Abstract:
A die and a stationary member of resilient gas permeable composition are adapted to receive between them a three-dimensional honeycomb core article. The die includes an array of elongated mutually parallel translating pins, each terminating at a tip end and arranged in a matrix for longitudinal movement between retracted and extended positions. The stationary member includes a receiving surface facing and laterally coextensive with the tip ends of the translating pins. The tip ends are engageable with first end surface of the article, the receiveing surface of the stationary member being engageable with a second end surface of the article. The die includes a housing movably mounting the translating pins, drive output shafts drivingly connected with each associated translating pin, a transmission for independent driving controllable interconnection of each translating pin, and a selectively energizable controller interconnecting each transmission to thereby achieve selective rotation of at least one translating pin. Each translating pin may be hollow and have planar sides which prevents its rotation by the restraining action of adjacent translating pins. A controller individually moves the translating pins in a coordinated manner into engagement with the first end surface to thereby impart a desired contour while simultaneously urging the second end surface of the honeycomb core article into engagement with the receiveing surface of the stationary member producing a contour substantially similar to the first end surface. Temperature controlled circuitous gas flow may be provided through the translating pins, article and stationary member.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates generally to forming of honeycomb core and, more specifically, to computer-controlled tooling capable of providing an adjustable three dimensional surface for forming honeycomb core articles with the capability of applying or directing heated air or gas through the honeycomb core cells as well as providing rapid contour changes. The mechanism of the invention is comprised of a plurality of assembled modules which act in concert with one another to effect the work operation. 
     2. Description of the Prior Art 
     Forming of honeycomb core is generally limited to the aerospace industry where a large number of honeycomb core details are used to build contoured, strong, highly weight-efficient structures. In the aerospace industry, each aircraft, or spacecraft, requires many pieces of formed honeycomb core, and the number of formed details is large relative to the amount of planes produced for a given year. A process that can quickly and easily adapt to produce small quantities each of many different details therefore is well-suited to the aerospace industry. Similarly, other aerospace-related components which utilize hot-forming techniques or presses are candidates for the apparatus and method described herein. Within the aerospace industry, matched-die forming tools may be used to fabricate sheet metal and thermoplastic parts. Of the two, thermoplastic sheets can be contour-formed using the described invention if the forming temperatures are within the thermal limit of the tools&#39; design. Thin gage aluminum sheet metal details could also be formed using this process, although the quality of the resulting parts may not be as high as with present processes. 
     Other industries in addition to the aerospace industry that need to hold, form, or inspect contoured components can benefit from the described discrete modular approach as well. The modular approach can also be used to translate a series of sensors for rapidly digitizing the surface(s) of a contoured part or component by replacing the pin tips with tips specially-configured to hold sensors or other devices. The digitized data can be directly stored in computer memory for a three-dimensional surface description which can be used by a computer-graphic or numerical control software application. Modular construction adds the ability to isolate and rapidly replace malfunctioning elements by replacing entire modules with spare, off-the-shelf modules. Further repairs can then be implemented off-line. This minimizes down time, and replacement cost. The ability to reconfigure an entire assembly of modules by adding or subtracting modules gives a high degree of versatility from which other forming processes might also benefit. 
     A pair of patents can be said to be generally representative of the present state of the art of forming complex metal shapes. A first instance is U.S. Pat. No. 4,212,188 to Pinson which discloses a plurality of longitudinally and laterally spaced and opposed die members in a matrix array for engaging and forming a sheet metal article interposed between them. Another instance is U.S. Pat. No. 5,546,784 to Haas et al. which discloses a computer controlled self adjusting sheet metal forming die which can provide rapid contour changes and comprises a computer control device which sends appropriately timed signals to translate each contour element so that a three dimension surface is formed by a discrete matrix of individual pins which press the sheet metal against a forming surface. These inventions, however, are directed to the forming of sheet metal, and do not provide for self-heating. In order to form honeycomb core, new and non-obvious methods and hardware are required. 
