes thus pinching the latter by hydrostatic pressure. The shield is opened by automatic unlocking of the nipple which engages the opposite phenomenon to closing. The system is managed by the on-board computer, associated with manual control. The whole thing is subject to a sound and light signal. Brooms are capable of withstanding maximum stresses in extreme degrees of natural phenomena and context. A particular and sustained attention is also paid to the level of sound quality in general atmospheric constraints (sound absorption of direct shocks and filtered shock waves). A high frequency key is mobile and associated with the portable box in order to remotely close or open the shield depending on the context. An emergency ladder placed (6) at the level of the mouth, vertically, ensures evacuation or emergency access in the event of technical failure of a system.

It may also be recommended or associated with another type of shield whose results obtained are the same as those of the aforementioned shield, only the mode of operation and its technical architecture differ. This shield (2) is made up of six tilting panels meeting in the center of the mouth to form a circle. A mechanical system allows the elevation of each panel which, once reached the vertical position, is stored via a jack system (3) in the appropriate parts of the mouth. The shield can optionally be covered with solar panels (4). The outer peripheral solar panels (5) form a circle at the level of the shield; they are retractable and are housed inside the mouth when the closing command is activated by the central computer. The structure of the protection panels is identical to that of the solar panels of the passenger compartment module.

8. Horizontal turbine wind turbine (plate 16 — figures 27 to 29)

The entire operating system of the horizontal wind turbine is:

The entire wind turbine is made up of a system of blades (1) and turbines associated with a heating system (2) adapted to the context and structure of the wind turbine. The heating is stirred by the turbine, thus increasing the number of revolutions/minute; as a result, it increases the energy flow of the product to be consumed or stored. This establishes a closed circuit between the different energy production systems, ensuring the recharging of the energy stores and the permanent circuit of the fuel cell. The wind turbine is made up of an envelope (3) made of translucent and solid material so as to ensure the rigidity of this assembly, thus allowing the passage of artificial or natural light through the cap into the habitable space. The adjustable blades (4) ensure rotational stability and are tiltable by cycle of 3 blades: one blade being at 70° or depending, the second at 90° or depending, the third at - 70° or depending. The outward end of the blades ends in a convex shell (5) constituting a hollow half-sphere to allow air to circulate. The latter is mounted on a jack and can act in a horizontal plane or in an inclined plane depending on the desired rotation relative to its axis of inclination. It can also be completely fixed on the horizontal plane.

9. Paddle wheel ( ^" plate 17 - figures 30 and 31)

S The entire operating system of the impeller is:

Paddle wheels can be attached to the sides of the passenger compartment module, in opposition. They enable the module to be propelled on water. The wheels are made of light and rigid material. The horizontal blades (1) of the paddle wheel have an angular inclination necessary for the best mixing efficiency relative to propulsion. The blades are automatically adjustable 0 and allow braking of the module as well as emergency reverse navigation, or simple reverse navigation by inverse orientation of the propulsion angles of the blades. In the axis of the wheel, a generator system (2) makes it possible to produce energy which is distributed or stored.

10. Doors (plate 18 - figures 34 to 37) 5

In addition to the descriptions in point 1.19. of chapter ¹ , the entire operating system of the door (plate 18 - figures 34 to 37) is:

When the compressor is placed at the door (1) and supplies air to the double tubular circuit (2), the air enters the compression chamber of the liner (3), 0 which pushes the piston head (4 ), which moves the axis (5). The piston head (4) compresses the spring (6) which crushes to its limit state of compression on the cover (7) at the bottom of the liner (3). The axis (5) while moving compresses the piston head (8) which in turn compresses the spring (9) which moves the shoe (10), which moves the liner (11), which pushes the pad (12) , which compresses the periphery made of composite and elastomeric material (13), which crushes in the groove 5 (14), which thus ensures sealing at high pressures.

Once the compression air has been released through the double tubular circuit (2), the reverse movement to closing takes place. The opening of the pressure relief of the automatic door closing or opening system is done by a contactor (15). Manual opening is done using the handle (16). A high security window (17) (temperature and pressure) 0 allows interior and exterior vision at the door.

11. Cocoon anti-seismic panels (plate 21 — figure 40) In addition to the descriptions in point 2 of chapter 3, the entire operating system of the anti-seismic panels (plate 23 - figure 45) is:

The cocoon panels are held by composite rings (1) on which compression bellows (2) and traction and compression cylinders (3) rest. The cylinders are fixed by specific rivets or screws (4). These screws or rivets are held at the end of the panels by the interlocking part (5). The panels are fitted with specific anti-seismic glazing (6). The heating, air conditioning and extreme cooling system is housed in the reservation (7) which also contains the compressors at the base of the panels.

12. Anti-seismic jib foot (plate 23 - figures 43 and 44)

In addition to the descriptions of point 2 of chapter 3, the entire operating system of the anti-seismic jib base (plate 23 - figures 43 and 44) is:

The anti-seismic bracket part (1) encloses and supports the system of anti-vibration panel supports of the cocoon. Balls (2) support the part (3) on which compression cylinders (4) fixed on a shelf (5) are placed. The upper part of the compression cylinder (4) supports the cover (6) on which the outer jacket (7) and the inner jacket (8) rest. Cylinders (9) fixed on rings (10) are placed on a part

(11) ensuring the necessary movements. Cylinders (12) are fixed on a spacer (13). These cylinders (12) rest on the outer jacket (7). A waterproof cover (14) is fixed by screws (15) and compresses the seal (16). The rotation of the stem is done via the groove (17) whose screw (18) ensures the adjustment of the rotation clearance and which is blocked by the handle screw (19) penetrating the groove (17).

13. Anti-seismic jib arm (plate 23 - figure 47)

In addition to the descriptions in point 2 of chapter 3, the entire operating system of the end of the anti-seismic jib arm (plate 23 - figure 47) is:

A jib arm supports at its end the entire anti-seismic support of the cocoon panels. The end of the jib arm supports and compensates for the seismic stresses of all the cocoon panels.

14. Head of the anti-seismic jib arm (plate 23 - figure 47) In addition to the descriptions in point 2 of chapter 3, the entire operating system of the head of the anti-seismic jib arm (plate 23 - figure 47) is:

The head of the jib arm consists of an outer jacket (1) in which there are cylinders (2) which are fixed on rings (3) which ensure a rotational movement. These rings (3) are fixed on an inner sleeve (4) and adjusted at intervals by a spacer (5). A ball ring (6) allows rotational movement in the event of compression by the part (7) which supports the cylinder support (8), as well as the cylinders (9). A ring (10) on which jacks (11) are fixed ensures the rotational movement. The ring (10) is fixed on the inner liner (4). The cylinders (9) support the cover (12) which is held by the compression cover (13) which compresses the spring (14). The assembly is held by a threaded rod (15), a washer (16), a nut (17), a counter nut (18), a safety pin (19). A cap (20) and a waterproof cover (21) ensure the watertightness of this system. The outer jacket (1) retains the assembly which is held by the specific self-drilling threaded rod (22).

15. Anti-seismic gallows box ( ^“ plate 23 – figure 46)

In addition to the descriptions in point 2 of chapter 3, the entire operating system of the anti-seismic jib box (plate 23 - figure 46) is:

A jib arm box comprises two parts (1) allowing the tightening of the cover (2) thus ensuring the joining of the two parts of the box. Threaded elements (3) penetrate the stem arm and serve as a stop for the cylinder (4). A cylinder (4) moves in translation and allows movements in the event of an earthquake; it serves as a stop. On the cylinder (4), rings (5) fitted with jacks (6) ensure movement in translation and rotation.

16. Anti-seismic panel rail support (plate 22 - figure 41)

In addition to the descriptions in point 7 of Chapter 3, the entire operating system of the anti-seismic panel rail support (plate 22 - figure 41) is:

A crosspiece (1) supports a set of cocoon rails and panels. The cocoon panels allow the protection of the passenger compartment module (A) or other additional protection element of the module. A set of screws (2), washers and nuts (3) holds the support in place cylindrical (4) containing the ball or ball (5) supporting the compression spring (6), enclosed by the cylindrical element (7) on which rests the sole (8) of the rail (9). A rack (10) is fixed on the sole (8) of the rail (9).

Adjustable mini-nipples (11) prevent too much play in the wheel (12) supported by an axle (13) on which a drive pinion (14) driving the wheel (12) is fixed. This drive pinion (14) is moved by the toothed wheel (15) and driven by the motor (16), housed in the reservation space (17) of the panel. The entire part allowing the rotation of the panel wheels comprises fixed threaded cylindrical parts (18) and movable cylindrical parts (19). At the ends of the cylindrical parts (19), cylinders (20) are placed in order to absorb possible mini-shocks. Inside this entire part, balls (21) ensure easy rotation of the panel. A set of motorized nipples (22) allows the wheel (11) to be placed on the siding route by the mini-jack (23).

17. Exchanger (plate 25 — figures 53 to 56 ^* )

In addition to the descriptions of point 3 of chapter 4, the entire operating system of the exchanger (plate 25 - figures 53 to 56) is:

The exchanger (1) conveys a gas, a fluid, etc. It ensures the continuity of the circuit (2) diverted by the injectors (3). The injectors constitute a distribution group deflected when an obstacle (4) presents itself (penetration obstacle).

18. High pressure particular conduit

In addition to the descriptions of point 4 of chapter 4, the entire operating system of the particular high pressure conduit (plate 26 - figures 59 and 60; plate 27 - figures 61, 62 and 63) is: Special high pressure conduits (2 ) convey fluids, gases or multiple or unitary conduits whose transport support is a hollow conduit (1) of the structure itself. The hollow conduits (1) can be of square, rectangular, cylindrical, hexagonal or other shape. The hexagonal conduit seems best suited for the circulation of fluids. A physical composition and a mathematical equation make it possible to best establish the positioning of the particular high pressure conduits (2), in the hollow conduits (1) of the structure.

