Patent Publication Number: US-10315303-B2

Title: Modular fabrication table

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     Not applicable 
     REFERENCE TO GOVERNMENT FUNDING SOURCES 
     Not applicable. 
     REFERENCE TO SEQUENCE LISTING 
     Not applicable. 
     BACKGROUND 
     Fields of the Invention 
     The disclosure as detailed herein is in the technical field of prototyping. More specifically, the present disclosure relates to the technical field of manufacturing. Even more specifically, the present disclosure relates to the technical field of modular fabrication tables. 
     Description of Related Art 
     Tables are commonly found in laboratories. They have to be sturdy and multiuse and, therefore, are usually fixed as part of a structure and immobile. Further, laboratory tables often have very heavy-duty countertops using such materials as soapstone. This causes laboratory tables to be difficult to setup in the manner that are needed for specific experiments, as they are fixed into place and are immobile. Further, due to their heavy weight, it is not easy to move laboratory tables into new configurations. 
     Fabricators are people who need to have a wide variety of arrangements and configurations to hold pieces they are assembling. Therefore, tables need to be both mobile but firm and need to accommodate specific spaces in a work area. These tables need to be flat, level, and square and able to hold components of a work piece in particular configurations. Existing tables in fabrication shops are often not adaptable and clamp locations are usually limited to the periphery. Fabricators often need to design configurations around the existing tables that they have, which usually takes a lot of time. Further, different work pieces often require different anchoring strengths for accurate positioning. In addition, safety is a big concern with setting up or working on one or more work pieces. A further consideration for a fabrication table is they often need to have surfaces of different materials that are compatible with the work pieces that are being worked on. 
     They may also need to have means for bolting in both an upwards and downwards perpendicular plane for configuration of work pieces. Further, it may also be desirable to have a means to configure a production or prototype the area to particular needs for particular products. Existing modular fabrication tables are often prohibitively expensive and require specific compatible clamps that must be purchased. In summary, fabrication prototypers often have work spaces that have limited surface area and use tables that are not for the purposes of fabrication. Tables that are used can be immobile or too mobile and, thus, give out under stress. Further, fabrication tables can be out of level, out of square, and have irregular surface structure. The non-adaptability of tables in a fabrication shop often cost money, because setting up configurations is time consuming and requires a great deal of creativity. 
     GENERAL SUMMARY OF THE INVENTION 
     Existing fabrication tables are often immobile, unsafe, and difficult to work with. This invention comprises a modular fabrication table, which is rapidly adaptable to expand over a large surface area, add perpendicular work surfaces, and integrate existing peripheral components that can be purchased at a store. This allows fabrication prototypers to have mobile, sturdy, square, and level tables within which to configure structures for the production of fabrication work pieces. 
     An embodiment of the instant invention allows one to have an N number of units that can interconnect in order to grow the work surface area. Yet another embodiment of the invention allows one to very easily set up an experiment for lab personnel. Yet another embodiment of the invention allows one to move the fabrication table to multiple spots in a lab as needed. Yet another embodiment of the invention allows one to have a variable means for mobility and anchoring for lab experiments. Yet another embodiment of the invention allows one to have a variable size of surface area and volume for assembly and fixturing for fabricators. Yet another embodiment of the invention allows one to have a variable mobility mechanism to be able to adapt to the needs for fixturing of the work pieces. 
     Yet another embodiment of the invention allows one to not have to make adjustments for tables that are not flat. Yet another embodiment of the invention allows one to not to worry about the flatness of the surface for present and future work pieces. Yet another embodiment of the invention allows one to to adjust the level of the table to suit the needs of the fixturing or work pieces. 
     Yet another embodiment of the invention allows one to not worry about the squareness of the table for work to be performed. Yet another embodiment of the invention allows one to allows one to to be able to hold component pieces of a work piece in particular configurations. Yet another embodiment of the invention allows one to have a low cost adaptable fabrication table. 
     Yet another embodiment of the invention allows fixturing and clamp locations to be configured as needed in the center or interior portions of a table as well as throughout the entire work area. Yet another embodiment of the invention allows one to have only one table that can be used for working on a particular project or projects. 
     Yet another embodiment of the invention allows one to have a strong anchoring substrate based on the design of the modular surface tube. Yet another embodiment of the invention allows one to have a safer working environment. Yet another embodiment of the invention allows one to have a fence or upwards perpendicular plane to attach to the fabrication table and support fixturing. 