     It was with knowledge of the foregoing state of the technology that the present invention has been conceived and is now reduced to practice. 
     SUMMARY OF THE INVENTION 
     According to the invention, a die and a stationary member of resilient gas permeable composition are adapted to receive between them a three-dimensional honeycomb core article. The die includes an array of elongated mutually parallel translating pins, each terminating at a tip end and arranged in a matrix for longitudinal movement between retracted and extended positions. The stationary member includes a receiving surface facing and laterally coextensive with the tip ends of the translating pins. The tip ends are engageable with a first end surface of the article, the receiving surface of the stationary member being engageable with a second end surface of the article. The die includes a housing movably mounting the translating pins, drive output shafts drivingly connected with each associated translating pin, a transmission for independent driving controllable interconnection of each translating pin, and a selectively energizable controller interconnecting each transmission to thereby achieve selective rotation of at least one translating pin. Each translating pin may be hollow and have planar sides which prevents its rotation by the restraining action of adjacent translating pins. A controller individually moves the translating pins in a coordinated manner into engagement with the first end surface to thereby impart a desired contour while simultaneously urging the second end surface of the honeycomb core article into engagement with the receiving surface of the stationary member producing a contour substantially similar to the first end surface. Temperature controlled circuitous gas flow may be provided through the translating pins, article, and stationary member. 
     The present invention details a single-die reconfigirable approach to forming honeycomb core using a modularized, computer-controlled forming die. The forming die utilizes an array of pins or members which translate to form a three-dimensional male or female external surface. The adjustable form die is configured so that hot air is blown through (or between) the discrete pins and through (or into) the cells of the honeycomb core to be formed. The opposite face of the honeycomb core is contacted by porous material to facilitate the flow of hot air or gas through the cells of the honeycomb core. Conformable material, material which the core cells can penetrate without cell-wall damage, or a fluid-filled bladder react the forming forces received by the honeycomb core. The described invention allows the forming sequence and core deformation to be controlled using press forming techniques in combination with partial and/or complete translation of the translating pills. 
     The present invention provides numerous advantages over the prior art including: 
     greater versatility: contour changes are made by recalling files from computer memory; 
     adaptability to changes: stored data can be “tweaked” as needed by changing pin translational data; 
     lower space requirements: no extra dies need to be stored; 
     greater production output; 
     less down time for contour changes; and 
     lower overall tooling cost which results from using the described adjustable, discrete heated forming process compared to presently-used fixed-die forming systems when a variety of core shapes must be formed by the same forming machine or system. 
     The process described herein is also inherently safer to the honeycomb core and to personnel since groups of pins can be used for intermediate core clamping to control local strains, and heavy fixed contour dies do not have to be changed with each different core shape needed. 
     When forming a wide-enough variety of honeycomb core shapes that it is advantageous to use a discrete, adjustable form die method over the typical heated core-and-fixed-die method, a modular approach to building larger form dies can offer a lower overall system cost than a non-modular approach. When many modules are assembled in a “building block” approach, lower overall cost is achieved by simplifying wiring, assembly, and machining operations. Inherently lower overall risk is also associated with modulalization because this approach reduces the magnitude of errors which cause scrap when creating larger-scale tools. Lower risk in this case translates to lower overall cost. A more consistent and accurately formed core contour can also result from the better temperature control and method of applying and removing heat as needed, and not before. 
     Easier servicing, component replacement, and less down time result when using the modular “building block” approach described herein. Individual modules utilize quick-disconnect electrical plugs, and rapid cross shaft gearing connections so that module replacement can be accomplished with minimum down time. Individual module repair and/or service can then take place off-line. 