19. Power supply and general distribution circuit (plate 26 - figures 59 and 60; plate 27 - figures 61, 62 and 63)

In addition to the descriptions of point 4 of chapter 4, the entire operating system of the power supply and general distribution circuit (plate 26 - figures 59 and 60; plate 27 - figures 61, 62 and 63) is:

The general hyper-hot or hyper-cold supply and distribution circuit is made from the main tank (1) of the type of product and circuit to be supplied. Main pumps (2) send the desired liquid or gas into a transition tank (3) which arrives in a tank (4) and an emergency tank (5), in parallel with the tank (4). A “by-pass” system authorizes or not the passage of fluid or gas or other, depending on the need for continued operation of gases or others, through high temperature pipes. A pump (7) ensures the flow of fluids towards the main distribution manifold (8). This main feeder (8), via the pump (9), supplies the secondary distribution feeder (10) under pressure. The secondary feeder (10) then supplies the desired number of circuits under pressure, housed in the walls of the structure (11), and conveys, at the end of the cycle, the fluids and/or gases to the vacuum tank (12). ) so that they are recycled and redistributed to the main tank (1) of the circuit concerned. Concerning the circulation of pressurized air, compressors are installed at the head of the distribution circuit as required. At the head of a composite supply circuit, the distribution is done following the multiple interior conduits, nested inside each other while maintaining sufficient space for the transport of their own fluids or gases, placed in the walls hollows of the structure; for example, in the following case, a circuit head supplies specific hyper-cooling or hyper-heating needs with gas, liquid, etc., namely:

• water (1)

• oil (2) • gas (3)

• oxygen (4)

• nitrogen (5)

• hydrogen (6)

• helium (7) • air 'one' under pressure (8)

• 'two' air under pressure (safety reserve) (9)

The physical composition can be reversed or recomposed mathematically in order to obtain the desired needs (hyper-cold, hyper-hot, half, etc.). A chemical equation is established in order to meet these same needs and to guarantee or further accentuate protection against chemical, bacteriological agents, exterior or interior to the habitable module and its annexes.

20. Specific lighting (plate 29 - figures 66 and 67)

In addition to the descriptions in point 13 of chapter 4, the entire operating system for lighting (plate 29 — figures 66 and 67) is:

A luminaire body (1) has a central cylinder (2) positioned on mini bearings (3) allowing it to rotate. This rotation is divisible according to 3 to 6 rotation possibilities. The deflector (4) reflects the luminance. On the central cylindrical axis (2) are fixed source supports (5) carrying sources of different types (6). These sources (6) are of different colors in order to obtain a linear harlequin color. These sources are capable of flashing. A source (7) gives constant and uniform brightness. It is supported by a mini-arm (8) fixed on the central cylindrical axis (2). The luminance body has six identical longitudinal compartments. On the cylindrical axis (2) is fixed a toothed wheel (9) which is blocked by a pin (10). A toothed wheel (11) driven by a motor (12) fixed on a support element (13) gives the rotational movement to the central cylindrical axis (2).

21. Heating - air conditioning - air conditioning (see § 2 of chapter 7) (plate 31 - figures 69 to 72)

The entire operating system of the general system and the equipment (Plate 31 — figures 69 to 72) is:

The system is held in place by a structure (1) moved by a set of cylinders (2). A false ceiling (3) allows adjustment of the volume to be treated because this false ceiling goes up or down. Groups of rolled air heaters (4) are placed only on the periphery of the heating surface. A multiple, grouped device group

(5) is contained in the support (6). The support is actuated vertically by a jack (7), which allows the equipment support to be raised or lowered. This jack is fixed to the structure of the movable false ceiling. A false ceiling grid (8) is placed over the entire heating surface. Slats (9) constitute a large part of the false ceiling grid, they allow the hot laminated air to be distributed. A motor (10) drives the belt (11) which drives the heaters (rotating heaters) (5). The power supply contacts are made at the end of the resistor supports (12) which supply energy to the pure resistance (13).

The entire operating system of the tubular circuit (plate 31 — figures 69 to 72) is:

At the level of this system in substance, a group of linear or sinusoidal circuits ensures the circulation of hot water (14), cold water (15), hot air (16), cold air (17), super air. cold (18). The set of hot, cold or hyper-cold volumes is mixed by groups of devices (4 and 5). The hot air/cold air pipes come from the compressors (20), located in the technical area. This air is distributed under pressure.

The entire operating system of the corner hoses (plate 31 — figures 69 to 72) is:

At the level of the structures (1 and 3), in substation in false ceiling and at the necessary angles, flexibles (19) are put in place to allow this structure (1 and 3) to move.

22. Structure (plate 25 — figures 52 and 53)

In addition to the descriptions in point 2.8. of chapter 7, the entire operating system of the structures is:

The structures of the passenger compartment module as well as the ancillary structures are self-protected against extreme temperatures by a heating system internal to the structure (hyper-hot) as well as by a cooling system (hyper-cold) (plate 25 - figures 52 to 56 ). This set of structures includes high pressure walls as well as conduits and a number of connection exchangers.

23. Chimney (see § 3 of chapter 7) (plate 19 - figure 38; plate 33 - figures 74 to

78}

The entire operating system of the chimney (plate 19 - figure 38; plate 33 - figures 74 to 78) is: The chimney consists of the exhaust duct including:

• physical protection (1)

• ceramic protection (2)

• the exhaust of gases from the generator (3)

• high temperature composite protection (4) • fresh air intake/external suction (outside to inside) (5)

• composite protection (6)

• extraction (inside to outside) (7)

• the passage of various cables (electrical, BT, IT, etc.) (8)

• thermal insulation (9) • ceramic protection (10)

• natural smoke evacuation (wooden chimney) (11)

• the extendable chimney flue (high temperature composite materials) (12).

The entire operating system of the upper connection base (plate 33 - figures 74 and 75; plate 34 - figures 79 and 80) is:

At the level of the upper connection (in the hat), a group of extractors and fans is put in place. They consist of the generator duct extractor (3) which ensures additional safety extraction. A fan allows the supply of fresh air from the outside to the inside through the duct (5). An extractor for rapid evacuation of fumes from the heating body (11) is located on the cap.

The whole operation system of the lower connection base

(plate 33 - figures 74 and 75; plate 34 - figures 81 and 82) is:

At the level of the lower connections (in the raised floor), evacuation connections are made. A specific hose is connected to the exhaust of the generator (3). Pipes are connected to the conduit (5) and are equipped with a fan in order to bring in outside air (fresh air). Tubes are fixed on the conduit (7) to extract the stale air.

24. Anti-seismic floor (plate 40 - figure 113")

In addition to the descriptions of point 1 of chapter 10, the entire operating system of the anti-seismic floor (plate 40 - figure 113) is: An anti-seismic floor is made up of plates (1) resting on balls

(2). The plates (1) are equipped at their end and over their entire perimeter with anti-seismic jacks (3) allowing the translation of the movement. The plates are supported by a set of gratings (4), themselves supported by a peripheral part (5). The seismic movement assembly is limited by the structure of the sleeping supports (6).

25. Anti-seismic structures (plate 40 - figures 114 to 119)

In addition to the descriptions of point 2 of chapter 10, the entire operating system of the anti-seismic jack (plate 40 - figures 114 to 119) is:

The cylinder (1) is actuated in a horizontal plane by the spring (2) which is compressed by the part (3) under the influence of the ball (4), itself supported by the part (4a). This assembly can move transversely under compressive constraints from right to left and vice versa, via the part (5) compensating for the clearance necessary for the proper functioning of this assembly. The guide (6) allows movement, and is threaded on its periphery to allow tightening and immobilization of the assembly by a nut (7) and a washer (8) on the supported part and on the supporting part ( 9).

O-ring seals (10) ensure the sealing of compression fluids or gases. Return springs (11) allow the assembly to return to the initial place. A double ball (12) reduces the friction force. The fluid or gas (13) makes it possible to physically assist the entire compression and relieves the spring (2).

In addition to the descriptions in point 2 of chapter 10, the entire operating system of the anti-seismic stop (plate 40 - figure 119) is:

This assembly is strictly identical to the operation of the anti-seismic jack, however, one of its ends differs. The entire cylinder is fixed on the part (1) which is itself fixed on the fixing support (2) and receives the part of the part (3) which is screwed onto the part (1). The assembly is immobilized by the washer (4), the nut (5) and the counter nut (6). In addition to the descriptions in point 2 of chapter 10, the entire operating system of the anti-seismic membrane ball (plate 40 - figure 117) is:

The fixed support (1) allows the composite membrane (2) to be held in place by rivets (3). This membrane maintains the support (4) of the ball or ball allowing the movements necessary for the rotation and translation of the ball or ball (5).

In addition to the descriptions in point 2 of chapter 10, the entire operating system of the anti-seismic cushion (plate 40 - figures 114 to 116) is:

The anti-seismic support (1) almost makes it possible to keep a complete assembly moving in all possible directions via the anti-seismic jacks (2) and the force compensation and clearance balancing balls (3). This anti-seismic support is called a cushion.

