Abstract:
A multiblock robot system with to each other compatible-and plug connectable, stationary and mobile earth, sea, aviation, planetary and space flight capable multiblock robot system standard cells, multiblock robot flange plug booster units and multiblock robots. Reconstructable with minimal expenditure of development and construction and by optional combinations between each other and with the total spectrum of all multiblock robot standard parts, objective-directed used for stationary and mobile multiblock robot individual systems and total complexes for mainland, sea, aviation, planetary and space flight fields, always exchangeable to each other, removeable, disintegrateable and re-plug connectable to the most different multiblock robot system solutions.

Description:
FIELD OF THE INVENTION 
     The application relates to a multiblock robot system with to each other compatible multiblock robot system standard cells, multiblock robot flange plug booster units and multiblock robots which are used on earth, in the sea technique, in the aviation technique, in space and on other planets. 
     DESCRIPTION OF THE PRIOR ART 
     It is well known, as illustrated in U.S. Pat. Nos. 5,241,875-5,850,762-5,852,353 and 6,014,597, as also in U.S. patent application Ser. No. 07/986,532 and 09/298,204, to provide multiblock robot systems with the advantage that object-directed multiblock total systems can be disintegrated and reconstructed with only a minimal expenditure of development and construction and with only a few handling operations by the users themselves for the originally aimed sphere of activities and which can be exchanged to each other and plug combined to other robot system solution. 
     SUMMARY OF THE INVENTION 
     It is an object of the present invention to increase further the advantages of economical manufacturing, functionality, the spectrum of operations and the application flexibilty of these multi-axis robot systems by introducing a small number of additional multiblock robot standard parts and the integration of to each other compatible multiblock robot system cells, multiblock robot flange plug booster units and multiblock robots for a standardized, all spheres of live comprising system technique, whose components are used on earth, in the sea technique, in aviation, rocket, space flight and planetary technique, thus raising further the number of pieces of all, one to the other compatible multiblock robot standard parts. 
     These objects are attained, according to the present invention, by providing with only a minimal expenditure of development and construction, to each other compatible and plug connectable stationary and mobile, earth, sea, aviation, planetary and space flight capable multiblock robot system standard cells and multiblock robots, with optional combination possibilities and interchangeability to each other and to the total spectrum of all multiblock robot standard parts for any desired multiblock robot system solution, for object-directed stationary multiblock robot individual systems and total multiblock robot mainland, sea, aviation and space complexes. 
     This arrangement is a considerable improvement over the prior-art systems, that by extending the multiblock robot system technique to the all spectra of live encompassing fields of applications, the variety, functionality and economical manufacturing of multiblock robots and other multi-axis systems is furthermore improved. In addition, totally new application perspectives are revealed on earth, in the sea technique, in aviation, on other planets and in space flight applications, where the use of multiblock robots is indispensable and reaches an additional economic efficiency and formative influence, by the creation of a multiblock robot favourable environment. 
    
    
     The novel features which are considered as characteristic for the invention are set forth in particular in the appended claims. The invention itself, however, both as to its construction and its method of operation, together with additional objects and advantages thereof, will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings. 
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIGS. 1 a,b,c  is a front view with a partial sectional view of a multiblock robot system standard cell; the perspective detail of a sub-view in direction of the continuous view-line of the central rotation flange plug connection; the perspective plain view detail of the central rotation flange plug connection; the plain view detail to the central rotation flange plug connection, to the central supply channel in a sectional view and, to the central access channel; 
     FIGS. 2 a,b,c,  is the plain view with a partial sectional view of the multiblock robot system standard cell in accordance with FIG. 1; the plain view detail to the central rotation flange plug connection with central supply and access channel, as also to three centrally arranged, concentric ring bodies, the section of the front view through two multiblock robot system standard cells in the region of the rotation flange plug connections, in the moment of the plug connection operation; 
     FIGS. 3 a,b,  is the front view with a partial sectional view of stationary, one above the other and side by side to each other plug connected, in x- and y- direction movement flexible multiblock robot system standard cells, in accordance with FIG. 1, comprising multiblock robot entrance and roof flange plug booster units; a perspective illustration with a partial sectional view of two multiblock robot system standard cell partial segments, prepared for the plug connection operation; 
     FIGS. 4 a,b,  the perspective view of three stationary, directly one above the other plug connected multiblock robot system standard cells, with central access channel, intermediate floors and always two centrally arranged, concentric ring bodies and, with multiblock robot entrance and roof flange plug booster units; in a perspective illustration, the front view of two, one above the other plug connected multiblock robot system standard cells, with central access channel, a multiblock robot entrance flange plug booster unit and always a multiblock robot roof flange plug booster unit; 
     FIGS. 5 a,b,c,  the perspective illustration of a multiblock flight robot; the accessory flange plug booster units for the flight capability; the accessory flange plug booster units for the conversion of the multiblock flight robot to a multiblock flight and under water robot; 
     FIGS. 6 a,b,  three one above the other plug connected multiblock robot system standard cells with different outer contour, directly plug connected to a ground installed supply channel flange plug booster unit and in head position, with an intermediate platform flange plug booster unit and a landed multiblock flight robot; three one above the other plug connected multiblock robot system standard cells with identical outer contour and intermediate platform flange plug booster units; 
     FIGS. 7 a,b,c,d,e,  the front view of an energy autonomous multiblock robot system standard cell; the energy autonomous multiblock robot system standard cell rotated around 90°; an energy autonomous multiblock robot total complex with two one above the other plug connected multiblock robot system standard cells, in mid position with a vertical wind rotor flange plug booster unit and in head position with a wind propeller flange plug booster unit; an energy autonomous multiblock robot total complex with three one above the other plug connected multiblock robot system standard cells and in head position with a vertical wind-solar flange plug booster unit; the wind flange plug booster unit in a perspective illustration; 
     FIG. 8, the perspective illustration of a multiblock robot harbour total complex with two, one above the other, plug connected multiblock robot system standard cells, having an identical outer contour, whereas the multiblock robot system standard cell in head position is rotated around 90° and, to the right of the center line showing, the floor-bounded load and unload of a mobile multiblock robot system standard cell and, to the left of the center line showing, the sea-bounded load and unload of a mobile, in water moved multiblock robot system standard cell; 
     FIGS. 9 a,b,c,d,e,f,  the side view of, on a road moved multiblock robot system standard cell, which is plug connected to a multiblock robot e-pool vehicles chassis flange plug booster unit, composing a multiblock robot e-pool transporter; the perspective view of, on a road moved multiblock robot system standard cell, plug connected to a multiblock robot e-pool vehicles chassis flange plug booster unit, composing a multiblock robot e-pool individual car; separately illustrated, the pivotable inside compartment unit; the persons box and the load box; the perspective view of a planetary ground vehicle for pilots, with pilot oxygen box, as also the folding vehicle chassis flange plug booster unit of a planetary ground vehicle for multiblock robots; the accomodation platform for multiblock robots; the folded accomodation platform flange plug booster unit; 
     FIGS. 10 a,b,  the side view of a multiblock robot total sea complex with application fields and one above the other plug connected stationary multiblock robot system standard cells and connection between each other through the multiblock robot access flange plug booster units, as also to the left in head position, the landing of a multiblock robot helicopter, in accordance with FIG. 15; the side view of the multiblock robot total sea complex, with loading and unloading of a multiblock robot ship flange plug booster unit; 
     FIG. 11, the plain view of a multiblock robot total sea complex in accordance with FIG. 10, showing the multiblock application fields; 