     Yet another embodiment of the invention allows one to have an apron to attach to the fabrication table and support fixturing below the surface of the table. Yet another embodiment of the invention allows one to have adaptable materials for a sanitary workspace. Yet another embodiment of the invention allows one to have a means to configure a production or prototyping area to particular needs for assembly or line production. An additional embodiment allows one to use clamps and fixturing devices that are specific to the modular table itself AND accommodate non-specific clamps and devices of various types and brands. 
    
    
     
       DESCRIPTION OF FIGURES 
         FIG. 1  is a perspective view which shows the base and working surface and related components. 
         FIG. 2  is a perspective view which shows the base and related components. 
         FIG. 3  is a perspective view which shows the anchoring frame and related components. 
         FIG. 4  is a perspective view which shows the leveling mechanism of the legs. 
         FIG. 5  is a perspective view which shows the leveling mechanism of the legs. 
         FIG. 6  is a perspective view which shows an adaptable attachable component attached to an MFU and frame edge unit. 
         FIG. 7  is a bottom perspective view which shows an MFU. 
         FIG. 8  is a bottom perspective view which shows an MFU with an attachment mechanisms to one or more adaptable attachable components. 
         FIG. 9  is a top perspective view which shows an MFU. 
         FIG. 10  is a end facing perspective view which shows an MFU end. 
         FIG. 11  is a top perspective view which shows a working surface of MSUs on top of a base. 
         FIG. 12  is a bottom perspective view which shows a working surface of MSUs on top of a base. 
         FIG. 13  is a bottom perspective view which shows a working surface of MSUs on top of a base, where inter MSU space is considerable. 
         FIG. 14  is a top perspective view which shows a working surface of MSUs on top of a base, where inter MSU space is considerable. 
         FIG. 15  is a top perspective view which shows a working surface of MSUs on top of a base. 
         FIG. 16  is a side perspective view which shows an MSU. 
         FIG. 17  is a end facing perspective view which shows an MSU end. 
         FIG. 18  is a bottom perspective view which shows an MSU. 
         FIG. 19  is a perspective view which shows multiple vertical and horizontal work surfaces. 
         FIG. 20  is a perspective view which shows a work surface attached vertical below the plane of the horizontal work surface. 
         FIG. 21  is a end facing perspective view which shows multiple vertical and horizontal work surfaces. 
         FIG. 22  is a side perspective view which shows multiple vertical and horizontal work surfaces. 
         FIG. 23  is a top perspective view which shows multiple integrated horizontal work surfaces with multiple bases. 
         FIG. 24  is a top perspective view which shows multiple integrated horizontal work surfaces with multiple bases. 
         FIG. 25  is a top perspective view which shows multiple integrated horizontal work surfaces with multiple bases. 
         FIG. 26  is a side perspective view which shows a horizontal work surfaces and fence peripheral. 
         FIG. 27  is a perspective view which shows an embodiment where a peripheral is attached to the work surface. 
         FIG. 28  is a perspective view which shows an embodiment where there are horizontal and vertical work surfaces. 
         FIG. 29  is a top perspective view which shows multiple integrated horizontal work surfaces with multiple bases attached with components between bases. 
         FIG. 30  is a side perspective view which shows multiple integrated horizontal work surfaces with multiple bases attached with components between bases. 
         FIG. 31  is a diagram view which shows overall use of the device. 
         FIG. 32  is a diagram view which shows an embodiment of a method to assemble the table. 
         FIG. 33  is a diagram view which shows an embodiment of a method to assemble the work surface. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     One or more different inventions may be described in the present application. Further, for one or more of the inventions described herein, numerous alternative embodiments may be described; it should be appreciated that these are presented for illustrative purposes only and are not limiting of the inventions contained herein or the claims presented herein in any way. One or more of the inventions may be widely applicable to numerous embodiments, as may be readily apparent from the disclosure. In general, embodiments are described in sufficient detail to enable those skilled in the art to practice one or more of the inventions, and it should be appreciated that other embodiments may be utilized and that structural, logical, software, electrical and other changes may be made without departing from the scope of the particular inventions. Accordingly, one skilled in the art will recognize that one or more of the inventions may be practiced with various modifications and alterations. Particular features of one or more of the inventions described herein may be described with reference to one or more particular embodiments or figures that form a part of the present disclosure, and in which are shown, by way of illustration, specific embodiments of one or more of the inventions. It should be appreciated, however, that such features are not limited to usage in the one or more particular embodiments or figures with reference to which they are described. The present disclosure is neither a literal description of all embodiments of one or more of the inventions nor a listing of features of one or more of the inventions that must be present in all embodiments. 