     Still greater versatility can be achieved by inexpensively allowing overall tool plan form size changes. The overall plan form (length and width) dimensions of the active forminig area can be changed when using the modular “building block” units to create adjustable form tools. Modules can easily be added or subtracted within the limitations allowed by the overall form tool base plates. The base plates can have printed circuitry, electrical connectors, pre-installed wiring, and/or bus bars for motor power, logic, and communication between modules and between modules and computer(s), all using common parts to lower assembly time and cost. 
     Framing members, if used, around the die assembly may have to be changed, but their cost would be low compared to replacement of an entire form tool of larger plan form, that is, overall length and width. 
     This invention can also claim all of the advantages of adjustable tooling. Many fixed-contour dies can be replaced by the adjustable dies described herein. This represents a significant tooling savings as well as savings in storage space, handling, repair, maintenance and rework of fixed dies. 
     Further, the invention described herein can be used for room temperature honeycomb core forming of aluminum honeycomb core, for example, as well as hot forming of Nomex™, graphite, fiberglass, and other nonmetallic honeycomb. The described hardware can also be used to retrofit old fixed-die presses. 
     Other and further features, advantages, and benefits of the invention will become apparent in the following description taken in conjunction with the following drawings. It is to be understood that the foregoing general description and the following detailed description are exemplary and explanatory but are not to be restrictive of the invention. The accompanying drawings which are incorporated in and constitute a part of this invention, illustrate one of the embodiments of the invention, and together with the description, serve to explain the principles of the invention in general terms. Like numerals refer to like parts throughout the disclosure. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is an elevation view of apparatus embodying the invention with certain parts broken away and shown in section for clarity; 
     FIG. 2 is an exploded perspective view of the apparatus illustrated in FIG. 1; 
     FIG. 3 is a detail elevation view of a translating pin for use with the apparatus of FIGS. 1 and 2 of the type that allows hot air (or gas) to flow through the pin and be diffused into the cells of honeycomb core; 
     FIG. 3A is a cross section view taken generally along line  3 A— 3 A in FIG. 3; 
     FIG. 3B is a top plan view of the translating pin illustrated in FIG. 3; 
     FIG. 3C is a cross section view taken generally along line  3 C— 3 C in FIG. 3; 
     FIG. 4 is a detail elevation view of a modified translating pin, also for use with the apparatus of FIGS. 1 and 2, of the type that allows hot air (or gas) to flow outside of the pins through the cells of the honeycomb core via channels created by the external geometry of the pins when grouped together. 
     FIG. 4A is a cross section view taken generally along line  4 A— 4 A in FIG. 4; 
     FIG. 4B is a top plan view illustrating a plurality of the translating pins illustrated in FIG. 4 as an array in side-by-side relationship to depict the channels which are formed by grouping the pins together; 
     FIG. 5 is an exploded perspective view illustrating a single individual-clutch module using two columns by six rows of translating pins; and 
     FIG. 6 is an exploded perspective view illustrating a single individual motor module using two columns by two rows of translating pins. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Numerous embodiments may result from the invention, some of which will be described explicitly, each depending upon the type of pin drive system used (clutch or individual motor) and the type of heat delivery system used (heated air or gas which is directed to flow either through-the pins or between-the-pins). Designations A 1 , A 2 , B 1  and B 2  are herein used to identify the different embodiments. The “A” and “B” designations refer to the type of drive system used. The “A” embodiments use a large motor to drive two columns of pins at a time whereby the lead screw of each pin is connected to the rotating input shafts with a timed electric signal to each clutch. The “B” embodiments use individual motors, each with an in-line gear reducer to directly drive the lead screw of each pin or translating member. The four basic embodiments use modular construction with modules having less than or equal to the number of pins in the upper or lower die. Suffix  1  and  2  refer to the type of hot air or other gas delivery method used. Suffix 1-type pins have holes in the tips and bases so that heated air (or gas) can pass through the hollow pins, and suffix 2-type pins use external channels created by the pins&#39; outer geometry to allow heated air (or gas) to pass between the pins. Still another two embodiments are possible (but not described further herein) by combining suffix  1  and  2  methods for each “A” and “B” drive system. Note that the number of possible embodiments may be doubled by considering that each of the previous six embodiments may be configured with only one module each (preferably for the special case of small dies), effectively eliminating the modular design feature. Details of both drive systems, and each heat delivery type are described and shown within. These basic two drive and two heat delivery methods are combined as indicated by the designations to form the four described embodiments. 