     FIGS. 12 a,b,c,  the side view of a multiblock robot total sea complex, in accordance with FIGS.  10 , 11 , with additional ground and sea mobile underwater multiblock robot system standard cells, as also the loading and unloading of a water moved multiblock robot system standard cell; the ground and sea mobile underwater multiblock robot system standard cell in a magnified illustration; the perspective illustration of the water moved multiblock robot system standard cell; 
     FIGS. 13 a,b,c,d,  the side view of four water moved multiblock robot system standard cells, with rotation flexible connection to a multiblock robot system standard cell, provided with multiblock robot rudder and propulsion propeller flange plug booster unit; the four multiblock robot system standard cells stationary plug connected to a multiblock robot ship carrier flange plug booster unit, having a multiblock robot rudder and propulsion propeller flange plug booster unit; the side view of a multiblock robot system standard cell, stationary plug connected to a multiblock robot ship carrier flange plug booster unit, provided with multiblock robot rudder and propulsion propeller flange plug booster unit; the side view of the multiblock robot ship carrier flange plug booster unit; 
     FIGS. 14 a,b,  the side view of a water moved multiblock robot system standard cell with rotatable underwater telescopic flange plug booster units, which are provided with gripper arms; the side view of the water moved multiblock robot&#39;system standard cell with under water telescope flange plug booster units, in accordance with FIG. 13, having a multiblock robot drill head flange plug booster unit and vertically movable, along the telescope guided sea mobile underwater multiblock robot system standard cell; 
     FIGS.  15 , a,b,c,d,e,  the side view of a multiblock robot system standard cell, provided with a ground floor drive, vertical rotor, propulsion and tail flange plug booster units for the aviation capable helicopter use; the plain view of the plug connected multiblock robot helicopter; the front view of the plug connected multiblock robot helicopter with cockpit and tail flange plug booster unit; the side view of the multiblock robot helicopter with cockpit and tail flange plug booster units; the plain view of the multiblock robot system standard cell during plug connection for the aviation suitable helicopter use, provided with vertical rotor, propulsion, as also cockpit and tail flange plug booster units; 
     FIG. 16, the perspective view of a multiblock robot helicopter with tail flange plug booster unit and docking to a multiblock robot airplane; 
     FIGS. 17 a,b,c,d,  the front view of a multiblock robot aviation complex, provided with separate vertical supply channel, as also with a stationary on the ground plug connected multiblock robot system standard cell, above it a multiblock robot roof flange plug booster unit and above this, three landed, vertically takeoff capable multiblock robot airplanes; the side view of a multiblock robot airplane; the front view of a multiblock robot airplane; the plain view of a multiblock robot airplane with separately illustrated wing flange plug booster unit; 
     FIGS. 18 a,b,c,  the front view of a multiblock robot total space complex, ready for liftoff from the ground, with centrally arranged multiblock robot system standard cells, outside multiblock robot liftoff rocket flange plug booster units, as also with left and right sided liftoff-space rocket flange plug booster units; the side view of a multiblock robot space complex with two, directly side by side and centrally arranged multiblock robot system standard cells, left and right sided multiblock robot liftoff rockets and centrally plug connected liftoff-space rocket flange plug booster units; the side view of a multiblock robot space station liftoff complex with one, centrally arranged multiblock robot system standard cell, provided with tail flange plug booster unit and view to the liftoff rocket flange plug booster unit; 
     FIG. 19, die side view of a multiblock robot total space complex, disconnecting the liftoff rockets and switching over to the tail space rocket flange plug booster unit; 
     FIGS.  20 , a,b,  the side view of a multiblock robot total space complex with outside multiblock robot liftoff rocket flange plug booster units and centrally plug connected liftoff-space flange plug booster units; the plain view of a multiblock robot aviation complex, disconnecting the outsided liftoff rocket flange plug booster units and switching over to the left and right sided liftoff-space rocket flange plug booster units; the perspective view of an accessory multiblock space robot with space rocket flange plug booster units; 
     FIGS.  21 , a,b,c,d,e,  the front view of a multiblock robot total space complex in accordance with FIG. 18 a,  however on a separate access channel liftoff ramp; the front view of a multiblock robot individual space unit on a separate access channel liftoff ramp; the side view of a multiblock robot total space complex in accordance with FIG. 18 c,  however provided with an own vertical lift propeller for the liftoff from the high atmosphere; the multiblock robot total space complex, reaching the right rocket liftoff height and disconnecting the vertical liftoff propeller with a parachute; a multiblock robot space station with own tail rocket propulsion flange plug booster unit. 
     Movement arrows in the Figs. show the movement direction of the system parts, continuous lines with and without view direction arrows from fig. to fig. show the origin and view direction for separated sub-views, sections and system details of the respective figs. Dash dot lines show the contours of possible multiblock robot accessories. The different dessignations and numerals are to a large extend used in analogy to the previous multiblock robot patents and applications, named at the beginning. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIGS.  1 ,  2 ,  3   
     The multiblock robot system standard cells  1 - 28  are multiblock room units which in the basic conception are designed like the multiblock robot standard parts and flange plug booster units in accordance with U.S. Pat. No. 5,241,875 and U.S. patent application Ser. No. 07/986,532. They are equally of nearly the similar design to each other and have central rotation flange plug connections  2 - 2  with current and communication channels, running horizontally and vertically through the multiblock robot system standard cells  1 - 28 . However, in correspondence with the respective needs, for the multiblock robot system standard cells, the known current and communication channels of the multiblock robot standard parts are replaced by supply channels  10 - 1 ′, 9 ′- 40  and access channels  12 - 1 , 1 - 25 . The supply channels  10 - 1 ′ accomodate supply lines  10 - 1  of the most different kind, as current and communication lines, fuel and general fluid feeding and derivation lines. In accordance with the respective objective for the multiblock robot system standard cells  1 - 28 , the supply channels  10 - 1 ′ are surrounded of fluid channels  9 ′ 40 , leading water, fuels, hydraulic fluids and other necessary production and operation fluids. The horizontal access channels  12 - 1  are used for person and multiblock robot passages. They are always in the center of the respective, concentrically to each other arranged, supply and access channels  10 - 1 ′,  9 ′- 40 ,  12 - 1 ,  1 - 25 . The access channels  1 - 25  are vertical channels for tackle line and hydraulic lift plug booster units  3 - 25 , provided for the lifting and lowering of loads, persons and multiblock robots. Especially for stationary multiblock robot system standard cells  1 - 28 , the vertical access channels  1 - 25  for tackle line and hydraulic lift plug booster units  3 - 25 , are surrounded by staircase installations  1 - 25 ″. The vertical supply channels  10 - 1 ′ and access channels  1 - 25  are surrounded by concentric equipment rings  1 - 16  for materials and devices. The multiblock robot system standard cells  1 - 28  are provided with intermediate floors  1 - 30  and intermediate walls  1 - 29 , having sliding doors  1 - 24 . The outer contour has a multiblock segment solar flange plug booster unit  9 ′- 27 , window openings  1 - 24 ′, an internal entrance flange plug booster unit  1 - 26  with sliding doors  1 - 24  to the outside and to the inside and, a transition to the horizontal access channels  12 - 1 . An internal, retractable platform  1 - 26 ′, to the outside covered by a balustrade, is provided above the internal entrance flange plug booster unit  1 - 26 . For the free access from the horizontal access channels  1 - 25  to the vertical access channels  1 - 25 , the concentric, vertical supply channels  10 - 1 ′,  9 ′- 40  and the vertical access channels  1 - 25 , have also sliding doors  1 - 24 . The access and transition from the intermediate floors  1 - 30  through the concentric equipment rings  1 - 16  is possible, if these are rotated on its annular chassis tracks  9 ′- 38  and thus, in the range of the sliding doors  1 - 24  of the vertical access channels  1 - 25 , composing each an access opening  1 - 24 ″. The transition to the intermediate floors  1 - 30  is also possible from the horizontal access channels  12 - 1 . For this, the supply channels  10 - 1 ′,  9 ′- 40 , concentrically to each other arranged, have also sliding doors  1 - 24  in its side walls. The total multiblock robot system standard cell  1 - 28  is supported in analogy to the multiblock robot standard parts of the patents and patent applications named at the beginning, having in head and bottom position turning attachments  41  and thus, being freely rotatable around the center axis and the vertical supply and access channels  10 - 1 ′,  9 ′ 40 ,  1 - 25 , by the driving motors  8 - 1 , the gear rim  25 - 1 ′, the transmission gear  25 - 1  of the rotation flange plug connection  2 - 2 . However, for each of the different rotation positions, the access to the supply channels  10 - 1 ′,  9 ′ 40 , 125  and to the supply lines  10 - 1  is always maintained. But, in accordance with U.S. Pat. No. 5,850,762, there are also provided non-rotatable flange plug connections  2 - 2 ′, having the most different design. Moreover in analogy to the multiblock robot patents and patent applications named at the beginning, the vertical and horizontal supply and access channels  10 - 1 ′,  9 ′- 40 ,  12 - 1 ,  1 - 25  are closed by sliding doors  1 - 24  and have in head and bottom position, on the horizontal exits and on all positions where are provided rotation flange plug connections  2 - 2  and non-rotatable flange plug connections  2 - 2 ′, plug sleeves  2 - 3 ′ and plug units  2 - 3 , as also corresponding clamp and locking devices for the plug connection to adjacent rotation and non-rotational flange plug connections  2 - 2 ,  2 - 2 ′ and the connection of the supply and access channels  10 - 1 ′,  1 - 25 ,  9 ′- 40 ,  12 - 1  and for the plug connection of the supply and access lines  10 - 1 . In so far, the conceptions for the rotation flange plug connections  2 - 2  of the multiblock robot system standard cells  1 - 28  and different multiblock robot booster units, are identical to the conceptions of the rotation flange plug connections  2 - 2  of the multiblock robot, shown in FIG. 5, and follow the same conceptions as for the multiblock robot standard parts and multiblock robot flange plug booster units of the patents and patent applications named at the beginning, but the dimensioning is different The supply channels  10 - 1 ′ consist of horizontal ring bodies with inner ring and outer ring walls, whereas the supply lines  10 - 1  are installed inside of the ring body, or the ring body with inner and outer ring walls composes partly or totally itself a supply line  10 - 1 , as for the lead of fluides. But, the supply channels  10 - 1 ′,  9 ′- 40  are optionally also composed, only of ring-shaped to each other installed supply lines  10 - 1 , without any inner and outer ring walls, and moreover of a ring-shaped solid wall, accomodating the supply lines  10 - 1  in distances to each other, as shown in FIG. 1 b ,  1   d . The provided supply lines  10 - 1  have in its end positions plug units  2 - 3  and plug sleeves  2 - 3 ′, these being sheathed of sealing materials  2 - 3 ″ and conical designed in a way, that in the moment of plug operations, a centering effect facilitates the plug connection of the respective rotation flange plug connections  2 - 2 , being in opposite position to each other. At the same time, the sheathings with the sealing materials  2 - 3 ″ provide sealed secured connections at the transition points of the supply lines  10 - 1  with the plug units  2 - 3  and plug sleeves  2 - 3 ′, if the supply channels  10 - 1 ′,  9 ′- 40  are finally plug connected to each other. The plug units  2 - 2  and plug sleeves  2 - 3 ′ on the periphery of the rotation flange plug connections  2 - 2 , have only a centering effect for the rotation flange plug connections  2 - 2  to each other and are identically designed as the plug units  2 - 3  and plug sleeve units  2 - 3 ′, for the plug connection of the supply lines  10 - 1  within the supply channels  10 - 1 ′. The approximation sensors shown in FIG. 2 c  are provided for the positioning and alignment of different rotation flange plug connections  2 - 2  with its inside supply channels  10 - 1 ′ and supply lines  10 - 1 . There is a centrally installed supply line  10 - 1  with current and communication lines  3 - 1 , and always to the right and to the left side, is installed a supply line  10 - 1  for fluids. The multiblock robot system standard cells  1 - 28  are composed of component segments  1 - 27 , in accordance with FIG. 3 b , having plug units  2 - 3  at on side of the segment edges for the connection to each other and at the outer edges in direction to the center, for the connection with the rotation flange plug connections  2 - 2  and, the counterparts of the component segments  1 - 27  for plug connection to each other, have always on its opposite side of the segment edges, the plug sleeve units  2 - 3 ′Furthermore, the upper and lower wall has peripheral supply lines  10 - 1 , identical to the plug connection detail, as shown in FIG. 2 c , which are connected to a supply ring line  10 - 1  above and below of the multiblock robot system standard cell  1 - 28  and, if all component segments  1 - 27  are plug connected to each other, they are composing a complete multiblock robot system standard cell  1 - 28 . In distances to each other, the supply ring lines  10 - 1  are plug connected with the horizontal supply lines  10 - 1  which surround the horizontal access channels  12 - 1 , by means of vertical connection lines  10 - 1 . All supply and access channels  10 - 1 ′,  9 ′ 40 , 112 , 1 - 25  and the component segments  1 - 27  have on its connection periphery and in the respective connection positions, conical sealing rings with the sealing material  2 - 3 ″, in analogy to FIG. 2 b . The multiblock robot system standard cells  1 - 28 , shown in FIG. 3, plug connected one above the other and adjacent to each other, are provided with rotation flexible flange plug connections  18 - 2 , in the range of the connection transitions of the rotation flange plug connection  2 - 2 . Thus, the multiblock robot system standard cells  1 - 28 , are plug connected on separate multiblock robot entrance flange plug booster units  1 - 26 , and between are provided the rotation flexible flange plug connections  18 - 2 . The separate multiblock robot standard entrance plug booster units  1 - 26  are plug connected by its rotation flange plug connection  2 - 2 , with the foundation flange plug booster units  9 ′- 19  and with the there inside leaded supply lines  10 - 1 . The foundation flange plug booster units  9 ′- 19  are under ground floor supply channels  10 - 1 ′ with inside supply lines  10 - 1  and, which have in its end positions rotation flange plug connections  2 - 2  and non-rotational flange plug connections  2 - 2 ′. They are in concrete casted and also freely under the ground floor installed. The shown foundation flange plug booster unit  9 ′- 19 , to which the multiblock robot entrance flange plug booster unit  1 - 26  is plug connected, with above the multiblock robot system standard cells  1 - 28 , is a foundation concrete block with integrated supply channels  10 - 1 ′, having non-rotational flange plug connections  2 - 2 ′ leading in different directions, for the plug connection with freely under the ground floor laid supply channels  10 - 1 ′ and the there integrated supply lines  10 - 1 , as for waste water, drinking water, fuel lines, current and communication lines. In head position is plug connected a separate multiblock robot roof flange plug booster unit  1 - 32 , which is identical to the separate entrance flange plug booster unit  1 - 26 , but has different equipments and sliding doors  1 - 24 ′ in top position, for the closure of the there provided rotation flange plug connection  2 - 2  and there ending supply and access channels  10 - 1 ′ 1 - 25 . In this head position are also provided multiblock robot hoist flange plug booster units  1 - 31 . The rotation flexible flange plug booster units  18 - 2 , as also the entrance flange plug booster units  1 - 26  and the roof flange plug booster units  1 - 32 , are likewise provided with supply and access channels  10 - 1 ′,  9 ′ 40 ,  12 - 1 ,  1 - 25  with integrated stair case equipment  1 - 25 ″ and supply lines  10 - 1 . These being in identical position to the supply and access channels  10 - 1 ′,  9 ′ 40 ,  12 - 1 ,  1 - 25  with integrated stair case equipment  1 - 25 ″ and supply lines  10 - 1  of the multiblock rotob system standard cells  1 - 28 . So that after the plug connection, a continuous transition of the supply lines  10 - 1  to each other is achieved and a continuous transition of the several supply and access channels  10 - 1  ′,  9 ′- 40 ,  12 - 1 ,  1 - 25 , the stair case equipments  1 - 25 ″ and the supply lines  10 - 1 , from one to the other is composed, which is only separated by the optional sliding doors  1 - 24 . The rotation flexible flange plug connections  18 - 2  are provided with supply lines  10 - 1  and access channels  12 - 1 ,  1 - 25 , consisting of rotation, tensile and deflection flexible plastics. After composition and plug connection of the multiblock robot total complex, the tackle line and hydraulic lift flange plug booster units  3 - 25  as like as hydraulic telescope lift platforms, are connected by lift ropes with the several multiblock robot hoist flange plug booster units  1 - 31  and thus, lifted and lowered over the total length of the vertical access channel  1 - 25 , from the entrance flange plug booster unit  1 - 26  up to the roof flange plug booster unit  1 - 32 . In the same way, a continuous transition from one concentric staircase equipment  1 - 25 ″ to the next one above is achieved, after the plug connection of the several building parts one above the other. Always at the periphery, under 90° to each other, are provided four multi-axis multiblock robot articulated arms  9 ′- 14 , which have hydraulic flange plug booster units in accordance with U.S. patent application Ser. No. 09/298,204. The multi-axis articulated arms  9 ′- 14  react self operating, released by signals from seismic sensor flange plug booster units  9 ′- 21 , to seismic changements and safely absorb earth movements by earthquakes. They have shock-absorber effect and keep the multiblock robot total complex always in a nearly horizontal, balanced state, also in the case of sudden earth sags. Moreover, the rotation flexible flange plug connections  18 - 2  prevent, that shocks and movements, affecting one multiblock robot system standard cell  1 - 28 , are not transmitted to the adjacent multiblock robot system standard cells  1 - 28 , but are absorbed by the rotation flexible flange plug connections  18 - 2 . In so far, the installation in accordance with FIG. 3 is not only suitable for earthquake, hurricane or otherwise endangered regional and general ground floor conditions, but also for under water installations under difficult current situations and for the installation on other planets. 