     Headings of sections provided in this patent application and the title of this patent application are for convenience only, and are not to be taken as limiting the disclosure in any way. 
     Devices that are in communication with each other need not be in continuous communication with each other, unless expressly specified otherwise. In addition, devices that are in communication with each other may communicate directly or indirectly through one or more communication means or intermediaries, logical or physical. 
     A description of an embodiment with several components in communication with each other does not imply that all such components are required. To the contrary, a variety of optional components may be described to illustrate a wide variety of possible embodiments of one or more of the inventions and in order to more fully illustrate one or more aspects of the inventions. Similarly, although process steps, method steps, algorithms or the like may be described in a sequential order, such processes, methods and algorithms may generally be configured to work in alternate orders, unless specifically stated to the contrary. In other words, any sequence or order of steps that may be described in this patent application does not, in and of itself, indicate a requirement that the steps be performed in that order. The steps of described processes may be performed in any order practical. Further, some steps may be performed simultaneously despite being described or implied as occurring non-simultaneously (e.g., because one step is described after the other step). Moreover, the illustration of a process by its depiction in a drawing does not imply that the illustrated process is exclusive of other variations and modifications thereto, does not imply that the illustrated process or any of its steps are necessary to one or more of the invention(s), and does not imply that the illustrated process is preferred. Also, steps are generally described once per embodiment, but this does not mean they must occur once, or that they may only occur once each time a process, method, or algorithm is carried out or executed. Some steps may be omitted in some embodiments or some occurrences, or some steps may be executed more than once in a given embodiment or occurrence. 
     When a single device or article is described herein, it will be readily apparent that more than one device or article may be used in place of a single device or article. Similarly, where more than one device or article is described herein, it will be readily apparent that a single device or article may be used in place of the more than one device or article. 
     The functionality or the features of a device may be alternatively embodied by one or more other devices that are not explicitly described as having such functionality or features. Thus, other embodiments of one or more of the inventions need not include the device itself. 
     Referring now to  FIG. 1 , which shows the base and working surface and related components. Working surface  100  (as in  FIG. 1 ) comprises the flat surface that a user interacts with made up of one or more MSU  101 . Working surface  100  preferably comprises one or more MSU  101 , one or more inter-MSU space  104 , and finally fixture aperture grid  105 . MSU  101  (as in  FIG. 1 ) comprises a modular unit of a specific material that becomes one or more surfaces of the fabrication table. The (MSU  101 ) is an acronym which stands for ‘modular surface unit’. MSU  101  is mainly thought to be composed of steel, however other embodiments may be composed of any of the following: stainless steel, aluminum, wood, plastic, polymers, rubber polymers, composites with different coatings, or any suitable metal. MSU  101  is preferably shaped like a capped tube, however, it is thought that in alternative embodiments that it may also be shaped like a solid block, an open tube, or a hollow and capped block. In some embodiments, MSU  101  has a preferred width of 3.5 inches but in other embodiments, may range from a minimum of 2 inches to a maximum width of 12 inches. In general, the maximum value of the width can be calculated by the overall needs of the structure of project. 
     In some embodiments, MSU  101  has a preferred height of 3.5 inches but in other embodiments, may range from a minimum of 2 inches to a maximum height of 12 inches. In general, the maximum height value can be calculated by the overall needs of the structure of project. In some embodiments, MSU  101  has a preferred length of 60 inches but in other embodiments, may range from a minimum of 15 inches to a maximum length of 240 inches. In general, the preferred length value can be calculated by the overall needs of the structure of project. In some embodiments, MSU  101  has a preferred weight of 40 lbs but in other embodiments, may range from a minimum of 1 lbs to a maximum weight of 150 lbs. The purpose of the preferred weight value is to have a weight that is manageable by one person. In general, the preferred weight value can be calculated by the overall needs of the structure of project. 
