Not Applicable
Not Applicable
The present invention relates to wire harnesses, and more particularly to a system for assembling wire harnesses using a transparent peg board with a rear mounted visual display system.
A transparent peg board is mounted in front of a display system such as an LCD or plasma display. The display is driven by a proprietary computer program running on computer. A plurality of round dots are illuminated on the display that align with pre-determined peg holes thus indicating to an operator where various pegs should be mounted. After the pegs have been installed the wire runs are displayed one by one as the operator lays in the wire runs in the appropriate locations. Visual notes with instructions and or videos are displayed on the LCD or plasma display to assist the operator. Finally wire ties and connectors may be assembled to the harness. There is also a Quality Control mode of the program so that a QC inspector may come onto the job and inspect the ‘as built’ harness on the pegboard before it is removed.
The advantages and features discussed above and other advantages and features will become apparent from the detailed description of the best mode for carrying out the invention that follows.
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention.
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The pegboard 12 has a plurality of pegholes 18 drilled into its surface. The pegholes 18 are designed to receive a variety of pegs 20. The pegholes 18 are illuminated or backlit with a green circle 22 of light emanating from the digital display 14. Such light is coming from the digital display 14 as commanded by the PC. During an initialization process controlled by the operator and PC, the display 14 was registered or aligned with the pegholes 18 so that the green circles 22 of light were all aligned with their respective pegholes 18. Once the on-center distance between pegholes 18 is selected on the PC at initialization, and the pegboard 12 is registered with the display 14, the PC software generates an illumination pattern of where to display the green circles 22 of light so that they illuminate exactly behind the pegholes 18 which are to be populated with pegs 20 by the operator in the assembly process.
Pegs 20 are inserted into the peghole 18 locations illuminated by the green circles 22. The display 14 also illuminates the various wire runs 24, cable ties 26, and a variety of connectors 28. Not only is the shape of the particular connector 28 shown, but a text description 30 is displayed in a location next to the connector 28. The connector 28 shape and text description 30 assist the operator in making sure the right connector 28 is assembled in that particular location. This is a great aid in eliminating costly operator errors.
As stated above the wire runs 24 are similarly illuminated by the display 14. In
It should be noted that in this application the term ‘wire’ applies to any flexible conduit or tube such as optical fiber, flexible tubing, catheter, biologic tubing, nanotubing, synthetic strand materials such as Kevlar or Nylon, and any other duct, vessel or canula which can be formed in pathways.
Currently digital displays 14 such as plasma are approximately 30-60 inches diagonally in size but larger displays 14 have been manufactured at over 100 inches. This size limitation does not limit the size of this invention or pegboard 12 as the displays 14 can be linked together beneath a common pegboard 12. The display software takes the entire image and breaks it up into appropriate visual segments to be displayed on each of the linked displays 14. Special image stitching software is used to make sure that the total image displayed is true to the real dimensions required for the harness 32. In other words the dead zones between the individual displays 14 is taken into consideration so that a wire run 24 from one display 14 to a peg 20 on the next display 14 is still dimensionally accurate. Special techniques are used to minimize the dead zones between displays 14 such as removing any bezel or frame and mounting the displays as close together as possible. Thus the pegboard 12 may be any width or length using this ‘stitching’ approach.
Another technology which may be used in conjunction with large pegboards 12 are the electronic billboards now beginning to populate our stadiums and highways. These billboards are large digital displays 14 that can be controlled in the same manner as in the digital wire harness assembly system 10. Essentially the modular LED components and software to coordinate the individual displays 14 into one large visual display 14 removes size alone as a limitation.
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It should be noted that the pegboard 12 must be transparent, not just translucent, for this invention to work. It must be completely transparent so that the operator can clearly see any of the visual information displayed by the LCD or plasma display 14 behind the pegboard 12. The pegholes 18 can be placed on the transparent pegboard 12 in any pattern and any size depending upon the type of harness 32 and or wire sizes to be used.
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The toolbar 16 can be used by an operator sitting at the PC in a conventional manner or by an operator at the pegboard 12 by using a touch sensitive display screen or other technology to sense the operators pressure touches to the pegboard. It can also be activated by the wireless mouse as described above by moving an image cursor over a tool icon 40 on the toolbar 16 and clicking.
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Pegs 20 can be of various lengths and diameter to accommodate various types of harnesses 32, wire sizes and number of wire runs 24.
The grid size, shape, and pattern of the pegholes 18 in the pegboard 12 can vary to accommodate various kinds of jobs and or requirements.
The pegboard 12 and assembled harness 32 may be easily removed as a unit from the digital display 14 and transported to another location for further processing or assembly of the harness 32.
The pegs 20 are designed to have different mechanisms for securing them to the pegboard 12. A first method is a peg 20 having a tapered shape that frictionally engages a similarly shaped peghole 18 in the pegboard 12. Another method is a peg 20 with bottom protruding ears designed for a twist lock bottom for mating securely with receiving grooves in the pegholes 18 of the pegboard 12.