26. The support hand (plate 28 - figure 64) In addition to the descriptions of point 5 of chapter 4 and point 4 of chapter 10, the entire operating system of the anti-seismic support hand (plate 28 - figure 64) is:

• high water resistance composite mattress, in which there is a fluid (1)

• waterproof composite sheet (2) • lead sheet (3)

• waterproof composite sheet (4)

• seismic wave compensating balls or balls with installation and holding net, elasticity difficult to extend (5)

• seismic wave compensating balls or balls with installation and holding net, elasticity difficult to extend (6)

• high temperature composite plate (7)

• double-sided ceramic with “mosaic” composition (double-sided ceramic mat treated and mounted “mosaic” style on the specific deformable net) (8)

• high temperature composite plate (9) • sand (10)

• high temperature small mesh composite mesh (11)

• high temperature anti-seismic balls (12)

• fine sand (13) • river stones (14)

• reinforced earth on clay (15)

• drainage (16)

• natural subsoil terrain (17) • an interface system adapted to extreme temperatures and chemical, atmospheric, bacteriological and other attacks (18).

27. Nose (see point 3 of chapter IQt (plate 10 - figure 17 ^" )

The entire operating system of the anti-seismic nose (plate 10 - figure 17) is:

The nose is the system on which the leg and the entire cabin module rests. What characterizes its operation is the set of specific elements composing it. It comprises an outer jacket (1) on which rest anti-seismic balls (2) on which rest an inner jacket (3), on which rest anti-seismic balls (4), on which rests a composite plate (5) , on which rests a cushion (6) composed of a set of cylinders in the horizontal and vertical planes. The cushion (6) supports a composite plate (7) which supports a set of balls (8), which support a composite seat (9). A composite insulator (10) covers the entire exterior part of the outer jacket (1). An expansion bellows (11) ensures the sealing of the system. Under the lower part of the jacket (1) a shock and vibration absorber (12) is fixed. Inside this absorber (12) is enclosed a composite sphere (13) allowing amplification of the deformation movement of the absorber and damping of seismic shocks. The composite sphere (13) compresses the space (14) containing a compression liquid or gas.

28. Blood Hydrolysis Checker

The entire operating system of the blood hydrolysis checker is: A blood hydrolysis checker is placed inside the passenger compartment module. It allows relatively efficient and rapid blood analysis without the absolute necessity of blood sampling. The analysis is done by the molecular reactivity giving the flow of the blood volume and thus detecting the value of the blood resistivity by difference in potentials in relation to the volume and mass of the person, and whose density conveyed at the level of this operation makes it possible to obtain the result of the analysis.

A device has been developed for this purpose, calibrating precise and specific settings at high definition. It determines in particular the molecular level of static electricity, passive and reactive electricity contained in the blood. An audible and visual alarm makes it possible to report an abnormal value in this analysis.

29. Specific combinations

The use of specific suits is: These suits are suitable for protection from extreme heat and extreme cold. In addition to these protections, the suit can prevent the need for depressurization in the extreme context of necessity. In addition, a suit made of air bags is ready for use. Mini-oxygen bottles are adapted to the operation of this suit which automatically inflates in the event of a fall. Through the suit, it is possible to breathe the volume of air contained in it through specific tips placed at face height.

30. Beacon lighthouse

The beacon light is: A beacon light adapted to the passenger compartment module can be installed at the upper level of the module in its axis or in its peripheral axis. Likewise, a beacon light can be installed at the level of the telescopic emergency evacuation airlock. The beacon light is suitable for this type of module element. In certain contexts, particularly highly critical natural disasters, lighthouses offer an advantage for navigation and for locating a survival point.

31. Ionization detector

The ionization detector is:

Ionization detectors are judiciously placed at specific locations in the passenger compartment module. The detectors inform visually and audibly of the presence of induction currents, etc. The audible and visual warnings come into action when the ionization frequency is found to be above the acceptable threshold for electrical disturbances or 000482

122

electrostatics in relation to physiological disturbances that can interfere with the human body.

32. Automatic disconnection (plate 35 — figure 85)

The automatic disconnection system is:

In the event of very serious problems and depending on the context, an automatic disconnection is carried out with all supply and evacuation circuits (electricity, telephone, IT, sewage water, waste water). The circuits are automatically closed by a specific system to avoid any electrical contact, thus avoiding short circuits. Specific systems are also provided on the waste water and sluice water networks, thus automatically cutting off the water inlet or waste water evacuation.

33. Motorization - propulsion (plate 35 - figures 83 and 84)

The operation of the motorization and propulsion system is:

1. Propulsion engines (propulsion) (plate 35 - figures 83 and $4)

At least one propulsion motor is installed inside the passenger compartment module. The motor allows the physical movement of the passenger compartment module on a liquid surface in exceptional cases. The motor can also be coupled to a second motor of the same type. Holes in the passenger compartment receptacle allow the passage of two drive shafts, parallel to the propulsion force to be provided, this being equal and identical at the level of each drive shaft.

Specific safety buffers ensure watertightness as well as high pressures (atmospheric and hydraulic when submerged). The motors are easy and quick to install in terms of assembly and disassembly. Their energy supply has the possibility of mixing via a specific fueling system (either by fuel or by electrical energy, etc.). The engine(s) are placed under the passenger compartment module, under the floor in the technical area. An automatic system associated with a manual system manages the control and synchronization of the movements of the propulsion shafts.

2. Automatic disconnection (plate 35 - figure 85J In the event of a serious problem with the general external power supplies, or when the passenger compartment module is separated from its base, an automatic disconnection system comes into action. This system is also implemented at the specific power supply level (electricity, telephone, IT, sewage water, waste water

3. Transmission and coupling system relating to the driving of the propulsion motor shafts and the activation of the paddle wheels (plate 35 - figures 83 and 84) A central system allows the angular variation of the shafts which must drive either the propellers, or paddle wheels. Given the difference in length relative to the position of each of the two types of specific character, the length of the shaft can be either reduced or extended by an internal sliding system between the different tubes. The coupling of each organ can then be done and give complete satisfaction in terms of their functioning. The variation angles will be equal to the operating requirement.

4. Paddle wheels (plate 17 - figures 30 and 31)

Paddle wheels and “gaudille” paddle wheels have the specificity of being able to bend transversely in compression. The paddle wheel is made up of peripheral hoops (3) to which flexible and waterproof composite bellows-shaped elements (4) are fixed. In the center of the bellows there are eccentric teeth (1) to allow the elements constituting the wheel to be folded. In the center of the wheel, there is an axis (6) allowing the coupling of the shafts of the propulsion motor(s); in this case, depending on the wish, we can use either the engine propulsion shafts, or these same shafts to allow the operation of the paddle wheels. At the center of this wheel, the parts supporting the hydraulic system constitute a set of cylinders (7) allowing the folding or deployment of the hoops which constitute part of the structure of the paddle wheels. The cylinders acting on a specific axis at the end of the wheel allow the transverse movement of the structure at the end and are thus brought towards the outside or towards the inside of the wheel, which then tightens the tooth system composites, allows contact with water and thus ensures the movement of the passenger compartment module via the rotation of the wheels. The mass of all of these wheels is particularly light.

5. “Gaudille” wheel (plate 17 — figures 32 and 33)

The “gaudille” is made up of the structure and elements identical to those of the paddle wheel, however, the central part is different. It is adapted to the periphery of the passenger compartment module and is held peripherally by an appropriate holding support.

The drive system is produced using a geared down transmission box which allows a pinion (1) of a given diameter, the rotational movements applied to this gaudille wheel. One or more intermediate motors located in the technical space of the habitable module ensure the supply of electrical energy. A second motor ensures complementary operation. One or more transmission shafts ensure translation between the motor(s) and the speed reducer.

The working principle and configuration of the outer ends and their components are the same as those of the paddle wheels. The gaudille can then physically propel itself.

34. Specific trailer (plate 36 - figures 86 and 87 ^* )

In addition to the descriptions in point 1 of chapter 16, the entire operating system of the specific trailer (plate 36 - figures 86 and 87) is:

The specific trailer is equipped with anti-seismic systems on its wheels and its traction axis. Specific equipment is provided on the trailer in order to unload or load the module.

35. Truck (plate 36 - figure 88)

The entire truck operating system (plate 36 - figure 88) is:

The truck is equipped with anti-seismic systems on its wheels and its traction axle. Specific equipment is provided on the truck in order to unload or load the module. Likewise, the truck platform is anti-seismic.

36. Indoor or outdoor PRM lift ( ^“ board 37 – figure 89)

In addition to the descriptions in point 1 of chapter 19, the entire operating system of the indoor or outdoor PMR lift (plate 37 - figure 89) is:

Specific supports (1) are placed on one of the walls of the passenger compartment module (A). The specific support supports the entire PRM lift system. The specific supports (1) support the parts (2) held by a cylindrical screw (3) which receives at its base a safety pin (4). The part (5) supports the part on which the part (6) which drives the toothed wheel (7) is fixed. A vertical cylindrical axis (8) allows the parts (6) to be connected together. At each end of the vertical axis (8) is fixed a set of washers, nuts, lock nuts, safety pins (9,10,11, and 12). The gear (7) is fixed on the body of the outer liner (13). Motors (14 and 15) fixed on the vertical cylindrical axis (8) drive the toothed wheels (16) in order to rotate the entire system on the horizontal plane.

A vertical cylinder penetrating the inner liner (18) of the outer cylindrical liner (13) allows the PMR plate (19) to be raised or lowered. The inner cylindrical sleeve (18) raises or lowers the arm support (20) of the PMR chair tray (19) in the vertical plane. A cylindrical arm (21) allows translation movements. A cylinder body (22) fixed on the part (23) allows this operation. A PMR chair wheel brake stopper (24) is positioned on the PMR chair plate (19).