     In some embodiments, MSU  101  has a preferred wall thickness of 3/16 inches but in other embodiments, may range from a minimum of ⅛ inches to a maximum wall thickness of 1 inches. MSU  101  preferably comprises at least an MSU end  102 , MSU top surface  103 , MSU side surface  1103 , MSU bottom surface  1800 , MSU interior aperture, fixturing aperture  1104 , one or more fixturing aperture distance  1105 , and finally one or more corner radial curve  1106 . MSU  101  has a couple alternative embodiments herein termed the ‘‘four side’ embodiment’ embodiment and the ‘solid’ embodiment. The ‘‘four side’ embodiment’ embodiment comprises an MSU where there are no specific oriented sides and attachment to peripherals and MFU can still occur. The ‘solid’ embodiment comprises an MSU where there is no interior aperture. 
     Inter-MSU space  104  (as in  FIG. 1 ) comprises the space between two parallel adjacent MSU  101 , which is taken into account when used to calculate the dimensions of the squares of fixture aperture grid  105  along with fixturing aperture distance  1105 . In some embodiments, inter-MSU space  104  has a preferred width of 1.5 inches but in other embodiments, may range from a minimum of 0.5 inches to a maximum width of 12 inches. In general, the preferred width value can be calculated by the value that is large enough to accept clamps and attachments through working surface  100 . It can further be calculated by the value that allows one to create a grid of fixture apertures from two or more adjacent MSU when attached to the base. 
     Fixture aperture grid  105  (as in  FIG. 1 ) comprises the grid that is created as a function of MSU width and inter-MSU space  104  that creates a grid of fixturing apertures  1104  so that components or fixturing peripheral  2700  can be reused in different places. MSU end  102  (as in  FIG. 1 ) comprises an apical region on the end of MSU  101 . One goal of MSU end  102  is to allow the fixturing of vertical MSU  101  and potentially other components, such as peripherals. MSU end  102  preferably comprises one or more MSU end cap  1100  and one or more MSU end angle  1101 . MSU top surface  103  (as in  FIG. 1 ) comprises the flat top surface of MSU  101  that when combined with other MSU  101  makes the flat work surface. MSU top surface  103  preferably comprises recessed anchoring aperture  1102 . 
     Legs  107  (as in  FIGS. 1 and 4 and 5 ) comprises the physical support for anchoring frame  109 , preferably perpendicular. Legs  107  preferably comprise one or more leveling mechanism  108 . Anchoring frame  109  (as in  FIG. 1 ) comprises a structure that sets the foundation for the squareness of working surface  100 . Anchoring frame  109  preferably comprises frame aperture  200  and one or more frame edge unit  110 . Leveling mechanism  108  (as in  FIGS. 1 and 4 and 5 ) comprises an adjustable mechanism that operably connects to one or more legs  107  that allows a user to adjust the level of one or more working surface  100 . 
     Frame edge unit  110  (as in  FIG. 1 ) comprises a support for an anchoring frame, that in a preferred embodiment, has a count of four and establishes the square of the anchoring frame. Frame edge unit  110  preferably comprises side mounting surface  201 , top mounting surface  202 , and finally interior mounting surface  203 . Frame edge unit  110  has an alternative embodiment herein termed the ‘electrical box’ embodiment. The ‘electrical box’ embodiment comprises an embodiment where one or more electrical boxes or power sources are otherwise affixed to the interior mounting surface  203  of a frame edge unit  110 . Frame edge unit  110  has an additional alternative embodiment herein termed the ‘tool holder’ embodiment. The ‘tool holder’ embodiment comprises an embodiment where one or more apparatuses are configured to attach to the frame edge unit that holds or wields tools. 
     MFU  112  (as in  FIG. 1 ) comprises a modular unit that establishes the foundation for the work surface  100 . The (MFU  112 ) is an acronym which stands for ‘modular framing unit’. MFU  112  is mainly thought to be composed of steel, however other embodiments may be composed of any of the following: stainless steel, aluminum, plastic, wood, polymers, rubber polymers, composites with different coatings, or any suitable metal. MFU  112  is preferably shaped like a capped tube, however, it is thought that in alternative embodiments that it may also be shaped like a solid block, an open tube, or a hollow and capped block. In some embodiments, MFU  112  has a preferred width of 3.5 inches but in other embodiments, may range from a minimum of 2 inches to a maximum width of 12 inches. In general, the maximum width value can be calculated by the overall needs of the structure of project. 