     Modules for large form dies can easily be added or subtracted within the limitations allowed by the overall form tool base plate. The base plate can have printed circuitry, electrical connectors, pre-installed wiring, and bus bars for motor power, logic, and communication between modules and between modules and computer(s). 
     It should be noted that the form die may be attached to the movable ram of a forming press whereby one or more external hydraulic cylinders, or screw jack type devices (not shown), or other translational means may be used to move the discrete-pin, adjustable form die. Or the die could be attached to a fixed platen, with the opposing platen movable. The adjustable form die could also be used, but less desirably, without a forming press, using the translating pins to provide all of the movement. Press-type forming methods are well known in the art. The adaptation of the invention embodiments described herein is dependent upon the particular press, and the adaptation techniques are well known to those of ordinary skill in the art. They are therefore not shown specifically. Hydraulic, pneumatic, screw-type drive presses, or even a fixed rigid structure may therefore be used without changing the spirit of the invention. 
     Two drive system approaches may be used to translate the pins. The first has been described in pending U.S. application Ser. No. 08/921,823 filed Sep. 2, 1997 entitled “Modularized Parallel Drivetrain”, now U.S. Pat. No. 5,954,175 the entire disclosure of which is incorporated herein in its entirety. It uses modules, each comprised of of an input shaft which is geared to two columns of parallel driven shafts. The rotary motion of the parallel driven shafts is converted into translational motion by lead screw and drive nuts which are connected to the pins. A drive gear at the bottom of each parallel driven shaft use right-hand threads or gearing on one column of driven shafts, and left hand threads or gearing on the other column. The Modularized Parallel Drivetrain approach is used to impart translational movement to a large matrix of pins or members in the same direction along many parallel axes simultaneously. The driven shafts are each engaged by individual electromagnetic clutches, and the translational distance required is determined by the duration of a electric signal. Rotary encoders can be connected to the driven shafts to provide feedback if necessary. 
     A second modular drive system approach utilizes individual motors to translate each pin. Each module uses an evenly-spaced array of miniature electric motors with in-line gear reducers and in-line rotary encoders. The individual motors are installed into a housing which also contains circuitry for providing local motor-control logic and inter-module communication. The relatively high output speed and low torque of the small motors is converted via the aforementioned gear reducers to lower rotational speed and higher torque. The output shaft of each individual gear reducer turns a lead screw. The lead screws impart translational movement to pins or members which are grouped together in an array, along many evenly-spaced parallel axes simultaneously. Each pin or translational member can therefore be activated to translate a unique distance individually, in any combination, or all the pins can be translated simultaneously. 
     Computer control of the die assures better results by tailoring the forming process to the individual job&#39;s needs. Algorithms which minimize local core deformations and provide an allowance for “spring back” may be included. This assures that the honeycomb core is formed precisely. Cool air can be introduced at the proper time in the forming cycle to cool the core and/or forming tool as desired. The entire forming sequence and the individual pin movements can be controlled by a Personal Computer (PC), computer work station, or other computer terminal which can preferably support a Graphical User Interface (GUI). The modular design or “building block” approach to discrete tooling not only reduces cost, but facilitates the manufacturing of discrete, reconfigurable tools with respect to repair, maintenance, tolerance build-up, wiring, assembly, and machining processes. 
     Many types of honeycomb core are traditionally hot-formed on a press. Core can be formed on a heated press or oven-heated and formed on a non-heated press, both traditionally using fixed-contour machined or cast dies to impart the needed 3-D contours to the exterior surfaces. Honeycomb core is also roll-formed and contour machined to achieve the desired external contours. Roll forming is generally limited to honeycomb core which has ruled surfaces, and cannot be used effectively to produce formed honeycomb core with contours that change in two orthogonal directions, both normal to the direction of the cells. 