37. Universal indoor or outdoor PRM lift (plate 37 - figures 90 to 92)

In addition to the descriptions in point 2 of chapter 19, the entire operating system of the universal indoor or outdoor PMR lift (plate 37 — figures 90 to 92) is:

The universal PMR lift assembly is housed in the passenger compartment module, under the floor, in the technical area. When the universal PMR lift is in the loaded state, a cylinder (1) pushes the entire system towards the outside of the passenger compartment module which slides on the side parts (2). A jack (3) moves longitudinally and enters the passenger compartment module under the floor, in the technical area. The cylinder (3) stops when the system support roller (4) reaches the intercession of the two parts comprising the motorized elements. Outside the access, at the base of the carpet, a nail (5) is placed and allows a PRM chair access to the carpet (6). Guardrails (7 and 8) deploy automatically.

A pinion wheel (9) is fixed on an axle (10) which is held by an axle (11). The sprocket wheel (9) drives the chain (12) which drives the sprocket (13), which drives the sprocket (14). The toothed wheel (13) is fixed on an axle (15) which is supported by an axle (16). The toothed wheel (14) is fixed on an axle (17) which is supported by an axle (18). A toothed wheel (19) is fixed on the axle (9).

A drive chain (20) drives a gear (21) which is placed on the axle (15). The drive chain (20) drives a toothed wheel (22) which is placed on the axle (17). The toothed wheels drive the cylinders (22, 24 and 25) which drive the treadmill (6) which is relieved in stress by the cylindrical rollers (26). Chain tensioners (27) ensure that chain play is taken up. A hook (28) allows the PMR chair to be supported and attaches to the axle of the wheels of the PMR chair. A return spring (29) allows the hook to be embedded at the end of its stroke in the groove (30). The hook (30) then passes under the carpet (6) which reaches the nail (5). the cycle can then start again.

In the opposite case of ascent, the hook (28) can be turned in the opposite direction to the horizontal plane. Thus a PRM chair can be hung at the level of the axis of its wheel supports to carry out the descent. The motors (14 and 15) then reverse their direction of rotation and the PMR chair descends.

The general drive is driven by a motor (31), fixed on the cylinder support (19).

38. Specific access to the toilet, shower, sauna (plate 38 - figures 93 and 94)

The access system to the sanitary, shower and sauna for PMR is:

The specific accesses other than the main access are the accesses to the sauna, the shower and the WC. Access to the full shower and full sauna allows PRMs to access with their own chair using a tilting stop located in the lower part of the shower or sauna cabin and mechanically controlled by a pull tab. It can be controlled automatically by decoding frequency at the PMR bracelet or at the chair level. Thus the armchair designed universally for indoors and outdoors allows relatively easy access. A delay of several minutes allows access to the spaces concerned. An optical contact allows the opening of the shower which is then managed by an automatic system. The latter regulates the temperature of the water and automatically cuts off its flow if the temperature is too high or vice versa. At the same time, a presser (compressed hose) immediately stops the flow when switching to 'exit shower' mode, another presser activates the 'automatic drying' blower for the PMR and their chair.

39. Washbasin for disabled people (plate 38 - figures 99 and 100)

The operating system of the sink for PMR is:

At the passenger compartment level, a PMR sink is installed in the bathroom between the sauna and the shower cabin. This sink is made up of a recessed basin (1) in an element supporting it in lightweight composite material that is resistant and flexible to shocks.

(possible fall of a PMR on the sink), or in material according to the requested wishes. This element is decorative and camouflages pipes, siphons, hoses, etc. Decorative and occasional lighting (2) to reinforce normal lighting is placed under the basin in a reservation (3) provided for this purpose. This lighting device is subject to all applicable and applied safety measures, according to standards and in the broadest sense. Side guides (4) allow the entire sink to slide. This assembly is moved by a cylinder (5) located in the axis of the sink, in the rear plane and installed at its base at the level of the technical volume of the floor. During operation, the cylinder acts according to demand in the up position or in the down position. If the PMR wishes to go to the WC and use it, the sink then rises following a manual or automatic order. The lighting device comes into operation from this moment. At the end of this operation, the WC returns to the initial position, thus the sink assembly can also return to its previous position. This system and this configuration of the whole make it possible to keep relatively easy volumes in terms of the evolution of PMRs, thus ensuring additional security and safety.

40. Double WC (plate 38 - figure 101)

The use of WCs by PRMs is:

The WC (1) is universally accessible. A bellows system (2) allows the device to be mounted in order to provide the desired ease for PRMs. Water supplies are provided by flexible hoses (3). The evacuation of waste water is also carried out by flexible hoses (4) of diameter allowing this function. The toilet is supported by a pre-cut slab fitting into part of the floor. A cylinder (6) activates either the raising or lowering of the toilet enveloped at its base by a flexible composite bellows (2). Thus the WC position is achieved at the desired height, either automatically by an infrared system attached to the PMR, or by a system attached to the PMR chair.

41. PMR bedding (plate 39 - figures 102 to 104)

In addition to the descriptions of point 6 of chapter 19, the entire operating system of the PMR bed (plate 39 - figures 102 to 104) is: A cylinder (1) acts in translation on the axis (2) which acts on the part (3) which pushes the axis

(4) which moves obliquely upwards bringing back the part (5) and which pivots on its axis (6). An axis (7) allows the joining or uncoupling of all the elements depending on the choice made. A connecting part (8) is used or not depending on the needs. In all the case, an assembly pressure (9 and 10) allows the continuity of the movement connections according to the operating choice chosen. The jack (11) acts on the axis (12) which gives movement to the part (13) which acts on the axis (14) which lowers the part (15) supported by the axis (16) which raises and acts on the axis (17). A connecting part (8) is used or not depending on the needs.

In all cases, an assembly pressure (9 and 10) allows the continuity of the movement connections according to the operating choice chosen. A jack (18) fixed on an axis (19) acts on the part (20) fixed on an axis (21) which gives movement to the part (22) fixed on the part (23) and whose axis (24 ) remains free. In all cases, a connection pressure (8) is used or not depending on the needs.

In all cases, assembly pressure (9 and 10) allows continuity of movements following the operating choice chosen.

A jack (25) fixed on the axis (26) pushes the part (27) which pushes the part (28) fixed on the axis (29) of the part (30) which is fixed on the shaft (31) . The shaft (31) is free. A connecting part (8) is used or not depending on the needs. In all cases, assembly pressure (9 and 10) allows continuity of movements following the operating choice chosen. A jack (33) acts on the axis (34) which tilts the part (35) which acts on the axis (36) which acts on the part (37) which tilts the part (22) as much as possible. The cylinders (38 and 42) act either independently, to tilt all the elements (5, 15, 22, 30) as much as possible at the same time; either, together. The cylinder (38) acts on the axis (39) which pushes the part (40) which acts on the axis (41) and which lifts all of the sleeping elements (5, 15, 22, 30). The cylinder (42) acts on the axis (43) which pushes the part (44) which acts on the axis (34) which pushes the part (35) and which lifts all the sleeping elements (5, 15 , 22, 30). A head rest (45) is removable by lateral pressures (45 and 47). This sleeping assembly slides like a drawer and is supported by the support element (48). This assembly is supported by transverse supports (49 and 50). A support jack (41) placed under all of these elements and in the longitudinal plane allows the transverse rotation function at desired angles, thus facilitating easier access to the PMR during a major intervention, and relieving it. at best physical pain in his movements.

42. Massage option (plate 39 - figures 102 to 108)

The entire PMR massage operating system (plate 39 - figures 102 to 108) is: The PMR, in addition to the possibilities offered by the PMR bed, can obtain, when in a horizontal position or in other positions, characteristic and relatively effective massages via a set of massaging elements. This massage assembly is enclosed in the casings (52, 53, 54, 56 and 56*). The casing (26) encloses the same operating system with the difference that it is not longitudinal but cylindrical. The massage housings (52, 53, 54, 56 and 56*) include the cylinder support elements (57, 58, 59 and 60) which receive the drive cylinders (61, 62 63 and 64) whose one end of each cylinder is provided with a toothed wheel (65, 66, 67 and 68), driven by the motors and held by a tightening assembly of washer, nut, lock nut, safety pin (69, 70, 71 and 72).

On the drive cylinders (61, 62, 63 and 64), a specific groove (73, 74, 75, 76, 77 and 78) is made. The grooves receive a set of massage belts (79, 80, 81, 82, 83 and 84) on which are fixed half-spherical supports (85) enclosing a massage ball (86) free of all movements. Each side of the periphery of the belts is perforated and provided with eyelets (87) to receive mini-nipples (88) fixed to the drive cylinders (61, 62, 63 and 64). The nipples enter the eyelets of the strap and are attached by crimping (mini-nipple/eyelet).

The toothed wheels (65, 66, 67 and 68) are driven by motors (89, 90, 91 and 92) which rotate the drive cylinders (61, 62, 63 and 64) which drive the belts of massages (79, 80, 81, 82, 83 and 84) and which give movement to the massaging ball (86) which rubs under the specific lower covering (93) and which provides the massage movement to the PMR.

43. Table and seats for disabled people (plate 19 - figure 38^

The entire operating system of the table and seats for PMR is:

In order to make it as easy as possible for people with reduced mobility to eat meals accompanied by a certain amount of relaxation, it is planned to reinforce easy movements in a surface area and volume that can be relatively small. This is why, for the sake of reconstituting a greater surface area and volume in space, while considering a relatively small volume, the evolution of the PMR remains comfortable. What characterizes the present system is the establishment of a central table in a central axis having two shelves on its sides in the horizontal plane. The shelves consist of support per side (a fixed shelf and a folding shelf on the fixed shelf). The folding tablet can also be made mobile (possibility of removing it completely manually). The folding shelf allows you to obtain a greater surface area of the useful plan and to double it or more, depending on the wish and possibility. The table (l), using the translation support, independently allows the table itself as well as the chairs (2) themselves to obtain a low position, a normal position, a snack position, and possibly a shelf position (higher position than the snack position). The folded table, in the shelves themselves folded towards the inside of the axis of the passenger compartment, can then descend automatically and fit into the floor (4) provided for this purpose. This makes it possible for PRMs or their chairs to pass over the table.