     In some embodiments, MFU  112  has a preferred height of 3.5 inches but in other embodiments, may range from a minimum of 2 inches to a maximum height of 12 inches. In general, the maximum height value can be calculated by the overall needs of the structure of project. In some embodiments, MFU  112  has a preferred length of 60 inches but in other embodiments, may range from a minimum of 15 inches to a maximum length of 240 inches. In general, the preferred length value can be calculated by the overall needs of the structure of project. 
     In some embodiments, MFU  112  has a preferred weight of 40 lbs but in other embodiments, may range from a minimum of 1 lbs to a maximum weight of 150 lbs. The purpose of the preferred weight value is to have a weight that is manageable by one person. In general, the preferred value can be calculated by the overall needs of the structure of project. In general, the maximum weight value can be calculated by the overall needs of the structure of project. In general, the minimum value can be calculated by the overall needs of the structure of project. 
     In some embodiments, MFU  112  has a preferred wall thickness of 3/16 inches but in other embodiments, may range from a minimum of ⅛ inches to a maximum wall thickness of 1 inches. MFU  112  preferably comprises at least an MFU end  204 , MFU top surface  205 , at least one MFU side surface  206 , MFU bottom surface  701 , one or more MSU attachment aperture  900 , and preferably MFU interior aperture (the central interior aperture of the hollow MFU  112  (in a preferred embodiment)). MFU  112  has an alternative embodiment herein termed the ‘fixture aperture containing’ embodiment. The ‘fixture aperture containing’ embodiment comprises an embodiment, where the MFU may contain one or more fixturing aperture for one or more fixturing peripheral. 
     Inter-MFU space  113  allows for the consideration of: the less space (or the more MFU) allows more unit increments of distance for MSUs to be arranged for particular patterns and/or interaction with other fabrication tables. The inter-MFU space  113  allows the expansion of working surface  100  beyond the original dimensions, for one or more fabrication tables to interact with one another. In a preferred embodiment, inter-MFU space  113  has a preferred width of 20 inches but in other embodiments, any quantity of unit increments of distance for MSUs to be arranged for particular patterns and/or interaction with other fabrication tables may suffice. 
     Anchoring surface  111  (as in  FIG. 1 ) comprises the combination of one or more MFU  112  that establishes a foundation for the work surface  100 . Anchoring surface  111  preferably comprises one or more MFU  112  and one or more inter-MFU space  113 . Base  106  (as in  FIG. 1 ) comprises the support for the work surface  100  that may be configured for modularity and establish a level planes for a user. Base  106  preferably comprises one or ore legs  107 , anchoring frame  109 , one or more adaptable attachment components  300 , and finally anchoring surface  111 . Base  106  has an alternative embodiment herein termed the ‘scissors style’ embodiment. The ‘scissors style’ embodiment comprises an embodiment that has one or mechanisms for adjusting the work surface height via a scissors mechanism. 
     Referring now to  FIG. 2 , which shows the base and related components. Frame aperture  200  (as in  FIG. 2 ) comprises an aperture of anchoring frame  109  that allows the anchoring frame to have structural integrity but be light weight. In some embodiments, it is thought that if frame aperture  200  is absent then a solid sheet may suffice. Side mounting surface  201  (as in  FIG. 2 ) comprises the side of frame edge unit  110  that in some embodiments allows connection to other side mounting surface  201  or adaptable attachment components  300 . Top mounting surface  202  (as in  FIG. 2 ) comprises the top of frame edge unit  110  that preferably interacts with adaptable attachment components  300 . Interior mounting surface  203  (as in  FIG. 2 ) comprises the underside or interior of frame edge unit  110  that preferably interacts and affixes one or more adaptable attachment components  300 . MFU end  204  (as in  FIG. 2 ) comprises an apical region on the end of MFU  112 . MFU end  204  preferably comprises the one or more MFU angled edge and one or more MFU end cap  700 . MSU top surface  207  comprises the flat top surface of the MSU that when combined with other MSU makes the flat work surface. The MSU top surface  207  preferably comprises the recessed anchoring aperture  1102 . MFU side surface  206  (as in  FIG. 2 ) comprises the perpindicular surface to MFU top surface  205 . 