     Since the cost for an adjustable forming die is high relative to the cost for a fixed-contour die, the use of discrete tooling should be considered when very few pieces each of a large variety of core details are needed. The converse is generally also true. Formed honeycomb core is generally used in aerospace application is where each aircraft requires a large variety of honeycomb core shapes. Since the economic viability of replacing a honeycomb core forming system using many fixed-contour dies with an adjustable-die system using a single discrete adjustable-contour die depends upon the number of fixed tools that an adjustable die can replace, aircraft manufacturing is well-suited to the discrete, adjustable-tooling approach. Additionally, the modular design approach allows the plan form of the discrete, adjustable die to be changed inexpensively, if needed. An adjustable form die can be changed rapidly to different length/width combinations by adding or subtracting modules mounted to oversize base plates. 
     Discrete, self-adjusting form tools which blow heated air through or into the cells of the core can form the core very rapidly. Additionally, these tools can adapt to many shapes through the use of data files stored within computer memory. When the desired size of the form die permits (i.e. only small plan form pieces of honeycomb core will be formed), only one module may be necessary to accommodate the needed plan form, thus utilizing a non-modular design. Large discrete dies composed of large numbers of translating pins or members encounter problems in assembly, wiling, tolerance build-up, and servicing. Additionally, the risk involved with machining tool bases and housings from solid material increases with the number of translating pins or members required for forming. The amount of machining necessary for a large discrete die could therefore be substantial. This causes high tool costs due to the large expenditures required to buy metal stock, then subsequently remove large volumes of metal during machining operations. The concept of “modularity” is additionally needed for discrete tools to allow taking a “building block” approach. The building block approach allows the tool designer to make use of low-cost, high quality castings for geartrain or drive motor housings and bases. Control systems for positioning of individual translating pins or members require substantial amounts of wiring which can become a problem when many wires are grouped together in very limited space. The use of modularity is described in prior-mentioned pending U.S. application Ser. No. 08/921,823 filed Sep. 2, 1997 entitled “Modularized Parallel Drivetrain”, now U.S. Pat. No. 5,954,175 and pending U.S. application Ser. No. 08/903,476 filed Jul. 30, 1997 entitled “Individual Motor Pin Module”, now U.S. Pat. No. 6,012,314, the entire disclosure of which is also incorporated herein in its entirety, for large die assemblies offers many advantages over non-modular discrete tool designs. “Modularity”, as described, permits the use of distributed control system logic which helps alleviate the problem of handling large quantities of wires in limited space. When using distributed logic, control system circuitry is placed inside each module housing minimizing external wiring connections. 
     Since heated honeycomb core is generally press-formed using fixed, three-dimensionally contoured dies, the springback in the honeycomb core cells is partly dependent upon the changing forming temperature of the core, die, and opposing surface material. Fixed dies do not have the ability to apply and remove heat directly to and from the honeycomb core cells. Springback and final shape consistency are therefore difficult to control precisely. 
     Troubleshooting, servicing, maintenance, repair and replacement tasks are also difficult to accomplish with discrete, self-adjusting tools without using the modular approach. Repairs, servicing, and maintenance of large discrete tools could otherwise require taking the equipment off-line for a long period of time. Down-time is therefore minimized by having the capability to rapidly replace complete modular assemblies quickly from acceptable spares stock. 
     Turn now to the drawings. Although the present invention will be described with reference to the embodiments shown in the drawings, it should be understood that the present invention can be embodied in many alternate forms of embodiments. In addition, any suitable size, shape or type of elements or materials could be used. 