The operator can easily move his head to the side or below an installed wire run 24 to see the display information below the harness 32.
A quality control (QC) inspection routine is built into the computer program to allow a QC inspector to step through the assembled harness 32 with visual display information and confirm each wire run 24 has been assembled correctly.
The display 14 has to be calibrated such that it is 1:1 as the harnesses 32 are being built to actual dimensions.
Tie wrap or cable tie 26 locations are indicated on the display 14 to assist the operator in placing them correctly.
A wireless mouse 54 can be used on the interactive pegboard 12/display 14 to control the software and or program. A wireless keyboard 56 can also be placed on the pegboard 12 and used to control the software.
A digitized surface 58 on the pegboard 12/display 14 allows for reverse engineering of old harnesses 32 so that the appropriate build information can be determined from an actual ‘used’ harness 32.
In an alternate mode, the tool bar 16 and work instruction windows 42, 44 will automatically move back and forth along the length of the display 14 as the operator moves back and forth so that the displayed information 42, 44 is always in front of the operator. The system senses the operator's location from a wireless transmitter 60 he is wearing on his waistband, or by sensing pressure from the operator's manual work on the pegboard 12.
The operator can override this ‘track’ mode through different inputs such as the wireless mouse or keypad or at the PC keyboard and mouse. The tool bar 16 and work instruction windows 42, 44 can be set into a fixed position on the display 14, or operate in ‘sequence mode’ where they progress from a first work location to a subsequent work location.
A method for confirming that a peg 20 has been inserted and/or a wire has been placed is provided. Peg 20 insertion may be sensed from pressure in the pegboard 12 pegholes 18, or sensing capacitive changes due to human touch as a peg 20 is inserted, or touch screen technology. Wire placement may be sensed by end to end electrical conductance along a wire run 24, or a capacitive change along the wire run 24. This may entail technologies or a combination of technologies such as pressure sensitive pegs, touch screen technology, and or software. In another alternative mode, the system may restrict the next image from being displayed until confirmation has been received that the previous task has been performed.
The fluorescent pegs 20 will be available in varying configurations, sizes and diameters. In one embodiment they are encased in a metal housing to provide maximum strength while at the same time keeping the diameter to a minimum. The metal housing may be full coverage or leave an open bottom and top for the fluorescent effect.
Voice recognition and audio technology will be used to communicate instructions/information or receive instructions/information. In one embodiment, the PC will support the operator with verbal commands/instructions and information. The PC will also receive and process audio acknowledgement and commands from the operator. For example, the program will not advance to the next step until it receives an acknowledgment from the operator the current manufacturing step is complete. All command normally input by keypad or mouse will be receivable by the PC with voice recognition technology. The operator may command the toolbar 16 to reposition, or request a video note or instruction note to be displayed. The operator may command the PC to advance to the next assembly instruction which will cause a new wire run to be illuminated, new notes and videos to be display. The notes can be converted into audio. The operator may wear a wireless audio headset with a microphone for communicating with the PC.
A variety of wireless technologies may be employed such as Bluetooth, infrared, cellular, radio frequency or any such technology that will allow for instructions/commands/information to be remotely communicated to and from the PC.
In another embodiment the operator may command the system 10 to display a digital ruler 62 the entire length and/or width of the display 14. The ruler 62 will be provided in either English or Metric measure, or in any other standard units of length. Also a visual grid 64 of operator selectable dimensions such as 0.5″×0.5″ may be displayed on the digital display 14 to assist the operator in judging distance and lengths.
The digital wire harness pegboard 12 and display 14 are supported by a specially designed stand 64. The stand 64 is operator adjustable in height and angle of tilt for the pegboard 12/display 14. The adjustment of height and tilt may be performed by mechanical, electrical or hydraulic actuators. The stand 64 also has fixed film spools at either end of the pegboard 12, one spool for dispensing film and a second spool for receiving used film. The film advancement may be controlled by mechanical means or by an electric motor. The film advancement may be controlled through a tool icon 40 in the toolbar 16, or via the PC, or by voice command.
Various wire spools 66 are attached to the stand 64 so as to be readily available to dispense all of the wire types needed for a harness 32. A unique color LED is attached to the output of each wire spool 66 so to assist in matching the wire type with the wire run 24. If a blue wire run 24 is displayed as the next assembly step, the operator pulls wire from the spool with the blue LED next to its output. Alternatively the LEDs may flash to indicate which spool should be used in the next step.
The system 10 also has operator selectable levels of transparency/brightness for the displayed tool bar 16 and instruction and video notes 42, 44. These visual images can be controlled so as not to obscure the underlying wire run 24/harness 32 images, as well as reduce unwanted brightness so as to assist in the operator's comfort by minimizing eye fatigue.
The foregoing description of the embodiments of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto.
This application claims priority benefit of a U.S. Provisional Application Ser. No. 61/070,510 filed in the United States Patent and Trademark Office on Mar. 24, 2008, and entitled “DIGITAL WIRE HARNESS ASSEMBLY SYSTEM”.
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