     Referring now to  FIG. 3 , which shows the anchoring frame and related components. Adaptable attachment components  300  (as in  FIG. 3 ) comprises a mechanism to attach the anchor frame to one or more MFU  112  or another portion of another base  106 . Adaptable attachment components  300  preferably comprises separator rod  600  and micro adjustment leveling mechanism  601 . 
     Referring now to  FIG. 6 , which shows an adaptable attachable component attached to an MFU and frame edge unit. Seperator rod  600  (as in  FIG. 6 ) comprises a mechanism for attaching one surface to another that interacts with one or more micro adjustment leveling mechanism  601  that is strong enough support one or more work pieces plus work surfaces. Micro adjustment leveling mechanism  601  (as in  FIG. 6 ) comprises a means for attaching frame edge unit  110  to another component while providing a means for changing distances between them via interaction with seperator rod  600 . In some embodiments, it is thought that an example of micro adjustment leveling mechanism  601  could be nuts and bolts or perhaps adjustable clamps and the like. 
     Referring now to  FIG. 7 , which shows an MFU. MFU end cap  700  functions to both 1) support the MFU during stress and to 2) allow attachment for fixtures. MFU end cap  700  preferably comprises one or more MFU monitoring holes and one or more MFU center fixturing hole. MFU bottom surface  701  (as in  FIG. 7 ) comprises the MFU surface that faces towards anchoring frame  109 . 
     Referring now to  FIG. 8 , which shows an MFU with an attachment mechanisms to one or more adaptable attachable components. In some embodiments, MFU angled edge  800  has a preferred angle of 45 degrees but in other embodiments, may range from a minimum of 15 degrees to a maximum angle of 90 degrees. MFU angled edge  800  functions to both 1) prevent a user of the table from catching their clothes or body while working and to 2) provide additional clearance for work being done in the area. In some embodiments, it is thought that if MFU angled edge  800  is absent then can be done without the angled edge, though in some embodiments, is less preferable. In some embodiments, MFU bottom attachment mechanism  801  may be used to attach one or more MFU to one or more adaptable attachable components. 
     Referring now to  FIGS. 9 and 10 , which shows an MFU. In some embodiments, MFU monitoring holes  900  has a preferred diameter of 0.375 inches but in other embodiments, may range from a minimum of 0.125 inches to a maximum diameter of 1 inches. In general, the preferred diameter value can be calculated by that that is the same as the wall thickness of the MFU. In general, the maximum diameter value can be calculated by that that prevents interface with the structural components. MFU monitoring holes  900  has many purposes which are as follows: First, the purpose of MFU monitoring holes  900  is to allow drainage. Next, it serves to clean out materials that have fallen through. Lastly, MFU monitoring holes  900  serves to run wires through for peripherals or other purposes. 
     In some embodiments, it is thought that if MFU monitoring holes  900  is absent then one may have MFU  112  that is still functional. In some embodiments, MFU center fixturing hole  901  has a preferred diameter of 0.375 inches but in other embodiments, may range from a minimum of 0.125 inches to a maximum diameter of 1 inches. In general, the preferred value can be calculated by that that is the same as the wall thickness of the MFU. In general, the maximum thickness value can be calculated that that prevents interference with the structural components. MSU attachment aperture  902  allows the MFU to attach to one more MSU  101 . 
     Referring now to  FIGS. 11, 12, 13, 14, 15 and 16 , which shows a working surface of MSUs on top of a base. MSU end cap  1100  functions to both 1) support the tube during stress and to 2) allow attachment for fixtures. MSU end cap  1100  is mainly thought to be composed of steel, however other embodiments may be composed of any of the following: stainless steel, aluminum, plastic, polymers, rubber polymers, composites with different coatings, or any suitable metal. In some embodiments, MSU end cap  1100  has a preferred thickness of 3/16 inches but in other embodiments, may range from a minimum of ⅛ inches to a maximum thickness of 1 inches. In general, the preferred value can be calculated by having the same as the wall thickness of the MSU. 
     MSU end cap  1100  functions to both 1) support the tube during stress and to 2) allow attachment for fixtures. In some embodiments, it is thought that if MSU end cap  1100  is absent then there may be no end cap, though it may be less adaptable and less resistant to stress. MSU end cap  1100  preferably comprises a MSU monitoring hole, MSU center fixturing hole  1700 , and finally end cap inset distance  1701 . MSU end cap  1100  has an alternative embodiment herein termed the ‘removable end cap’ embodiment. The ‘removable end cap’ embodiment comprises an embodiment where there the end cap can be removed in order to have access to the interior aperture. 