     Embodiment A uses individual clutch drive modules  100  as shown in FIG.  5  and either suffix  1  or  2  type discrete translating pins or members  5  or  505  as shown in FIGS. 3 and 4 respectively. The adjustable form die  230  (FIG. 1) may employ the modularized “building-block” approach of adding (or subtracting) common modules  560  (FIG. 2) containing a smaller quantity of clutch-driven lead screw assemblies. Alternatively, if the size of the adjustable form die  230  permits, one module only may be used having the same number of pins  5  or  505  as the entire adjustable form die  230 . Modules  100  containing two columns of eight rows each are shown for convenience, but any number of rows and columns could be used as long as each module  100  is identical. The suffix  1  or  2  heated air (or gas) delivery methods determine how the heated air (or gas) is channeled into or through the cells of the honeycomb core  200 . Alternatively, these two heated air or gas delivery methods could be potentially combined if desired. Both hot air (or gas) delivery methods employ a heater or heat exchanger  260  which can supply hot or cool air (or gas) via vents and/or other controls (not shown) as necessitated during the particular stage of the forming cycle. The air or gas may be channeled through a suitable filter  290  and a recycling duct  320  which connects to a manifold which is coextensive with a stationary member  310  of resilient composition and may be porous to the flow of the air or gas. Methods of supplying cool air are well known in the art and are not specifically shown but are optionally a part of this invention. Note that if the stationary member  310  is of a material that doesn&#39;t permit the flow of air or gas, the interpolating pad  210  must have sufficient thickness and porosity for substantially even flow of air or gas to the cells of the honeycomb core article  200 . 
     The stationary member  310  of resilient composition includes a receiving surface  330  facing and laterally coextensive with the tip ends  6 ,  506  of the translating pins  5 ,  505 . The die  230  and the stationary member  310  are adapted to receive the honeycomb core article  200  between them such that interpolating, pads  210  are located at either end of the honeycomb core  200  and the tip ends of the array of translating pins are engageable with one surface of the interpolating pad  210  and the opposite surface of the interpolating pad  210  engages with the surface of the honeycomb core article. The receiving surface  330  of the stationary member is engageable with one end of the other interpolating pad  210  and the opposite surface of the interpolating pad  210  engages with the surface of the honeycomb article  200 . 
     The generic heated adjustable honeycomb core forming tool  1  shown in FIG. 1 may use an adjustable form die  230  as shown in FIG. 2 (without framing) whereby the translating pins or members  5  or  505  move under computer control such that the outer surfaces of the pin tips  6  or  506  form a three-dimensional (generally concave or convex) surface. The honeycomb core  200  is forced to assume the con tour of the surface created by the outer pin tips  6  or  506  by the movement of the press and/or pins  5  or  505 . At least one mesh or interpolating pad  210  may be placed between the pins and the honeycomb core  200  and optionally on the opposite side of the core  200 . High-temperature, open-weave fiber or mesh pads  210  may be used to prevent local crippling or damage to the honeycomb core  200  cell walls and to evenly diffuse heated air or gas through the cells so that fast, even heat-up and cool-down is assured. A heater or heat exchanger  260  is shown diagrammatically in FIG. 1 which is used with a blower or pump  250  for air (or gas) circulation. Ducting or hose  270  is used to interconnect the components approximately as shown. The heater or heat exchanger  260  may be a gas, oil, electric, or other type of heater, or a conductive, convective, or radiative-type heat exchanger. A computer control module  300  is shown in FIG. 1 which interfaces with a PC, work station, or other computer terminal  301  containing a user interface. Although one computer control module is shown, any number may be used according to the circuit layout for the particular tool. Thermal insulation may be used to prevent motor or clutch overheating, but is not specifically shown. Note that additional ducting (not shown) may be supplied to bypass the heater or heat exchanger  260  and/or other elements without changing the spirit of the invention. 