The chairs are based on the system that characterizes it and which remains the system identical to the operation and intermediate positions of the table, with the exception of the shelf position which is not desired in the context but can be achieved individually, if the need or desire is emphasized. The chairs have a ring at their seat designed for lifting the chair independently of the automatic system. Furthermore, in an automatic system and if you do not want the chair to rise with the other chairs (set of chairs), simply lift the ring located on the seat slightly and turn it slightly on one or the other position. This operation then directly disconnects the automatic raising and lowering system of the furniture concerned.

What characterizes the system in its context is the automatic function as well as the appropriate furniture and their position which can be adapted as much as possible for the comfort of PRMs. The system is pneumatic, hydraulic or manual. Its function is to allow the elements constituting the furniture in question to be raised or lowered either collectively, individually, or completely independently. This is why you can set up a single chair, for example, and in the desired position. The same goes for the table. It is then possible to lower the table, and only keep the chairs in the desired position during a meeting, for example. A peripheral assembly in the axis of the seats (chairs) moved by a cylinder (5) raises the whole or part of the assembly according to wishes. A hook-shaped system at the end of the chair support and the table support, in the lower part, ensures the physical grip of these elements. They can be separated from the system by lifting and rotating the elements. The hydraulic system then rises alone given the separation and does not involve any element constituting the type of furniture.

44. Central patient lift (plate 38 - figure 95)

In addition to the descriptions in point 9 of chapter 19, the entire operating system of the central PRM lift (plate 38 - figure 95) is:

A support rail (1) supports a PMR system. On a cylinder (2) are fixed splined wheels (3 and 4). On this cylinder, transverse axes (5 and 6) are positioned. They allow the cylinder (2) to move longitudinally by the cylinder body (7) surrounding it. A cylinder (8) moves vertically in the supported part (9). At the lower end of the cylinder (8), a support part (10) makes it possible to support and slide a cylindrical arm (11) which supports at its end a support part (12) which allows the cylinder to be raised or lowered (13) on which is fixed an axis (14) supporting the PMR plate (15). A safety brake (16) holds the PRM chair in place. The PMR plate (15) is foldable and folds at the level of the axis (14). It is held by a clip (17) which fits by force onto the cylinder (13). A specific strap support (18) is fixed at the end of the cylinder (11).

A strap (19) allows the lifting of the PMR in substance, either in a vertical position or in a horizontal position. Once the operation is completed, the system is folded and is held, in the upper part, discreetly at the level of the canopy.

45. Shower and sauna (plate 38 - figures 93 and 94)

In addition to the descriptions of point 12 of chapter 19, the entire hygiene and toilet operating system of the PMR (plate 38 - figures 93 and 94) is:

A set for the toilet of PRMs consists of a foot trigger (1) allowing the opening or closing of the water. A composite conduit on which is a bulb (2) allows the PMR to open the water in a standing and immobile position by hand pressure. A conduit on which a bulb (3) is located at its end ensures a standing position for the PMR but with a certain mobility. A water closing or opening device (4) is placed on the conduit between the shower head (5), located in the ceiling of the cabin, and the thermostat (6) and the mixer (7). Behind the mixer is the shower shut-off valve (8). The device (4) placed on the conduit comprises a body (9) made up of two parts and held at its center by a specific threaded part (10) which includes a seal (11). A cylindrical inner sleeve (12) encloses the return spring (13) bringing back or pushing (depending on opening or closing) the stuffing box which rests on its axis (15). A screw with a hollow and cylindrical grid (16) on which is fixed in its center an axis (17), surrounded by a mini-return spring (18) which acts in the opposite direction and cuts the water supply circuit supplying the shower head (5), located in the cabin ceiling. The operating procedure is identical with the operation of the hand bulb (2 and 3).

In addition to the descriptions in point 12 of chapter 19, the entire operating system of the seat and sauna (plate 38 - figures 96 to 98) for PMR is:

A folding seat consists of a plate arm (1) resting on a support (2), the axis (3) of which allows the assembly to be folded 90°. On the table arm (1) there is a vertical axis (4) on which rests a cylindrical seat plate (5) which has a rotational movement on the horizontal plane at 360°. The vertical seat support axis (5) has at its end base, a pin (6) allowing the seat plate (5) to be held in place. On the cylinder (7), an axis (8) is fixed. On the axis (8), arms (9) allow the PMR to be maintained on the horizontal plane. The arms (9) have the possibility of free rotation of 90° on the vertical plane. In the hollow part of the arms (9), cylindrical parts for extending the arms

(11) slide manually inside the handles (12) to ensure the stability of the PMR and thus avoid, when seated, falling forward. A locking ring (13) allows the arm extension parts (11) to be held together. A head rest (10) is fixed on the cylindrical tube (7). In order to keep maximum space in the volume, the entire seat folds vertically and horizontally to 90°.

46. Assistance in moving PRMs by detection and alarm

The entire travel assistance system for PRMs is:

In order to facilitate the movement of PRMs, the visually impaired, the hearing impaired, the hearing impaired and the blind, a system is set up on the one hand inside the passenger compartment module, on the other hand and partially inside outside the passenger compartment module, in the surrounding areas and on certain routes designed for them.

These operating systems are of the PRM detection, alert and guidance type. The different types that characterize them are motion detection, infrared, heat. These types of detectors are associated with an alarm or alert. The alert is then given by an alarm group or an independent alarm concerning an event of necessity, particularly zone control.

The different contacts define the zones, in particular by contact with heat, light signal, noise, olfactory zones and also correspond to different scents released automatically depending on the context of the alarm and the zones to be protected.

47. Guidance

PMR guidance is a system based on the detection and reception of any frequencies and their encoding and decoding. An electronic box gives the route to follow to the blind PMR by encoded beeps, by sequences adapted to each type of approach and initiative, for example, a touch at the sensory level corresponds to a straight line, a different sensory touch corresponds to a turn, a sensory and sequential tap corresponds to an obstacle, etc., thus the detection of a sidewalk, a hill, a descent, a staircase, etc. can be encoded, deciphered and used by the

Blind and hard of hearing disabled people.

48. Sport and maintenance for PMR (plate 39 - figures 109 to 112)

In addition to the descriptions of point 15 of chapter 19, the entire operating system of the equipment for sport and maintenance of PMR (plate 39 - figures 109 to 112) is:

This PMR set is further characterized by its constitution. An outer liner element (1) is composed of its cylinder. The outer jacket (1) is hollow and encloses over its entire height a compression spring (2). On the upper part of the outer jacket (1), a cover (3) serves as a stopper for the compression spring (2). Under the lower part of the outer jacket (10), a cover (6) serves as a stopper for the compression spring (6).

At the base of the outer jacket (1), height adjustment is possible via specific hollow spacers (4 and 5). The specific spacers (4 and 5) are placed under the outer jacket (1) and vertically support the weight of the assembly in context. These spacers are placed by lifting the outer jacket (1) to accommodate them underneath. In the center of the outer jacket (1), a guide cylinder (7) is placed on the periphery on which the compression spring (2) is located. The outer jacket (1) is supported by part supports (8) which allow sliding of the vertical outer jacket. The parts (8) are held by cylindrical parts (9) also allowing the cylindrical parts (9) to slide and be blocked by a specific hand screw (10). An independent external cylinder (11) is fixed in its upper part by a specific screw (12) which is placed at the level of the ceiling. A specific screw (13) is located on the lower part of the outer cylinder (11) and is pressed against the floor.

On the upper part of the outer jacket (1), the part (14) can be free in all rotational movements or be blocked by a specific screw (15). On this part (14), traction support arms (16) are adjustable in translation angle (angle in the upper vertical plane and angle in the lower vertical plane) and in horizontal rotation. These traction arms (16) support at their end pulley supports (17), screwed by traction support arms screwed by specific screws (18). On the pulley supports (17) are placed traction pulleys (19).

Pins (20) fixed in the upper part of the traction support arms (16) make it possible to receive a spacer rod (21) which allows the adjustment of the interior or exterior angle of the traction support arms (16) and their blocking. This removable rod is made up of two hollow and cylindrical tabular parts which fit together and slide between them, allowing either the lengthening of the cylindrical tabès, or their shortening depending on the desired angles of rotation to be obtained at the level of the traction support arms.

The tabes are perforated at regular interdistances; these perforations allow their ends to be accommodated in the pins (20) of the traction arm supports (16). The end of the nipples (20) fixed on the traction arm supports (16) is threaded to receive the specific locking nut (22). The spacer rod (21) is provided at its linear center with an adjustment and locking screw (23) allowing extension in the longitudinal plane or vice versa. The traction support arms (16) are adjustable and lock or unlock this assembly using the threaded screw and the handle tightening nut (24).

On the periphery of the outer jacket (1), the cylindrical parts (25) slide which are blocked or unlocked as desired by handle screws (26) acting by locking compression on the outer jacket (1). The cylindrical parts (25) support by screws (27) a plate (28) called 'back'. A counter-top (29) is covered either with thick leather (30) enclosing a composite material (31) with high anti-allergic resistance ensuring comfort comfort over its entire height and surface, or wood covered with static mechanical rotating massage balls (32). The counter-plate (29) is provided with pressure pins (33) which fit into the plate (28). The plate (28) is provided with holes receiving the pressure pins (33) of the counter-plate. Thus, you can change the counter-plate as desired depending on whether you want to obtain different massages (harder or softer).