     FIG.  4   
     The multiblock robot system standard cells  1 - 28  have the most different outer contours, and in accordance with the respective objectives and application fields, different inner and outer equipments. The installations shown in FIGS. 4 a ,  4   b  are on principal identical. However, the total complex of FIG. 4 a  has a more sphere shaped outer contour and the total complex of FIG. 4 b  has a more disc shaped outer contour. Moreover, the installation of FIG. 4 b  shows, that a roof flange plug booster unit  1 - 32  is plug connected between both multiblock robot system standard cells  128 , whereas the three multiblock robot system standard cells, shown in FIG. 4 a , are arranged directly one above the other. The roof flange plug booster unit  1 - 32 , shown in FIG. 4 b  , is there used as an intermediate flange plug booster unit for the storage of multiblock robot battery units  9 ′- 6  at its periphery, being an energy intermediate store of the multiblock robot total complex and a battery dispenser for multiblock robots. The multiblock robot battery units  9 ′- 6  are recharged by the segment solar flange plug booster unit  9 ′- 27  at the outer contour of the multiblock robot system standard cells  1 - 28 . For the multiblock robot total complexes, shown in FIG. 4 a, b , is not provided a staircase equipment  1 - 25 ″, but only a vertical access channel  1 - 25  with inside lift equipment, having in its outer walls the supply lines  10 - 1 , thus being in this case a combined vertical access channel  1 - 25  and supply channel  10 - 1 ′, reaching from the ground floor rotation flange plug connection  2 - 2  up to the rotation flange plug connection  2 - 2 , installed in top position. The several multiblock robot system standard cells  1 - 28  have two intermediate floors and no intermediate walls, so that inside continuous, all around room units are composed. Each intermediate floor is provided with position and direction code train guide-ways  3 - 5 , in accordance with U.S. patent application Ser. No. 09/298,204, for the fast orientation and positioning of multiblock robots. Furthermore is each multiblock robot system standard cell  1 - 28  provided with two concentrical, rotatable rings  1 - 16  which are rotated separately to each other on its ring-shaped tracks  9 ′- 38 , by multiblock robot drive units  9 ′- 39 , as shown in FIG. 2 b,    
     FIG.  5   
     The multiblock robst system standard cells  1 - 28  are designed for earth, under water, over water, aviation, rocket, space and planetary tasks. For these objectives, they are provided with the most different assessories and combinations of corresponding multiblock flange plug booster units, sub and system standard cells. In addition they are fully compatible to multiblock robots and offer a multiblock robot favourable and most effective operational environment For these objectives, the multiblock robots are provided with aviation and under water propulsion flange plug booster units, so that they have an easy access to the multiblock robot system standard cells  1 - 28 , independently of the environmental and operational conditions. The aviation equipment consists of multiblock robot standard parts  2 - 1 , plug connected above the head unit, where otherwise for a mere ground floor operation, only the antenna flange plug booster unit  9 ′- 3  or solar flange plug booster units are plug connected. The plug connected multiblock robot standard parts  2 - 1  are provided with multiblock robot vertical rotor flange plug booster units  9 ′ 41  and propulsion flange plug booster units  9 ′- 42 , which are plug connected to the horizontal and vertical multiblock robot standard parts  2 - 1 , arranged above the head unit. Furthermore, this multiblock robot standard part  2 - 1  is provided with fuel channels. As shown in FIG. 5 b , alternatively or in addition to this equipment, at the back side below the computer unit, to the there plug connected multiblock robot standard part  2 - 1  and to its rotation flange plug connection  2 - 2 , is a separate multiblock robot control flange plug booster unit  9 ′- 43  plug connected, for the control of the propulsion flange plug booster units  9 ′- 42 , being positioned centrally to these units. Below the control flange plug booster unit  9 ′- 43 , plug connected to the corresponding vertical rotation flange plug connection  2 - 2 , is provided a separate fuel flange plug booster unit  9 ′- 47 . The antenna flange plug booster unit  9 ′- 3  has been disconnected and replug connected to the multiblock robot standard part  2 - 1 , which is arranged above the multiblock robot belt drive flange plug booster unit. For the under water propulsion, the multiblock robots have the equipment, in accordance with FIG. 5 c . For the under water operations, the multiblock robot standard parts  2 - 1  have separated fuel flange plug booster units  9 ′- 47  and to its corresponding rotation flange plug connections.  2 - 2 , arranged at the left and the right side, is always one water-rotor flange plug booster unit  9 ′ 44  plug connected. Alternatively, and in accordance with U.S. Pat. No. 5,850,762, there are provided multiblock robot battery booster units  9 ′- 6  plug connected as energy units, instead of the multiblock robot fuel flange plug booster units  9 ′- 47 . Multiblock robots are optionally provided with aviation propulsion flange plug booster units  9 ′- 42  and at the same time with under water rotor flange plug booster units  9 ′- 40 , and additionally with ground floor suitable belt drive units, so that they are able to operate on the ground floor, under water and in the air, without to change, to disconnect, or to replug connect the corresponding flange plug booster units. For space and planetary objectives, the multiblock robots are provided with rocket flange plug booster units  9 ′- 41 , as shown in FIG. 20 c , as also with the accessory fuel flange plug booster units  9 ′- 43  and with walk or drive flange plug booster units. 
     FIG.  6   
     The stationary ground floor multiblock robot total complex comprises three one above the other arranged multiblock robot system standard cells  1 - 28 , in accordance with FIG. 6 a . Each is rotated around 90° in relation to the other. They are conceptionally identical to each other, however, the outer contour of the lower multiblock robot system standard cell  1 - 28  is different to the both others, above plug connected. The multiblock robot system standard cell  1 - 28  in upper position has a retractable platform flange plug booster unit  1 - 26 ′ which is partly retracted. In head position is a landing platform flange plug booster unit with balustrade  1 - 33  plug connected and a multiblock flight robot has been landed. The multiblock flight robot is going to be lowered to the inside of the multiblock robot system standard cell  1 - 28 , by a hydraulic flange plug booster unit  3 - 25 , lowered and lifted inside of the vertical access channel  1 - 25 . The three one above the other plug connected multiblock robot system standard cells  1 - 28 , shown in FIG. 6 a , have totally different outer contours as the multiblock robot system standard cells  1 - 28 , in accordance with FIG. 6 b , but they are conceptionally identical to each other. To each of the multiblock robot system standard cells  1 - 28 , shown in FIG. 6 b , is a passable person platform flange plug booster unit  1 - 33  with ballustrade plug connected. 
     FIG.  7   
     The multiblock robot system standard cell  1 - 28  in ground floor position, shown in FIG. 7 a , is identical to the multiblock robot system standard cells  1 - 28  in head and mid-position, as shown in FIG. 6 a . Above this multiblock robot system standard cell  1 - 28  are provided three rotatable solar flange plug booster units  9 ′- 51 , which are plug connected one above the other by means of its own rotation flange plug connections  2 - 2 . The access and supply channel flange plug booster units  9 ′- 50  have the same design characteristic as the access channels  1 - 25 , in accordance with FIG. 1, and are provided with supply lines  10 - 1 . The segment solar flange plug booster units  9 ′- 51  are identical to the design of the rotatable segment solar flange plug booster units  9 ′- 27 . Between both of the multiblock robot system standard cells  1 - 28 , as shown in FIG. 7 c , is a vertical wind rotor flange plug booster unit  9 ′- 49  plug connected, and in head position is plug connected a multiblock robot wind propeller flange plug booster unit  9 ′- 25 , in accordance to U.S. Pat. No. 5,852,353. The multiblock robot total complex, as shown in FIG. 7 d , with the three one above the other plug connected multiblock robot system standard cells  1 - 28 , has in head position vertical multiblock solar-wind flange plug booster units  9 ′- 49 ′ and above it, is plug connected a multiblock robot antenna flange plug booster unit  9 ′- 3 . The solar-wind flange plug booster unit  9 ′- 49 ′ is composed of three concentrically arranged, curved and conical vertical wind rotor blade flange plug booster units  9 ′- 48 , which are plug connected with the equally curved solar surface flange plug booster units  9 ′- 48 . This permits at the same time the current generation of sun and wind, by means of the solar surface flange plug booster units  9 ′ 48 ′ and, by means of the vertical wind rotor blade flange plug booster units  9 ′- 52 , or only by the sun, or only by the wind, depending on the prevailing weather and sunlight conditions. The generated current is leaded through the vertical supply channel  10 - 1 ′, to the below plug connected multiblock robot system standard cells  1 - 28 . 