     Referring to FIGS. 3,  4 , and  5 , each pin  5  or  505  has a tip  6  or  506  and a base or drive nut  15  or  515 . The base or drive nut  15  or  515  has internal threads which mate to its respective lead screw  10  or  510 . Alternatively, the pins  5  or  505  may be bored from solid metal stock and internally threaded a short distance from the base, but it is preferable to make the pins from hollow or semi-hollow tubes. If the pins  5  or  505  are made from hollow tubes, a lead screw base or drive nut (or coupling)  15  or  515  needs to be attached to the end of the pin shank  9  or  509 . In suffix  1  (shown in FIG.  3 ), the lead screw base or drive nut has holes  516  drilled or formed to allow the passage of heated air (or gas) into the hollow pin and through additional holes  507  or passages in the pin tip  506 . 
     The pins  5  or  505  of Embodiment A are translated by the lead screws  10  or  510  which are rotated directly by specific timed electric signal from the control system to apply each individual clutch  55  to connect the flow of rotary power from the input shaft  65  to the lead screw  10  or  510 . After the pin module assembly  100  is inserted into the frame of the forming die apparatus  1 , the pins  5  or  505  are prevented from rotating by the restraining action of the pins&#39; planar sides against the sides of the tooling frame. Note that the pins  5  or  505  are preferably square (nominally), but can be rectangular or hexagonal in cross section, and may or may not have external chamfers or radii. The applied clutch  55  therefore rotates the lead screw  10  or  510  and translates each pin  5  or  505  a distance proportional to the length of time of the clutch “apply” signal given a steady gear train output shaft  25  rotational speed (e.g. from a synchronous motor whose output shaft speed remains fairly constant as loads change within its operating range). Also, as seen in FIG. 3A, insulating material  565  may optionally be provided on each of the translating pins for minimizing heat transfer to the pins from the air flowing to the cells of the honeycomb core article  200 . 
     Referring to FIG. 5, the input shaft  65  is driven by an external motor(s) (not shown). Either one single motor per module can be used to drive the module input shaft(s), or a cross shaft can be used to drive columns of parallel modules via one or more external motors. The motor(s) may or may not have its or their own gear reduction gearbox(es), depending upon the required lead screw  10  or  510  speed and input shaft drive gear-to-clutch drive gear ratios  90  &amp;  85 . Power is transmitted from the input shaft  65  to the clutch assembly  55  via the 90° meshing of the input shaft drive gear  90  and clutch drive gear  85  which can be either worm gear, helical or other gear combinations as long as a 90° change in power flow is permitted to drive the input side of the clutch assembly  55 . The input shaft  65  is supported by bearings  60  (or optionally bushings) which can withstand both radial and axial thrust forces. 
     The bearings  60  are retained by bearing retainers  110  which can withstand both axial and radial forces. The clutch assembly  55 , when deactivated, will not transmit rotary motion to the clutch output shaft  105 . Each clutch assembly  55  must be activated by a timed electric signal which connects the flow of power from the clutch drive gear  85 , through the clutch assembly  55 , to the clutch output shaft  105  and lead screw  10  or  510 . The control system  301 , capable of applying these timed signals, can be used with either centralized or distributed logic. The control system (not shown) may operate using either an open-loop or no feedback mode or a closed loop mode in the event rotary encoders (not shown) are connected to the clutch output shafts  105 . 
     The lead screws  10  or  510  are all threaded to allow the translating component or pin  5  or  505  to translate to the bottom of its&#39; travel such that the flow or heated air or gas is blocked from passing through to the internal or external flow passages. This assures that the flow of heated air or gas is directed to the honeycomb core only. Blocks may be added as needed (not shown) to prevent heated air or gas from being directed other than as desired. Temperature or thermal measurement sensors or devices (not shown) may be included to detect the temperature of the honeycomb core or forming cavity. Spacers (not shown) may also be used as needed to help locate small core details and allow the tool to adapt to different sizes of honeycomb core. Since linear, motion in the same direction from all shafts simultaneously, is desired, alternate columns of translating components or pins  5  or  505  may have opposite hand threads or teeth so that all of the parallel lead screws  10  or  510  can translate simultaneously in the same direction if desired. 