The safety guardrails (34) fixed to the sides of the plate (28) and held by axes (35), have a rotational movement of 90° on the vertical plane. The upper part of the guardrails allows the person to stand and get up. The guardrails can also take the protection and lifting position following the principle of a crutch. A seat (36) is supported by a composite plate (37) which is fixed on the part (38) which can slide on the outer jacket (1) or be blocked there depending on the adjustment by a handle screw (39). The seat (36) pivots on two horizontal planes, one at 360°, the other at 180°.

In addition to the descriptions in point 15 of chapter 19, the entire operating system of the PMR bicycle support arm (plate 39 - figures 109 to 112) is:

A bicycle support arm (40) is fixed on the cylindrical part (41) which slides on the vertical plane and which can perform limited rotations on the horizontal plane. On the bicycle support arm (40) are fixed two sets of gears (42 and 43), which rest on the axes (44 and 45). A specific chain (46) is driven by the crankset (47). A protective casing (48) surrounds the entire bicycle support arm. On the cylindrical part (41) there is a handle screw (49) which tightens and blocks it in order to adjust the height of the bicycle support arm (40). A cylindrical stopper (50) limits the vertical travel of the part (41).

In addition to the descriptions in point 15 of chapter 19, the entire seat operating system for obese PRMs (plate 39 - figures 109 to 112) is:

A specific seat intended for obese people, which can be integrated into the system in place of the normal seat, is provided in addition.

49. Al scenario in the earthquake context (plate 41 - Al. figures 120 and 121)

In addition to the descriptions of scenario Al in chapter 20, the entire operation of the passenger compartment module and its ancillary elements (plate 41 - Al. figures 120 and 121) is: The vibrations are absorbed on the one hand by the system in place, in particular, by the panels, floors and other anti-seismic systems, stated and presented in the project, on the other hand, by the ground designed specifically to absorb a large part seismic waves but also to restore the balance of the natural terrain in medium-sized deformation. This is in order to arrive at a result including the seismic systems in movement and the static systems in simultaneous deformation.

50. Scenario A.2. in the event of submersion (plate 41 - A2. figures 122 to 125)

In addition to the descriptions of scenario A2 in chapter 20, the entire operation of the passenger compartment module and its ancillary elements (plate 41 — A2. figures 122 and 125) is:

For light flooding, the module remains stationary up to a water height corresponding to the situation programmed in the passenger compartment module. The water level can then be a few tens of centimeters below the threshold of the main access door to the passenger compartment module.

For rising water levels reaching a few centimeters below the threshold of the main door providing access to the passenger compartment module, an automatic control allows the immediate raising of the module depending on the rising water. For water rises greater than the maximum elevation capacity of the module, an automatic release using claws is provided; this stall is subject to manual control. In this case, the module is completely detached and becomes completely independent of the whole. From then on, the flotation system is put in place automatically by float systems, one supporting the mass of the passenger compartment module, the other ensuring its flotation.

51. Scenario A3 in the event of drift (plate 41 - A3. figures 126 to 130)

In addition to the descriptions of scenario A3 in chapter 20, the entire operation of the passenger compartment module and its ancillary elements (plate 41 - A3. figures 126 and 130) is:

Depending on the nature of these waves and the environment, when the oscillation of the module approaches its maximum inclination axis, lateral floats, partly upper, deploy automatically thus allowing the recovery of the module which is at water level on one of its lateral parts, and thus guard against any possible shock with sustained and external physical constraints.

In the event that a very violent storm of an exceptional nature occurs, and when the float ensuring the flotation system is at its limit state of stress, a marine anchor is released in order to avoid a situation of uncontrollable drift risking damage. cause loss of the module. The anchor holding winch remains active and its operation control is ensured automatically inside the passenger compartment module. The winch allows the module to drift in a controlled manner in order to avoid any violent traction that could irreversibly damage the assembly.

Furthermore, the same phenomenon can occur in a freshwater environment (lake, river, river, etc.). In this case, the phenomenon is identical to that in the marine environment, the anchor can be dropped. If the instability phenomenon continues, a grappling hook is launched via a grappling gun on the route of a tree, for example, or rocks in order to stabilize the entire module by both actions simultaneous (anchor and grappling hook).

In the most extreme case and depending on the simultaneous atmospheric context (very violent wind, extreme storm, etc.), the cabin module must be capable of immersion a certain number of meters below the water level, in order to to eliminate as much as possible all external constraints. Its anchor ensures it stays underwater without drifting or aggression. To enable this operation, the upper inflators are deflated semi-automatically.

52. Scenario A.4. in the event of a fall (plate 41 — A4. figures 131 and 132)

In addition to the descriptions of scenario A4 in chapter 20, the entire operation of the passenger compartment module and its ancillary elements (plate 41 — A4. figures 131 and 132) is:

An automatic system allows the opening of ultra-rapid inflation balloons which ensure a relatively slow descent, depending on the height. These balloons guarantee an inflation reserve for automatic parachutes which then come into action in turn; the passenger compartment module then has a relative possibility of being installed without damage.

53. Scenario A.5. in the event of lava rising (plate 41 - A5. figures 133 and 134)

In addition to the descriptions of scenario A5 in chapter 20, the entire operation of the passenger compartment module and its ancillary elements (plate 41 — A5. figures 133 and 134) is:

Balloons provided for this purpose, located in the upper part of the passenger compartment module, are inflated. The claws allow the separation of the cabin module which then rises in order to very quickly gain altitude and maintain it there to navigate.

54. Scenario A.6. in normal times (plate 41 - A6. figures 135 to 138)

In addition to the descriptions of scenario A6 in chapter 20, the entire operation of the passenger compartment module and its ancillary elements (plate 41 - A6. figures 135 to 138) is:

The breakwater (bow) is put in place to facilitate penetration into the water and thus ensure easier advancement of the passenger compartment module. In the event that problems of various kinds arise with the propulsion engines or ancillary technical parts, paddle wheels will be installed. These paddle wheels would allow the propulsion of the cabin module.

In the event of simultaneous failure of the paddle wheels and propulsion motors, a “gadille” wheel allows the module to advance at a very low speed. This "gaudille" wheel is an approach to a turbine similar to a paddle wheel placed in the horizontal plane below the lower floats, whose rotational movements can be reversed, in the event of rudder failure, to thus maintain a desired course. The peripheral gateway can then be set up automatically or manually. Outdoor renewable energy and detection systems can then be at maximum efficiency or at maximum remaining efficiency.

55. Scenario A7. in the event of avalanche and snowfall (plate 44 - A7. figure 179) In addition to the descriptions of scenario A7 in chapter 20, the entire operation of the passenger compartment module and its ancillary elements (plate 44 - A7. figure 179) is:

In regions and sites with risk of type 5 avalanches, the cabin module and its ancillary elements are capable of ensuring the protection of people.

56. Scenario B: Passenger compartment module and its ancillary elements making up the entire main element (plate 41 - Bl. B2 and B3. figures 139 to 141)

In addition to the descriptions of scenario B in chapter 20, the entire operating system of the central anti-seismic support system of the passenger compartment module fixed to the platform (plate 41 - Bl, B2, B3, figures 139 to 141) is :

In the case where the entirety of such a system is set up at a site capable of supporting this type of installation and implementation, we can then consider that great care must be taken at the level of the safety and security of the individual. In addition, rapid intervention and information measures contribute to the effectiveness of this protection in the face of extreme natural disasters that can occur without warning.

This is why in this hypothesis, emergency evacuation is no longer necessary as all these elements ensure the immediate safety of individuals. Consequently, the installation of this type of element meets their protection and survival needs: the passenger compartment module, the protection vent, the survival airlock, the telescopic evacuation or emergency access airlock , the cocoon (optional but complementary in certain cases, because the shield ensures effective protection of the passenger compartment module; the cocoon being recommended when the module does not have the “shield/protective mouth” element).

The present scenario is as follows: a message received at the passenger compartment module at the location of the synoptic table, located by the satellite radio frequency part is decoded and written on the printer, an audible and visual alert then causes the start of the cycle of placing on alert. The family or group of individuals concerned must have access to the passenger compartment module or already occupy it depending on the circumstances at the time. The alert is given sufficiently in advance and this gives the organization plenty of time. The module, once locked and perfectly sealed, is controlled both by the user at the general and synoptic control panel and by the on-board computer. The passenger compartment module descends vertically using its central cylinder. Once at the bottom of the “mouth” element, it rests on its anti-seismic cushions.

The external peripheral solar panels at the level of the “mouth” element fold inside this same element into the compartments provided for this purpose using appropriate peripheral cylinders. Once this operation has been carried out, the shield panels close in order to completely seal the “mouth” element with absolute tightness. the panels are moved by a set of cylinders housed in compartments provided for this purpose. Once this operation is completed, the general check is carried out by computer at the level of all technical points, the general condition and all the elements.

The group of individuals then listens to all events that may occur outside (approaching tsunami, earthquake, cyclone, volcanic smoke, etc.). The system must be able to cope with a spontaneous immersion of great importance in the presence of a tsunami subjecting the whole to extreme pressures or to particularly high temperatures (heat or cold). In the event that people living in the passenger compartment module are still outside during the natural disaster phenomenon, it is possible for them to access the passenger compartment module through the telescopic airlock which is located on the survival airlock element, airlock ambulatory.

Likewise, if there is an urgent need to exit or evacuate groups of people inside, the operation will be done in reverse. A winch and a flexible automatic ladder facilitate this evacuation. Particular attention is paid in the context to the evacuation of PRMs who can be evacuated by a PRM lift located at the base of the telescopic emergency evacuation airlock. Different PMR devices are distributed across all of these additional elements.