     FIG.  8   
     This multiblock robot total complex is located at a harbour quay. The two, one above the other plug connected multiblock robot system standard cells  1 - 28 , have a rectangular contour, and above plug connected rotatable segment solar flange plug booster units  9 ′- 27 . These being plug connected to the central, conical roof contour of the multiblock robot system standard cells  1 - 28 . The central, conical roof contour of each multiblock robot system standard cell  1 - 28  is provided in head position with its own rotation flange plug connection  2 - 2 . Above it are optionally plug connected further multiblock robot system standard cells  1 - 28  with diameter compatible rotation flange plug connection  2 - 2 , or the most different flange plug booster units. Centrally is positioned the access channel  1 - 25 , which closes in its head position likewise with its own rotation flange pug connection  2 - 2 , having a different diameter and being able to be plug connected with other, diameter compatible rotation flange plug connections  2 - 2 , respectively with flange plug booster units. Always at the short ends of the outsides of the multiblock robot system standard cells  1 - 28  are provided access channels  1 - 25 , having in its head positions likewise its own rotation flange plug connections  2 - 2 . The tackle line and hydraulic lift flange plug booster units  3 - 25  within the lateral access channels  1 - 25  are provided for the withdrawal and taking over of multiblock cool box flange plug booster units  1 - 12  and multiblock robots, in accordance with U.S. patent application 09/298,204. The multiblock robot system standard cell  1 - 28  in head position is going to exchange loads to a multiblock robot e-pool transporter and its multiblock robot system standard cell  1 - 28 , as the coolbox flange plug booster units  1 - 12 . These are lifted and lowered between both multiblock robot system standard cells  1 - 28 . The multiblock robot e-pool transporter is positioned by position and direction code train guide-ways  3 - 5  for the deposition and taking over of coolbox flange plug booster units  1 - 12 . At the left side are exchanged, lifted and lowered, cool box flange plug booster units  1 - 12  between the multiblock robot system standard cell  1 - 28  of the multiblock total complex and a multiblock robot ship unit with its multiblock robot system standard cell  1 - 28 . For the take over and delivery of the cool box flange plug booster units  1 - 12 , the multiblock robot ship unit is self operating positioned by an own approximation sensor ring flange plug booster unit  9 ′- 15  around the outer contour, and the signal exchange with the approximation sensor ring flange plug booster unit  9 ′- 15 , at the outer contour of the entrance flange plug booster unit  1 - 26 . For the take over and deposition of the coolbox flange plug booster units  1 - 12  from and to the multiblock robot system standard cell  1 - 28  in head position, the multiblock robot system standard cell  1 - 28  in bottom position of the multiblock robot total complex is rotated around 90°, so that the multiblock robot system standard cell  1 - 28  above is free for loading and unloading. If the multiblock robot system standard cell  1 - 28  in bottom position has to be loaded or unloaded, it is likewise rotated around 90° in direction of the multiblock ship unit, respectively to the multiblock robot e-pool transporter. The stationary ground floor multiblock robot total complexes and also individual installations of multiblock robot system standard cells  1 - 28 , are provided for general applications, as productions, offices, labs, residence objectives, hotels, restaurants, for specific applications like television stations, astro researchs, multiblock robot e-pool computer centers, with the respective, necessary inner equipment being completed with additional outside multiblock robot flange plug booster units. 
     FIG.  9   
     The multiblock e-pool transporters are conceptionally designed as the e-pool individual vehicles. The multiblock robot system standard cell  1 - 28 , plug connected to the vehicles chassis flange plug booster unit  9 ′- 8 , has a similar contour like the greater spaced multiblock robot system standard cell  1 - 28 , in accordance with FIG. 1, but the width is reduced, for the unhindered operation on roads and optionally on rails, in the case of multiblock e-pool robot rail and road transporters and buses. There are likewise provided central entrance flange plug booster units  1 - 26  with rotating inside compartments  9 ′- 28 . Depending on the requirements, transporter and buses have in addition driver seats or load cabin units, and these also being combined with cool box flange plug booster units  1 - 12 , as shown in FIG. 8, which are vertically withdrawable and lowerable, being arranged closely one behind and side by side to each other, inside of the multiblock robot system standard cells  1 - 28 . Multiblock robot e-pool individual vehicles and the e-pool transporter, in accordance with the U.S. patent application Ser. No. 09/298,204, are equally provided with plug connected multiblock robot system standard cells  1 - 28 . Conceptionally, the multiblock robot system standard cells  1 - 28  for individual vehicles are identical to the design, shown in FIG. 9 a . They are plug connected on a multiblock robot vehicle chassis flange plug booster unit  9 ′- 8 , having multiblock robot drive units  9 ′- 9 . The inner equipment corresponds to the objectives of road vehicles. The multiblock robot system standard cell  1 - 28  consists of a back and front part, shaped like vehicle body parts, being plug connected to each other and on the central rotation flange plug connection  2 - 2  of the multiblock robot chassis flange plug booster unit  9 ′- 8 . Near to the connection line between the back and front part, at the bottom section of the multiblock robot system standard cells  1 - 28 , directly above its central, outer rotation flange plug connection  2 - 2 , for the plug connection to the rotation plug connection  2 - 2  of the vehicles flange plug booster unit  9 ′- 8 , is provided a second central, inside rotation flange plug connection  2 - 2 . To this is plug connected the entrance flange plug booster unit  9 ′- 37 , composed of the two, from above withdrawable and lowerable, inside partial segment flange plug booster units  1 - 12 ′, Both inside partial segment flange plug booster units  1 - 12 ′ have in roof and bottom positions non rotatable flange plug connections  2 - 2 ′. The back sided inside partial segment flange plug booster unit  1 - 12 ′ is used as a load unit and the front sided as a passenger unit, having passenger seats and control equipment for all functions of the multiblock robot e-pool individual vehicles. The inside entrance flange plug booster unit  9 ′- 37  with its both partial segment flange plug booster units  1 - 12 ′ is freely rotatable around 360°, giving free access to the passenger and the load units through the side openings  9 ′- 37 ′. For fully self operating multiblock robot e-pool individual vehicles are optionally provided, always mirror imaged combinations of load units and passenger units, as only load or only passenger units for the back and front partial segment flange plug booster units  1 - 12 ′. In the case of a plug connection only with passenger units, the passenger seats are not arranged mirror imaged but all in the same front driving direction. Conceptionally, a multiblock robot planetary ground floor vehicle has a chassis, identical to a road multiblock robot e-pool individual vehicle, but it is foldable from the mid-axis to the longitudinal axis, so that during the space transport, the needed volume is reduced, and it has optional belt or wheel drive flange plug booster units  9 ′- 9 . On the central rotation flange plug connection  2 - 2  of the vehicles chassis flange plug booster unit  9 ′- 8 , is plug connected an oxygen flange plug booster unit  1 - 12  for the oxygen supply of pilots, which in its mechanical function is identical to the inside flange plug booster units  1 - 12 ,  1 - 12 ′ of the spool individual vehicles. But in addition to the multiblock robot standard part  2 - 1 , centrally plug connected to the vehicles chassis flange plug booster unit  9 ′- 8  for the rotation of the inside flange plug booster units  1 - 12 ,  1 - 12 ′ around 360°, is provided a multiblock robot oxygen pump flange plug booster unit  9 ′- 33 , having moreover an oxygen tank flange plug booster unit  9 ′- 47 , identical to the fuel flange plug booster units  9 ′- 47 , provided for the multiblock robots, in accordance with FIG.  5 . Thus, oxygen is pumped by the multiblock robot pump flange plug booster unit  9 ′- 33  to the multiblock robot oxygen flange plug booster unit  1 - 12 , as soon as this unit is rotated around, and the side openings  9 ′- 37 ′ of the inside entrance flange plug booster unit  9 ′- 37  are dosed. As such, the whole oxygen flange plug booster unit  1 - 12  has the effect of an oxygen device without additionally necessary accessory devices, in which the pilots are able to breathe freely, e.g. without oxygen masks. The oxygen flange plug booster unit  1 - 12  is also provided in an identical design, as an air sluice for under water works. In that case, after the entrance of a diver into the oxygen flange plug booster unit  1 - 12 , the likewise intruded water is pumped out and simultaneously oxygen is pumped in. The multiblock robot planetary ground floor vehicle, provided for multiblock space robots, has not an oxygen flange plug booster unit  1 - 12 , but a foldable platform flange plug booster unit  1 - 12 ″, with the front part for the plug connection of a multiblock robot antenna unit  9 ′- 3 , the mid-part for the access of the multiblock space robots with both sided steps, and the back part for the plug connection of a solar flange plug booster unit  9 ′- 25 . 