     Modularized Parallel Drive Trains  100  used in this invention (as described in U.S. application Ser. No. 08/921,823 can be connected to one another in series by using male and/or female links or slip couplings between two connected collinear input shafts  65 . The modules  100  therefore can he placed side by side, front-to-back, or both. 
     FIGS. 2 and 6 show the Embodiment B Modular Individual-Motor drive approach (reference U.S. application Ser. No. 08/903,476). As with the Modularized Individual Clutch Drive method, either suffix  1  or  2  translating pins  5  or  505 , lead screws  10  or  510 , and the like may be used (individually or in combination). The prior discussion of the pins applies as does the discussion of the overall tool design and operation except as noted herein. 
     Referring to FIG. 6, the lead screws  10  or  510  are connected directly to the gear train output shafts  525  which in turn receives its&#39; rotary motion from the motor  540  via the in-line gear train  535  unit. The motor  540  torque therefore translates each pin a distance proportional to the amount of gear train output shaft  525  rotation. The gear train  535  can use either planetary or non-planetary gears. These units are readily available commercially and can be connected directly to the motor  540  housing and motor output shaft. Each motor  540  is activated by D.C. power. The control system  310  which is capable of controlling pin motion can be built with either centralized or distributed logic. The distributed logic approach is preferred when building large scale contour tools because the amount of external wiring is greatly reduced. The control system determines how many revolutions (and portions of revolutions) that the motor  540  must revolve and stores the correct number of pulses in local memory. As the motor  540  rotates, the local circuitry counts the number of pulses from the rotary encoder assembly  545 . The number of pulsed-feedback signals is compared to the target number of pulses stored in local memory for each motor  540 , and the motor is stopped when the pulses counted are greater than or equal to the stored target number of pulses. Wiring is therefore needed from the motor  540  encoder assembly  545  to the local circuit board  550 , and from the local circuit board  550  to the neighboring circuit modules. Wiring is also needed to the control computer  301  and to electrical power (not shown). 
     In practice, all modules are identical and interchangeable, yet each module can be individually addressed by the system controller. To accomplish this, the modules communicate using a novel bi-directional ring architecture and communication scheme. In this architecture, a module receives commands and data from the preceding module, that is, closer to the system controller, and acts on and/or transmits to the succeeding module, that is, the module which is farther from the system controller. This provides an extensible mechanism by which any number of controllers can receive a command. For a controller to recognize and act upon a command, it must have been initialized to a valid, unique address. Since all modules are initially configured to have an invalid address stored in EEPROM (Electrically Erasable Programmable Read-Only Memory), the system controller first transmits an initialize command with the desired starting address, and the first module accepts this as its address and stores it. This module then increments the address and transmits it to the next module in the ring, which repeats the process. The last module in the ring transmits to the system controller, which receives the initialize command containing an address that is one larger than the total number of modules in the system. By this method, all modules are initialized with unique addresses, and the system controller is made aware of the exact number of modules and their addresses. 
     In actual use, the pitch of the lead screw  10  or  510  is chosen so that the pins  5  or  505  are self-locking under compressive load. Forming loads are transferred from the pill  5  or  505  to the lead screw  10  or  510  and then from the lead screw base  15  or  515  to the module base  520 . As with the Individual Clutch method of Embodiment A, the pins  5  or  505  are prevented from rotating by the restraining action of their planar sides against framing members or sidewalls  240  of the form die. Each pin module assembly  560  is located via locating pins  555 , or the like, onto a base plate or frame member  220  which connects to the frame  280  of the form die for enclosing an upper and lower array of pin module assemblies  560 . 
     While preferred embodiments of the invention have been disclosed in detail, it should be understood by those skilled in the art that various other modifications may be made to the illustrated embodiments without departing from the scope of the invention as described in the specification and defined in the appended claims.