     MSU end angle  1101  is preferably positioned perpendicular to MSU top surface  103 , perpendicular to MSU side surface  1103 , and perpendicular to MSU bottom surface  1800 . One goal of MSU end angle  1101  is to establish a perpendicular plane for one or more peripheral or MSU  101  to be attached. In a preferred embodiment, MSU end angle  1101  has a preferred angle of 90 degrees but in other embodiments, the angle may vary. 
     Fixturing aperture  1104  (as in  FIG. 11 ) comprises an aperture through one or more sides of MSU  101  that when combined with one or more other fixturing aperture  1104  makes a fixture aperture grid  105  for combining one or more MSU  101  and potentially one or more fixturing peripheral  2700 . One goal of fixturing aperture  1104  is to allow one or more AM or fixturing peripheral  2700  to be attached to MSU  101 . In some embodiments, it is thought that if fixturing aperture  1104  is absent then there are no apertures and the table can be used without peripherals that attach through one or more fixturing aperture  1104 . 
     Recessed anchoring aperture  1102  (as in  FIG. 11 ) comprises a mechanism for threading an AM through MSU top surface  103  to the bottom surface in order to maintain a flat work surface  100 . One goal of recessed anchoring aperture  1102  is to allow threading of an AM in order to attach one or more MSU or MFU to one another. Fixturing aperture distance  1105  (as in  FIG. 11 ) comprises the distance between two adjacent fixturing aperture  1104  on the same surface of MSU  101 . 
     In some embodiments, fixturing aperture distance  1105  has a preferred length of 5 inches but in other embodiments, may range from a minimum of 0.5 inches to a maximum length of 24 inches. In general, the preferred length value can be calculated by the size of fixture aperture grid  105  that one wants to create. MSU side surface  1103  (as in  FIG. 11 ) comprises the perpindicular surface to MSU top surface  103  adjoined by corner radial curve  1106 . Corner radial curve  1106  (as in  FIG. 11 ) comprises the smoothed edge between adjacent surface of MSU  101 . Corner radial curve  1106  functions to both 1) allow one to slide in peripherals more easily and to 2) allows one to carry the MSU more easily. In some embodiments, it is thought that if corner radial curve  1106  is absent then the corners may be at 90 degrees. 
     Referring now to  FIG. 17 , which shows an MSU end. The MSU monitoring hole  1702  has many purposes which are as follows: First, the purpose of the MSU monitoring hole  1702  is to allow drainage. Next, it serves to clean out materials that have fallen through. Lastly, the MSU monitoring hole  1702  serves to run wires through for peripherals or other purposes. In some embodiments, it is thought that if the MSU monitoring hole  1702  is absent then then one may have an MSU that is still functional. In a preferred embodiment, MSU monitoring hole  1702  has a preferred diameter of 0.5 inches but in other embodiments, the diameter may have a maximum value of 1 inches. In general, the preferred diameter value can be calculated by the same value as the wall thickness of the MSU. In general, the maximum diameter value can be calculated by the diameter value that does not to interfere with the structural components. 
     The MSU center fixturing hole  1700  allows attachment to other MSU  101  and/or peripherals. In a preferred embodiment, MSU center fixturing hole  1700  has a preferred diameter of 0.5 inches but in other embodiments, the diameter may have a maximum value of 1 inches. In general, the preferred diameter value can be calculated by the same value as the wall thickness of the MSU. In general, the maximum diameter value can be calculated by the diameter value that does not to interfere with the structural components. One goal of end cap inset distance  1701  is to allow one to leave hardware attached to the end cap and not have it interact with a user. In some embodiments, it is thought that if end cap inset distance  1701  is absent then there may be no inset distance. End cap inset distance  1701  has a preferred depth of 5/16 inches but in other embodiments, the diameter may have a maximum value of 3 inches. 
     Referring now to  FIG. 18, 19, 20, 21, 22, 23, 24, 25, 26  which shows an MSUs and works surfaces in various configurations. MSU bottom surface  1800  (as in  FIG. 18 ) comprises the surface that faces towards anchoring surface  111  which contains the hole through which one or more AM is used to attach MSU  101  via recessed anchoring aperture  1102  from the top surface. 