     FIGS.  10 ,  11   
     The stationary multiblock robot total sea complex is plug connected on foundation flange plug booster units  9 ′- 19 , installed in sea regions. The multiblock robot system standard cells  1 - 28  are plug connected on separate vertical access channels  1 - 25 ′. These have also support column character. The separate vertical access channels  1 - 25 ′ for the accomodation of tackle line and hydraulic lift plug booster units  3 - 25  , are additionally surrounded by staircase equipments  1 - 25 ″ and are sheathed by supply channels  10  - 1 ′ and fluid channels  9 ′- 40 , in accordance of the previous fig. Depending on the static point of views, the separate vertical access channels  1 - 25 ′ are leading centrally right through the individual multibloc robot system standard cells  1 - 28  up to the head position and above it, as shown in FIG. 17 a , having an additional central support column function for the entire multiblock robot total complex. Between each of the one above the other plug connected multibloc robot system standard cells  1 - 28 , is plug connected a multiblock robot vertical wind rotor flange plug booster unit  9 ′- 49 . Furthermore, in head position is plug connected a multiblock wind propeller flange plug booster unit  9 ′- 52 , for the energy autonomous current supply of the multiblock robot total complex, and a multiblock robot helicopter, in accordance with FIG. 15, is landed on the multiblock robot air landing plattform flange plug booster unit  1 - 34 . The several, separated vertical access channels  1 - 25 ′ are rectangularly positioned to each other and plug connected on rotation flange plug connections  2 - 2  with separate, outer horizontal access channels  12 - 1 , being conceptionally identical to the access channels  12 - 1 , inside of the multibloc robot system standard cells  1 - 28 . Therefore, depending on the respective application requirements, they are also sheathed by supply channels  10 - 1 ′ and fluid channels  9 ′- 40 . The outer access channels  12 - 1  have laterally, above and below of its traversing course, rotation flange plug connections  2 - 2 . The outer, horizontal access channels  12 - 1  are plug connecting the several, in the same height to each other, already vertically plug connected multibloc robot system standard cells  1 - 28 , with the internal horizontal access channels  12 - 1 , so that a transition and passage is achieved of persons and multiblock robots, as also the exchange of supply materials and supply fluids, of current and communications, on the shortest ways, from one section of the multiblock robot total complex to the adjacent section. The outer horizontal access channels  12 - 1  compose rectangular frames to each other in the identical height with the transitions to the vertical access channels  1 - 25 ′, but also above and below in optional other heights, which are used as the most different application fields. Thus, an application field for fishing is composed by a fishing net  1 - 36  which stretches between the adjacently separate vertical access channels  1 - 25 ′ and above the laterally arranged rotation flange plug connections  2 - 2  of the tackle line and hydraulic lift plug booster units  3 - 25 , and of these being taken in, respectively lowered. Accordingly, there are provided optional application fields, as for sea water desalting, but also for farming, the production of sea ground treasures, recovering of averages by means of the multiblock flight and underwater robots, in accordance with FIG. 5, and of the equipments, in accordance with FIG.  12 . Moreover, for processing and other objectives, needed for the self sufficient supply of the multiblock robot total sea complex, but also for the supply of external regions. For the sea water desalting application fields, the sea water is leaded to the corresponding application fields through the fluid channels  9 ′- 40 , in accordance with FIG. 1, and by means of multiblock fluid pumps  9 ′- 33 . The produced drinking water is leaded to especially provided fluid channels  9 ′- 40 ′ and, in addition to the self supply of the own multiblock robot total sea complex, it is also leaded to the mainland or to other multiblock robot total sea complexes in greater distances installed, through horizontal fluid access channels  9 ′- 40 ′, laid down on the sea ground. Likewise for the surplus of current, which is generated by multiblock sun and wind flange plug booster units and application fields of the multiblock robot total sea complex, exceeding the needed own consumption, being equally transmitted to the mainland and other consumers, by supply channels  10 - 1 ′, laid down along the sea ground. In addition, own productions of the multiblock robot total sea complex are transported by multiblock robot ship units  1 - 34 , being loaded through the outer, horizontal access channels  12 - 1 , fluid channels  9 ′- 40  and supply lines  10 - 1 . A goods, material, person and multiblock robot exchange is also provided by multiblock robot helicopter units which, like the multiblock flight robots, are landing and taking off on and from the landing platforms  1 - 34 . 
     FIG.  12   
     The multiblock robot total sea complex is similarly designed as the multiblock robot total sea complex of FIGS. 10,  11 . However, multibloc robot system standard cells  1 - 28  are additionally provided under water, guided on the separate vertical access channels  1 - 25 ′, lifted and lowered by the multiblock robot hoist flange plug booster units  1 - 31  which are plug connected laterally to the separate vertical access channels  1 - 12 ′. The multiblock robot hoist flange plug booster units  1 - 31  inside of the separate vertical access channels  1 - 25 , are also for multiblock robot total sea complexes always plug connected in upper position, after composition and plug connection of the multiblock robot total sea complex, so that after lift-rope connection with the respective tackle line and hydraulic lift plug booster units  3 - 25 , these are lifted and lowered inside and along of the separate vertical access channels  1 - 25 ′ total lift height, from the sea ground up to the head position. For the access from the separate vertical access channels  1 - 25 ′ to the under water situated multiblock robot system standard cells  28 , are provided non rotatable flange plug connections  2 - 2 ′, laterally in several heights on the separate vertical access channels  1 - 25 ′, being closed by sliding doors, respectively opened, if the corresponding access openings inside of the respective multiblock robot system standard cells  1 - 28  which are actually under water, are lifted or lowered up to the identical, same heights. The multiblock robot system standard cell  28 , landed on the sea ground, is provided with self operating multiblock robot submerge, propulsion and ground movement equipment. For the submerge operations, the internal fluid channels  9 ′- 40 ′ are used as flood tanks and, in correspondence with the submerge operations, they are flooded or pumped out respectively. For the propulsion is provided a multiblock robot propulsion screw flange plug unit  9 ′- 54 , and for the horizontal direction changements are plug connected rudder flange plug booster units  9 ′- 53  to the stem of the submerged multiblock robot system standard cell  1 - 28 . These equipments are also plug connected to the stems, and to the there installed rotation flange plug connections  2 - 2 , of over water driving multiblock robot system standard cells  1 - 28 . The sea ground drive is achieved by multiblock robot belt flange plug booster units  9 ′- 29  and, the balanced drive over jagged and rough grounds and the steady keeping in an always horizontal position during the sea ground drive of the multiblock robot system standard cells  1 - 28 , is achieved by multiblock robot articulated arms  9 ′- 14 . The submerged sea ground driving multiblock robot system standard cell  1 - 28  is laterally docking to a rotation flange plug connection  2 - 2 , for the transition and access to the separate vertical access channel  1 - 25 ′. The outer contour of all multiblock robot system standard cells  1 - 28 , operating over water and under water, being guided by the separate vertical access channels  1 - 25 ′, as also of the multiblock robot system standard cells  1 - 28 , being submerged but being fully self operating with its own driving equipment, is nearly similar to each other and to the multiblock robot system standard cell 2   1 - 28 , as shown in FIG. 12 c . The underwater submerged, vertically guided and otherwise selfoperating multiblock robot system standard cells  1 - 28 , are used for geological researchs, under water labs and for the producing of solid, fluid and gaseuos minerals and substances recovering objectives, fishing and further underwater applications. Conceptionally, the installation of multiblock robot total sea complexes is not limited to sea regions, but they are likewise provided for mainland, space and planetary objectives. 