In the event of absolute impossibility of exit or entry, a survival airlock is accessible; it includes all the elements and devices necessary for relative durability over time. In the event that an irreversible problem arises at the level of this entire group of elements, the passenger compartment module must be able to urgently extract itself from this assembly, and we then find ourselves in the various scenarios adapted to the case of the passenger compartment module alone and completely independent.

57. Scenario Cl: installation of the passenger compartment module in the trees (plate 42 - figures 142 to 144 and 146: plate 46 - figures 200 to 203)

In addition to the descriptions of scenario Cl in chapter 20, the entire operating system of the central anti-seismic support system of the passenger compartment module fixed to the platform (plate 42 - figures 142 to 144 and 146; plate 46 - figures 200 at 203) is:

The cylindrical cover (1) by pressure or vibration of the passenger compartment module (A) compresses the cylinder (2) held by the base of the cover (3) which is held by the part (4) enclosing the system. A ring (6) is fixed on the cylindrical sleeve (5), comprising compression cylinders (7). A composite free ring (8) ensures delicate and secure tightening on the platform (9). A specific capstan nut (10) allows the part (4) to be tightened. A composite free ring system (11) leaving vertical play and providing a stopper system (12) is held tight by screw handles (13). The axis (14) can be the element of the structure of the raising or lowering cylinder of the passenger compartment module or a single part for its attachment (without raising or lowering cylinder).

In the case where the module is no longer associated with the support platform, and in the specific case of the module being fixed in the branches of trees, a set of complementary elements is necessary, namely, the part (15 ) encloses the cylindrical part (16) on which compression cylinders (17) are fixed. On the part (15) is fixed an anti-seismic assembly which connects the body of this part (15) to the anti-seismic arm. For the proper functioning of the system and in this case, the part (15) receives the part (4).

The fingers (plate 46 - figures 205 and 206) allow the assembly to be held on the branches and automatically adapt to the diameter of the branch on which the arm must be held (plate 46 - figures 205 and 206) and which must be in turn keep the module in balance. Once this operation has been carried out, at the end of the finger, a part slides in the hollow part of the latter until it reaches a holding tightening adapted to the needs. Furthermore, this last operation can be carried out manually by a tightening strap which is placed in the hole at the end of the finger.

In addition to the descriptions of scenario Cl in chapter 20, the entire operating system of the body of the anti-seismic forearm (plate 46 - figure 204) is:

The body of the forearm is made up of a cylindrical box with two parts (22 and 23), which is held in the center by a threaded system (24) ensuring their connection. A cylinder liner spacer (25) ensures the movement of the axis (26) on which rings (27) comprising anti-seismic cylinders (28) are fixed.

In addition to the descriptions of scenario Cl in chapter 20, the entire operating system of the anti-seismic arm (plate 46 - figures 205 and 206) is:

The arm makes the connection between the finger and the forearm. The arm is moved by a system of cylinders. The arm (18) is held by links (19) which allow the angular movement of all the arms (18). On one of the ends of the arm (18), an end of the forearm is fixed which allows a 360° rotational movement and an angle of 180° in the vertical plane. The other end of the arm (18) receives the finger (20) which encloses the inner finger (21) allowing it to slide.

58. Scenario C4: forest model ( ^“ plate 42; plate 47 – figures 207 to 211)

In addition to the descriptions of scenario C4 in chapter 20, the entire operating system of the anti-seismic platform (plate 42; plate 47 - figures 207 and 211) is:

A platform (1) is supported by the hooks (2) placed at each end of the platform (1). The hooks (2) are fitted with rollers (3) protecting the traction cables (4) which are passed through the rollers (6) and the counter roller (7) of the collar (8), fitted with crampons (9). The collar (8) is tightened by the lever (10). The cables (4) are tensioned by the winch located on the platform (at each end of the traction point).

In addition to the descriptions of scenario C4 in chapter 20, the entire operating system of the anti-seismic carrying arms (plate 47 - figures 209 to 211) is: The platform (1) is supported by the carrying arm ( 2) reinforced with ribs

(3). This arm is held by a cylindrical axis (4) which is provided with keys (5) allowing rotation by the toothed wheel (6) driven by the toothed wheel (7), driven by the motor (8). The part (9) ensures the transmission between the support arm (2) and the hooking arm (11). The part (9) supports the support arm (2) and is held by the rivets (10) allowing the opening or closing of the hooking arm (11) including the anchoring crampons (12), fixed on the part (13), also ensure clearance compensation by vertical rollers (14) placed in the housing (15) of the hooking arm (11). Cylinders (16 and 17) ensure the closing, opening, tightening and blocking of the hooking arm (11). The motors (18) provide automatic backlash compensation.

59. Scenario E: installation of the cabin module in an aquatic environment ( ^“ plate 42: plate 48 – figure 212)

In addition to the descriptions of point 1 of scenario E in chapter 20, the entire operating system of the anti-seismic platform (plate 42; plate 48 - figure 212) is:

The platform (1) on which the passenger compartment module (A) is located is guided by guide handles (2) made up of a cylindrical part containing a set of ball bearings (3), enclosed by the cover (4 ). The guide handle (2) has a transverse cylinder welded to that of the vertical cylinder. An anti-seismic box composed of two parts (5 and 6) is held by a clamping assembly (7). An inner jacket (8) receives the compression of the cylinder (9) which is fixed on the ring (10). A cylindrical central shaft (11) penetrates the housing portions (12 and 13) to enable lateral movement of the platform support arm (14). This cylindrical axis (11) is provided at its ends with a compression cylinder (15). The platform support arm (14) is penetrated by the cylindrical hooks (16) of the platform and a compression cylinder (17) is attached to the cylindrical end of the platform hook. A winch support (18) is fixed on the platform (1) and supports all the traction maneuvers of the cable (19) by horizontal roller cylinders (20) and vertical roller cylinders (21) which take up the possible slack in the cable when maneuvering. The double winch (22 and 23) allows the activation of the movements. Tensioner guides (24) ensure linear tension of the traction cables. The guide element (25) allows the raising or lowering of the platform of the module or of the carrying arm or of the module itself depending on.

60. Scenario F: installation of the passenger compartment module in a marshy area (plate 42; plate 49 - figures 215 and 216^

The entire operating system of the anti-seismic holding fin (plate 42; plate 49 - figures 215 and 216) is:

A surface maintenance fin in marshy areas is necessary to support the passenger compartment module. A fin connected to the articulated arm supports the entire cabin module. The fin is made up of inflated elastomeric composite elements (1), a metal support consisting of cylindrical parts (2), inflated elastomeric composite elements (3), a central composite elastomer membrane (4), inflated composite elements (5), a gridded metal support (6), inflated composite elements

(7).

The body of the fin (8) is fixed on an axis (9) allowing the fin element to connect to the arm (10) thus obtaining the possibility.

61. Relationship between elements in water, forest or on the ground

1. Carrying the passenger compartment module (plate 42 — figures 142 to 154, - plate 48 — figures

212)

The passenger compartment module carrying operating system is:

The passenger compartment module is carried by a mini platform of shape that can vary and always adapted to the specific context of natural disaster phenomena. The aesthetics are particularly strong. This platform is made of light and resistant materials adapted to the ambient aquatic environment as well as their operation. It is surrounded by a peripheral guardrail to prevent any accidental falls of an individual.

At the end of the platform, between three points or following the geometric figure to be supported, “handles” constituting the elements allowing the sliding and stability of the platform are positioned at the level of the guide cylinders. These “handles” are equipped with anti-seismic systems. The sliding and guiding of the “handles” are carried out in addition by ball bearings to relieve mechanical stress and thus facilitate movement through a low coefficient of friction and rolling. The module is left free to attach to the horizontal plane of the platform, but is held, if necessary, by the safety stop. Thus with the central part of the anti-seismic system and its side “handles”, the passenger compartment module is permanently stabilized and is little subject to strong resulting stresses.

2. Guiding elements (plate 48 - figure 214J The passenger compartment module guidance operating system is:

The guide elements (6) are made up of varied geometric figures which can be adapted to the mechanical constraints as well as the requested aesthetics. The guide elements are hollow parts on the inside and smooth on the outside. In this case presented, the guidance consists of three elements with geometric figures made by hollow cylinders. These three cylinders allow the passenger compartment module to be lowered or raised via its platform. This rise or fall can be carried out either hydrostatically using the flotation inflator placed on the periphery of the platform on which the passenger compartment module rests (natural rise or fall of the water), or by a mechanical, pneumatic or electrical system. .

In the center and below the plane of the passenger compartment module, at the upper end of the tubes, is placed a drill bit system (plate 48 - figure 213) on which rests a set of pulleys (1) ensuring traction of the cables (2) as well as catching up on play in different angles and planes. A pulley support box (3) holds the latter, ensuring the lifting or lowering movement of the passenger compartment module. The pulleys are slightly off-centered from the main axis via the pulley support which supports the entire pulley system, in order to minimize the mechanical stresses acting on them. The pulley supports are held at the central axis (4).

An intermediate ring (5) preventing blocking and frictional contact of the pulley supports with each other is placed at each interval requiring it. At the end head of the pulley support axle, an anti-seismic system (6) is placed. Washers, nuts and counter-nuts (7, 8 and 9) allow locking on the axis of the pulley carrier support.

3. Stem support (plate 48 — figure 214)

The operating system of the passenger compartment module stem support is:

A system of jibs (3) can circulate on the periphery of the cylindrical support holder (1) of jibs, a wheel (2) ensures its rotation. A cable system (4) makes it possible to raise or lower the entire passenger compartment module in optimal safety conditions. At the base of the stems (5), a security system using specific pins and keys ensures the fixing and stability of the stem concerned.