     Referring now to  FIG. 27, 28, 29   30  which shows a peripheral attached to a work surface and various work surface configurations. Fixturing peripheral  2700  (as in  FIG. 27 ) comprises a component that is used for fixturing that operably attaches to MSU  101 , or in some embodiments additionally one or more MFU  112 . In some embodiments, it is thought that examples of fixturing peripheral  2700  may include: clamps, ratchet straps, threaded hardware, or set up kits. Fixturing peripheral  2700  has multiple alternative embodiments herein termed the ‘diagonal accommodating’ embodiment, the ‘fence’ peripheral embodiment, the ‘plate’ peripheral embodiment, and the ‘clamp’ peripheral embodiment. 
     The ‘diagonal accommodating’ embodiment comprises an embodiment that accommodates the diagonal threaded distance which may be specific to peripherals added to the table. The ‘fence’ peripheral embodiment comprises a peripheral that creates a fence like structure surrounding the work surface  100 . the ‘plate’ peripheral embodiment comprises a peripheral that lays a plate down over some portion of the work surface  100 . and the ‘clamp’ peripheral embodiment comprises a peripheral that clamps to one or more portions of the work surface  100 . 
     Referring now to  FIG. 31 , overall, a preferred embodiment of the invention is used as follows: First, a person assembles a fabrication table (Step  3101 ). This is further detailed below in (Step  3201 -Step  3205 ). Now referring to  FIG. 32 , first, a person lays an anchoring frame  109  and legs on the ground (Step  3201 ). Next, a person attaches the leveling feet to legs  107  (Step  3202 ). Next, a person attaches one or adaptable attachment components  300  to anchoring frame  109  (Step  3203 ). Next, a person would attach one or more adaptable attachment components  300  to anchoring frame  109  (Step  3204 ). Next, a person assembles the work surface (Step  3205 ). This is further detailed below in (Step  3301 -Step  3303 ). 
     Now referring to  FIG. 33 , in order to assemble the work surface, a person would attach one or more MFU  112  to adaptable attachment components  300  in order to create anchoring surface  111  for working surface  100  comprising one or MSU  101  (Step  3301 ). Next, a person would level the anchoring surface  111  by adjusting one or more adaptable attachment components  300  until anchoring surface  111  is level and flat (Step  3302 ). Next, a person would attach one or more MSU  101  to anchoring surface  111  until the working surface is complete (Step  3303 ). 
     Referring back to  FIG. 31 , after assembly, a person uses the fabrication table (Step  3102 ). If a person wants to have a larger work surface  100  (Step  3103 ), then, one or more MSU  101  can be expanded out to the side by reconfiguring the attachment to the MFU (Step  3104 ). If a person wants to have a larger work surface  100  and connect to one or more fabrication table (Step  3105 ), then, one or more MSU  101  can be expanded out to the side by reconfiguring the attachment to the and attached to MFU  112  of another table (Step  3106 ). If one attaches a peripheral to the work surface  100  (Step  3107 ) and if they add a clamp (Step  3108 ), then, one may insert the clamp through inter-MSU space  104  and attach the clamp and peripheral (Step  3109 ). If one attaches a peripheral to the work surface  100  (Step  3107 ) and then adds a designed peripheral (Step  3110 ) then one may attach the designed peripheral via one or more fixturing aperture  1104  (Step  3111 ). 
     The invention has some elements that are commonly known and other terms defined as specific to this specification. These include: fabricator, AM, work piece, and finally apron. However their use and relationships to the novel components and steps of the invention render them applicable herein. In order to preface the roles they play in the specification, they are subsequently explained here. 
     A fabricator comprises a user of a modular fabrication table that requires one or more configurable adaptations during the course of fabrication for one or more work piece. In some embodiments, examples of a fabricator may include: welders, engineers, inventors, hobbyists, or machine shop patrons. AM (anchoring mechanism) comprises a user of a the modular fabrication table that requires one or more configurable adaptations during the course of fabrication for one or more pieces. In some embodiments, an example of AM could be clamps, screws or bolts and the like. A work piece comprises one or more physical components that is configured to be positioned relative to the fabrication table and to have work being done on it.