     FIG.  13   
     Multiblock robot swim and submerge capable individual and total complexes, consist of multiblock robot system standard cells  1 - 28 , in accordance with FIG. 12 c , which are equipped with propulsion screw flange plug booster units  9 ′- 54  and rudder flange plug booster units  9 ′- 53 . The overwater driving multiblock robot system standard cells  1 - 28  are optionally individually driven or, to serveral one behind the other, plug connected with its rotation flexible bow and stem flange plug connections  18 - 2 , these being designed, as shown in FIG.  2 . In the case of several plug connected multiblock robot system standard cells  1 - 28  one behind the other, only for the last multiblock robot system standard cell  1 - 28  of the sea-compund is provided a rudder and screw flange plug booster unit  9 ′- 54 ,  9 ′- 53 , for driving and heading the total arrangement. Moreover, multiblock robot system standard cells  1 - 28  are provided on ship carrier flange plug booster units  1 - 34 , individually or several one behind the other, on rotation flange plug connections  2 - 2 , in a corresponding distance to each other. In this case, only the ship carrier flange plug booster unit  1 - 34  is provided with propulsion screw and rudder flange plug booster units  9 ′- 54 ,  9 ′- 53 . The bow and stem rotation flexible flange plug connections  18 - 2  between each multiblock robot system standard cell  1 - 28 , are not applicated, but non rotational flange plug connections  2 - 2 ′ are provided, for the transition from one multiblock robot system standard cell  1 - 28  to the other. The horizontal connection is also provided by separately laid, outer horizontal access channels  12 - 1 , which are arranged below or above the multiblock robot system standard cells  1 - 28 . 
     FIG.  14   
     The over water and under water driving multiblock robot individual units and total complexes are provided with telescope access channels  1 - 37 , being plug connected on rotation flange plug connection  2 - 2  bottom positions of the multiblock robot system standard cells  1 - 28 . By means of the intermediate multiblock robot standard part  2 - 1 , a telescope access channel  1 - 37  is rotated up to 360° around the own axis and up to 180° in vertical direction, close under the bottom of the multiblock robot system standard cell  1 - 28 . During the drive to the prospective sea region, the telescope access channel  1 - 37  is retracted and rotated up to the horizontal position, under the bottom of the multiblock robot system standard cell  1 - 28 . For sea ground works, the telescope access channel  1 - 37  is provided with multiblock articulated arms  9 ′- 14 , gripper, excavator and other multiblock robot flange plug booster units  9 ′- 56  for under water and sea ground works, and also with under water cameras  9 ′- 33 , all plug connected to the rotation flange plug connections  2 - 2  at the bottom position of the telescope access channel  1 - 37 . There are moreover provided drill head flange plug booster units  9 ′- 57  for sea ground drills and conveyor means for producing gaseuos, fluid and solid minerals and substances. Furthermore is provided in bottom position an access opening  1 - 24  with sliding door  1 - 24 ′ for the access of divers and under water multiblock robots. Additionally, the telescope access channels  1 - 37  are headed for docking by under water operating multiblock robot system standard cells  1 - 28 . The docking operation and for this the reaching of a transition congruent position, being controlled by means of approximation sensors  9 ′- 21 , provided in head position on rotation flange plug connections  2 - 2  of the multiblock robot system standard cells  1 - 28  and in opposite head position on rotation flange plug connections  2 - 2 , provided at the bottom section of the telescope access channels  1 - 37 . After completion of the docking operation, the multiblock robot system standard cells  1 - 28  are freely vertically moved up and down by its own submerge ability, being vertically guided by the telescope channels  1 - 37  and having steady access to the telescope access channels  1 - 37 . The telescope access channels  1 - 37  are conceptionally designed as the separate vertical access channels  1 - 25 ′, but in correspondence with the requirements, they have internal continuous conveyor means, for the continuous conveyance of gaseous, fluid and solid minerals and substances from the sea ground to the sea surface and to the multiblock robot individual and total sea complexes. The entire equipment of the over water driving multiblock robot system standard cells  1 - 28 , with telescope channels  1 - 37  and with the corresponding accessory flange plug booster units, is also provided, supported and guided for directly under water and in deep sea submerged operating multiblock robot system standard cells  1 - 28 . For the individual operation of divers, the oxygen flange plug booster unit  1 - 12  is lowered from a laterally arranged, vertical access channel  1 - 25 , of the multiblock robot system standard cell  1 - 28 . 
     FIGS.  15 ,  16   
     The aviation capable multiblock robot system standard cells  1 - 28  are optionally provided with propulsion flange plug booster units  9 ′- 58  and vertical rotor flange plug booster units  9 ′- 59 , which are laterally and centrally in head position, plug connected on rotation flange plug connections  2 - 2 , of the multiblock robot system standard cells  1 - 28 . Additionally, there are provided optional folding tail and cockpit flange plug booster units  9 ′- 62 ,  9 ′- 61 , plug connected on the back and front rotation flange plug connection  2 - 2 . The folding is operated by means of multiblock robot articulated arms  9 ′- 14  and multiblock robot standard parts  2 - 1 . The folding tail and cockpit flange plug booster units  9 ′- 62 ,  9 ′- 61  have each one landing operative multiblock robot floor ground drive unit  9 ′- 9  and one small dimensioned adjustment floor ground drive unit  9 ′- 9  at the endpoint of the under side. Each of the folding tail and cockpit flange plug booster units  9 ′- 62 ,  9 ′- 61  have two foldable outside flange plug booster units  9 ′- 60 ′, connected to each other by means of the multiblock robot articulated arms  19 ′- 14 . For the aviation completion, the tail and cockpit flange plug booster units  9 ′ 62 ,  9 ′- 61  are pushed together, in direction of the central rotation flange plug connections  2 - 2 . The positioning is controlled by the approximations sensors  9 ′- 21  being opposite to each other on the rotation flange plug connections  2 - 2 , which are provided on the tail and cockpit flange plug booster units  9 ′- 62 , 9 ′- 61  and horizontally and vertically on the multiblock robot system standard cells  1 - 28 . If the right adjusted position is reached, the multiblock robot articulated arms  19 ′- 14  close the two foldable outside flange plug booster units  9 ′- 40 , and all plug units  2 - 3  and plug sleeves  2 - 3 ′ of the tail and cockpit flange plug booster units  9 ′- 62 ,  9 ′- 61  are engaged to the counterpart plug units  2 - 3  and plug sleeves  2 - 3 ′ of the rotation flange plug connections  2 - 2  of the multiblock robot system standard cells  1 - 28 . After the plug connection of the tail and cockpit flange plug booster units  9 ′ 62 , 9 ′- 61  and the engagement of the plug units  2 - 3  and plug sleeves  2 - 3 ′ of the rotation flange plug connections  2 - 2 , are all access and supply channels  12 - 1 ,  10 - 1 ′,  9 - 40  with its integrated current communication and fluid lines  10 - 1 , in accordance with FIG. 1,  1 , immediately closed and to each other interconnected. The adjustment floor ground drive unit  9 ′- 9  is only used for the plug connection operation of the tail and cockpit flange plug booster units  9 ′- 62 , 9 ′- 61  with the multiblock robot system standard cells  1 - 28  and is folded to the inside, when closing the flange plug booster units  9 ′- 40 , so that only the front and back sided arranged multiblock robot floor ground drive units  9 ′- 9  are finally effective as landing operative ground floor drive units  9 ′- 9  for the completed multiblock robot aviation unit. The tail flange plug booster units  9 ′- 40  are provided with side rudder flange plug booster units  9 ′- 62  for horizontal flight maneuverings and with additional propulsion flange plug booster units  9 ′- 58 , which are plug connected to the rear position of the tail flange plug booster units  9 ′- 40 . The cockpit flange plug booster units  9 ′- 61  have multiblock robot control and board computer flange plug booster units, cockpit seat flange plug booster units and further flange plug booster units, needed for carrying out flight operations. The vertical rotor flange plug booster units  9 ′- 59  have an optional number of three or four rotor blades, and are plug connected on the central rotation flange plug connection  2 - 2 , so that the central, lockable vertical access channel  1 - 25 , with its sheathing supply channels  10 - 1 ′, is not restricted in its function and transition to and from the outside out of the top position, after the plug connection of vertical rotor flange plug units  9 ′- 59 . The multiblock robot aviation units are not only capable to takeoff and land vertically by means of the plug connection with the vertical rotor flange plug booster units  9 ′- 59 , but also by plug connection with propulsion flange plug booster units  9 ′- 58  on the outsides of the multiblock robot system standard cells  1 - 28 . There, being freely rotatable around 360° and thus having horizontal and additionally vertical propulsion functions. In correspondance with the flight effective requirements, the multiblock robot aviation units are provided without the tail and cockpit flange plug booster units  9 ′- 62 , 9 ′- 61 , only with a cockpit flange plug booster unit  9 ′- 61 , only with a tail flange plug booster units  9 ′- 62 , only with lateral propulsion flange plug booster units  9 ′- 58 , only with the vertical rotor flange plug booster unit  9 ′- 59  and the rear sided propulsion flange plug booster unit  9 ′- 58  and, with further optional combinations of the catalog of multiblock robot standard parts, flange plug booster units and system standard cells  1 - 28  to each other. 