4. Traction cables (plate 48 - figure 212) The operating system of the passenger compartment module traction cables is:

The traction cables (19) placed longitudinally and vertically along the guide tubes (25), pass inside tensioning guides allowing sustained flexibility in terms of traction of the cables. J. Tensioner guides (plate 48 — figure 212) The operating system of the passenger compartment module tensioner guides is:

The tensioner guide (24) consists of a central pulley and two small free cylinders rotating under the effect of friction of the cable. The tensioning guides are placed along the guide cylinder following spaces allowing uniform tension on the cables which also take up any play.

6. Operating winch (plate 48 — figure 212j

The operating system of the passenger compartment module operating winch is:

A maneuvering winch (18) placed and fixed on the platform (1) of the passenger compartment module (A) makes it possible to carry out all the maneuvering operations relating to the logical phases of the emergency operations to be carried out and in the best safety conditions . There are three winches, placed at each end of the lifting constraints (at the level of the guide cylinders (25), etc.).

7. Flotation The flotation operating system of the passenger compartment module is:

Peripheral inflators, placed under the platform on which the passenger compartment module rests, allow the system to remain naturally buoyant. In the event of an extreme natural disaster situation, a visual and audible alert specifies the type of phenomena expected to occur; the on-board computer located in the volume of the passenger compartment module then controls the synchronized rotation of the lifting winches, the platform on which the passenger compartment module rests is then lifted urgently in order to bring it to a safe and secure height adapted to the context. The module or the platform of the module (depending on the case of the model and operating principle) also offers the possibility of being able to immerse itself to a certain depth if the case proves necessary; this submersion could reach a certain number of meters.

8. Safety inflators

The operating system of the passenger compartment module safety inflators is:

Safety inflators placed under each part of the platform arms ensure the safety of the latter in the event of an unexpected vertical fall (defective cable, cable breakage).

9. Safety for separating the passenger compartment module from the platform supporting it The safety operating system for separating the passenger compartment module from the platform supporting it is:

A safety system allows the separation of the passenger compartment module from the platform/walkway supporting it. In this case, in addition to its circular float placed at its lower part, a complementary semi-spherical float placed at its base and in its axis of gravity automatically inflates in order to stabilize and maintain the passenger compartment module in a vertical plane with greater ease .

10. Headlights The operating system for the passenger compartment module headlights is:

A beacon light can be installed at the upper level and at each end of the multiple support guides or at the level of the single guide (if this is the case).

11. Single guide cylinder aquatic module

The operating system of the single guide cylinder aquatic cabin module is:

The unique guidance system of the cabin module, in an aquatic environment, is based on the same basic system as that of the multiple cylinder guidance. The only difference is the number of cylinders.

12. Aquatic module with aquatic beacon The operating system of the aquatic cabin module with aquatic beacon is:

The aquatic beacon system is based on the same principle as that of the aquatic module with a single guide cylinder. Only the sliding of the movements in translation and rotation differs because at this module, the guide cylinder passes through its axis, which does not change the characteristics of the latter (same interior and exterior configuration), only the seismic bases differ , the symmetrical and uniform bases of the passenger compartment module are adapted substantially to the desired type of operation, for example, sliding and sealing. In terms of detections and alarms, the characteristics are identical to the basic project module. In order to reinforce the height of the position of the passenger compartment module, the platform support guides can be fitted with a system of extendable cylinders ensuring a greater height in the desired context.

62. All-wood passenger compartment module (board 51 - figure 232; board 52 - figure 233 board 53 - figure 235: board 54 to board 58)

In addition to all the descriptions in chapter 22, the entire operating system of the anti-seismic sole box (plate 55 — figures 240 and 241) is:

A two-part peripheral anti-seismic box absorbs seismic movement. A lower sole (1) has grooves (2) on which the compression cylinders (3) come under pressure, which are held by junction pieces (4), which fold and unfold like an accordion (before implementation). ). The cylinders (3) are separated from the other elements. An upper sole (5) has grooves (6) on which cylinders (7) come under pressure. On the lateral parts (8) of the lower sole (I) _5, compression cylinders (9) are fixed. On the lateral parts of the upper sole (5) compression cylinders (10) are fixed.

In addition to all the descriptions in chapter 22, the entire operating system of the anti-seismic stirrup (plate 55 — figures 240 and 241) is:

A compression stirrup (11) takes up the anti-seismic clearance. Anti-seismic jacks

(12) are placed at its two ends. Compression adjustment is done by a threaded rod

(13) passing into the cylinder (14). The ends of the threaded rod (13) are held and tightened by a washer, a nut and a lock nut (15, 16, 17). The end cylinders (12) are supported by the caliper arm (18), supported by the caliper body (11).

On the lower part of the lower sole (1) a longitudinal stop (20) is fixed over its entire periphery. A groove (21) is also made on the entire periphery. On the upper part of the upper sole (5) a longitudinal stop (22) is fixed over its entire periphery. A groove (23) is also made over its entire periphery. The longitudinal stops (20 and 22) ensure the mobility of the sole structure-stirrup assembly. Longitudinal supports (24 and 25) fixed to the panel structure support the anti-dust and anti-seismic protection bellows (26).

In addition to all the descriptions in chapter 22, the entire operating system of the anti-seismic connection internal structure/external structure (plate 55 - figure 243) is: At the level of the fixings connecting the internal structure to the external structure, anti-seismic spacers (1) are put in place. They allow a flexible connection and pass through the honeycomb panels without loss of energy and ensure good quality sealing. The anti-seismic membrane (2) allows translational movement in the case of seismic vibrations. It is made of composite material and elastomer. It is placed on the periphery of Pentretoise (1) and on the thickness of the last exterior peripheral panel (3) as well as on the first interior panel (4) of the passenger compartment module. A physical connection is made by a screw (5).

In addition to all the descriptions in chapter 22, the entire operating system of the framework (plate 54 - figures 236 to 238) is:

The all-wood structure is made up of a set of wooden elements which represents the framework for receiving the panels (8) of the all-wood cabin module. This framework consists of a support (1), a specific lower sole (2), a specific upper sole (2), a connecting post (3) with absorption of transverse and longitudinal forces, an oblique sole supporting the lower panels (5), a connecting crosspiece (6); the whole is anchored by wooden dowels (7). An anti-seismic system is located in the side part of the module shell, in the upper part and in the lower part of the shell (structure board 54 - figures 236 and 237, 239).

In addition to all the descriptions in chapter 22, the entire operating system of the panels (plate 54 - figures 236 and 238; plate 56 - figure 247) is: The panels (8) are made up of wooden elements of suitable dimensions . They are pegged (7) and glued together to form a perforated plate thus constituting, once the assembly is complete, cellular panels allowing the passage of air through the cells (9). Through these, the pipes necessary for heating, air conditioning and hyper-cold provide the needs desired by the cells.

In addition to all the descriptions in chapter 22, the entire operating system of the pipes (plate 57 - figures 248 to 251) is:

The pipes are distributed in the panels of the passenger compartment module so as to provide maximum efficiency. They are arranged either in a transverse line perpendicular to the panels of the passenger compartment module (Plate 57 - figure 249), either diagonally and staggered (Plate 57 - figure 250), or in a line parallel to the panel of the passenger compartment module (Plate 57 - figure 251). The pipe returns are bent at their cycle ends (1) in order to return to their redistribution point (plate 57 - figure 248).

In addition to all the descriptions in chapter 22, the entire operating system of the supply and distribution manifolds for heating, air conditioning and air conditioning (plate 56 - figures 244 to 246) is: power supply (1) for distribution of needs (heating, air conditioning, hyper-cold, pressurized air) are arranged in the receptacle of the passenger compartment module, in the technical area. These feeders supply the desired circuits, depending on the needs. They are circular and cylindrical in most cases. On the circumferences of these feeders, injector nipples (2) allow the connection of the conduits concerned. The number of nipples is proportional to the cycle of the ducts or pipes which must ensure each function (heating, air conditioning, hyper-cold, pressurized air). In order to multiply the number of connections, circuits and pipes, and also to lighten the distribution feeders (1), an element called 'distribution hand' (3), equipped with several flexible connections (4), allows the connecting feeders to circuits, conduits (5) and distribution pipes which pass through the honeycomb wooden panels.

Stopcocks (6) are placed at the outlet head of the water tanks (1), in front of the connection of the distribution hand (3). A safety and security valve (8) is placed near the general distribution inlet of the tank (1).

In addition to all the descriptions in chapter 22, the entire operating system of the heating, air conditioning and air conditioning units (plate 56 - figures 244 to 246) is:

Blocks distributed around the outer periphery of the last interior panel of the passenger compartment module, at the level of the wooden panels, allow complementary heating, air conditioning and air conditioning. This heating principle is achieved by a heating block (1) comprising thermal insulation (5), sound insulation (6). The heating block (1) consists of a support capable of receiving the supporting members and the rotating members. It is composed of heating resistors with rotating fins (2) and resistors with fixed fins (3), linear fans (4), horizontal or vertical. THE organs rotating between them produce a movement of hot or hyper-hot air. The principle is the same for cold and hyper-cold with the exception of the coils and their accessories which are integrated on the inside of the heating resistors and in the vertical plane, integral with the support of the heating block.

In addition to the general description, the entire operating system of the door and the double door (plate 52—figures 233 and 234) is:

This door is made up of sliding frames (1) on upper rails (2) in the upper part and lower ones in the lower part. A perfect seal is achieved (3); the double transverse door allows the sliding of the door frames in the structure of the passenger compartment module without disturbing the heating surfaces and volumes inside this structure. A system of jacks (4) is placed horizontally in the axis of the doors and on both sides (left and right).

63. Designs and models

The designs and models presented in this file are an integral part of the patent application, insofar as they describe and accompany the design of the project and ensure its intelligibility.