     FIG.  17   
     The multiblock robot aviation complex consists of a multiblock robot system standard cell  1 - 28  with a radar flange plug booster unit  9 ′- 3  in ground floor position. Above the multiblock robot system standard cell  1 - 28 , is a retractable platform flange plug booster unit  1 - 26 ′ plug connected and a separate multiblock robot entrance flange plug booster unit  1 - 26 , rotated around 180°, with internal equipment for the objectives of a control tower, as for air traffic controll of vertical takeoff and landing operations of multiblock robot aviation units. The central, separate vertical access channel  1 - 25 ′ is plug connected to a foundation flange plug booster unit  9 ′- 19 , in accordance with the preceding fig., and leads through the several, central rotation flange plug connections  2 - 2 . In head position of the separate access channel  1 - 25 ′ is provided a rotation flange plug connection  2 - 2  with approximation sensors  9 ′- 21  and a hoist flange plug booster unit  1 - 31 . There are moreover provided inside tackle line and hydraulic lift plug booster units  3 - 25  and laterally, lockable rotation flange plug connections  2 - 2  and access openings  1 - 24 . The multiblock robot helicopters and the vertical takeoff and landing capable aviation units, are guided by the signals from the approximation sensors  9 ′- 21  of the rotation flange plug connections  2 - 2  and are self operating vertically and horizontally precise positioned and, with its own propulsion units, are rotated around 90° for the vertical landing, lowered and softly landed on top of the already landed multiblock robot airplane, the multiblock helicopter, or in the case of not yet landed multiblock robot airplane or helicopter, directly on the rotation flange plug connection  2 - 2  of the entrance flange plug booster unit  1 - 26 . For the takeoff and landing operations, the different one above the other landed multiblock robot aviation units, are rotated with its wing flange plug booster units  9 ′- 63 , so that during the takeoff and landing of the multiblock robot aviation units in upper position, the propulsion reflections hit not the multiblock robot aviation units below it. In accordance with the flight requirements, the wing flange plug booster units  9 ′- 63  of the multiblock robot airplanes and helicopters are also optionally provided and plug connected, laterally to the rotation flange plug connections  2 - 2  of the multiblock robot system standard cells  1 - 28 . Than, the propulsion flange plug booster units  9 ′- 58  are plug connected in end position, and additionally above or below of the wing flange plug booster units  9 ′- 63 . Thus, the wing flange plug booster units  9 ′- 63  and all plug connected propulsion flange plug booster units  9 ′- 58  are individually, freely rotatable around 360°, being able to control the flight height movements. In so far, there is an option to control the vertical takeoff and landing by the rotation of the wing flange plug booster units  9 ′- 63  around 90°, together with its plug connected propulsion flange plug booster units  9 ′- 58 , for having the most reduced air resistance during the takeoff operations. For refuel operations, the exchange of materials, persons, multiblock robots, in the air during the flight, the multiblock robot aviation units are self operating positioned one above the others, by means of the approximation sensors  9 ′- 21 . And, by the central, vertical access channels  1 - 25  with the sheathing supply lines  10 - 1 , a temporary rotation flange plug connection  2 - 2  is closed between the multiblock robot aviation units, from the airplane or helicopter to the above docked multiblock airplane or helicopter. 
     FIGS.  18 ,  19 ,  20 ,  21   
     A multiblock robot total space complex consists of the multiblock robot system standard cells  1 - 28  with the laterally, on rotation flange plug connections  2 - 2  plug connected, liftoff rocket flange plug booster units  9 ′- 64  and optionally, above and below plug connected liftoff-space rocket flange plug booster units  9 ′- 64 ′. Moreover, the multiblock robot system standard cells  1 - 28  are provided with plug connectable tail and nose flange plug booster units  9 ′- 60 ′,  9 ′- 61 ′conceptionally in accordance with the tail and cockpit flange plug booster units  9 ′- 62 ,  9 ′- 61  for multiblock robot aviation units, however for the total multiblock robot space complex having the objective to protect against overheating if going through the stratosphere and, being a shield against hits of space particles and radiations. The multiblock robot total space complex does not need a launching ramp. The longer and heavier dimensioned liftoff rocket flange plug booster units  9 ′- 64  are combined plug connected with the smaller and lightweight dimensioned liftoff-space rocket flange plug booster units  9 ′- 64 ′. Or, the multiblock robot system standard cells  1 - 28  are plug connected with internal, in rear position provided liftoff-space rocket flange plug booster units  9 ′- 64 ′ and these are combined with liftoff-space rocket flange plug booster units  9 ′- 64 ′, plug connected laterally, above and also below of the multiblock robot system standard cells  1 - 28 . For the liftoff from the ground, the smaller liftoff-space rocket flange plug booster units  9 ′- 64 ′ are at first fired for a short time, until the heavier liftoff rocket flange plug booster units  9 ′- 64  are lifted free from the ground. Than, these are fired and the liftoff-space rocket flange plug booster units  9 ′- 64 ′ are switched off. After reaching the stratosphere and the orbit, the liftoff rocket flange plug booster units  9 ′- 64  are optionally disconnected and pushed off from its rotation flange plug connections  2 - 2 , whereas at the same time, the liftoff-space rocket flange plug booster units  9 ′- 64 ′ are again fired for the propulsion into space. In accordance with the danger situations and requirements in space, the nose and tail heat, particle and radiation protection flange plug booster units  9 ′- 60 ,  9 ′- 61  are likewise disconnected from its rotation flange plug connections  2 - 2  and pushed off, or they are retained. Extensive multiblock robot total space complexes comprise, in accordance with FIG. 18 b , two one above the other plug connected multiblock robot system standard cells  1 - 28 , always with two laterally plug connected liftoff rocket flange plug booster units  9 ′- 64 , and between each being provided a liftoff-space rocket flange plug booster unit  9 ′- 64 ′. Reaching the aimed space position, through the lateral access channels  12 - 1  and the horizontal access channels  1 - 25  of the multiblock robot system standard cells  1 - 28 , are disembarked and exchanged space pilots, multiblock space robots and space satellites. The multiblock space robots are conceptionally designed, as shown in FIG.  5 . However, they are provided with liftoff-space rocket flange plug booster units  9 ′- 64 ′. Each multiblock robot total space complex is suitable to be applied as a space station but also as a planetary station for other planets. Depending on the total liftoff weight, the multiblock robot total space complexes are also lifted off from separate vertical access channels  1 - 25 ′, sheathed by the supply channels  10 - 1 ′, in accordance with FIGS. 10,  12  and  17 , where the multiblock robot system standard cells  1 - 28  are vertically and horizontally guided during the liftoff operation, by the separate vertical access channels  1 - 25 ′ with its sheathed supply channels  10 - 1 ′. The separate vertical access channels  1 - 25 ′ are dimensioned for the liftoff operations of multiblock robot total space complexes, but also additionally for the takeoff and landing of multiblock robot aircrafts and helicopters. Moreover, equally depending on the total liftoff weight of the multiblock robot total space complexes, they are provided with own vertical rotor flange plug booster unist  9 ′- 59 , and are vertically lifted to great heights of the air space. There, the vertical rotor flange plug booster units  9 ′- 59  are disconnected from its rotation flange plug connections  2 - 2  and pushed off to the earth by a parachute flange plug booster unit  9 ′- 66 , which up to this moment has been covered within the vertical access channels  1 - 25  of the vertical rotor flange plug booster units  9 ′- 59 . Simultaneously, the real liftoff rockets  9 ′- 59  are fired. In space, the multiblock robot total space complexes are self operating positioned by means of the approximation sensors  9 ′- 21 , for docking one above, behind and side by side to each other, for fuel operations and the exchange of persons, materials and multiblock robots. As for all multiblock robot individual systems and total complexes, also for multiblock robot total space complexes, is the compatibility maintained to each other and to all multiblock robot standard parts, flange plug booster units, as also to the multiblock robot system standard cell units  1 - 28  of the whole multiblock robot system catalog, and its ability to be optionally plug connected, combined, disconnected and exchanged to each other.