Not Applicable
Not Applicable
Not Applicable
1. Field of the Invention
The present invention relates to a computer based system for assisting a technician in performing maintenance and repair operations.
2. Description of Related Art Including Information Disclosed Under 37 CFR 1.97 and 1.98
Complex machinery typically requires substantial amounts of maintenance and repair and because of the complexity involved; technicians skilled in performing such operations can be quite costly. Further, most complex equipment incorporates mechanical, electrical, and computer components which confounds the issue further. Such equipment may require multiple technicians to accomplish even the simplest of repairs.
Such complex equipment having multiple sub-assemblies and components also requires numerous volumes of manuals that can be difficult to store, retrieve, and access. These manuals tend to be relatively “unfriendly” in terms of usability for all but the highest of skilled technicians. Also, unless the manuals are maintained current, they can sometimes become out of date and not provide the latest in troubleshooting tips and available part numbers. Moreover, the real estate required to house this library of manuals only adds to the overall expense.
For example, a basic high-speed mail sorter with the U.S. Postal Service (USPS) can have hundreds of mechanical electrical, and computer control sub-systems. These sub-systems must be perfectly synchronized to properly sort the tremendous volume of mail that the USPS processes daily. Often, a failure in one sub-system is difficult to trace when considering only the overall symptoms. A repair technician must consult numerous volumes of manuals and perform detailed, exacting steps to isolate the problem and, once isolated, must properly calibrate the transport and sorting mechanisms.
In the past, an “inside-out” approach to maintenance/training has been used. This inside-out approach required leader-led training, computer based training, self-study, maintenance documentation, parts ordering knowledge, and years on the job experience to attain an expert level of knowledge of a complex machine. The inside-out approach concentrated on how the machine did what it did. Such training techniques are costly in both time and expense.
What is needed is a repair system that allows a relatively unskilled technician to perform maintenance and repairs on complex machinery. Also needed is a means for providing equipment maintenance and repair manuals that is easy to support and update. The present invention satisfies these needs and others as shown by the detailed description below.
A method is disclosed for providing a user with dynamically varying levels of operational, support, maintenance, and repair information for a machine or piece of equipment composed of a plurality of subcomponents, the method steps comprising: providing a database device capable of supplying detailed information regarding a machine, and a first computing device operably coupled with the database device and operably configured to provide a graphical user interface (GUI) capable of user interaction, the GUI providing a cursor for manipulation by a user and at least a first area and a second area for display of information detail regarding the machine, the first area and second area including one or more hot-spots for user interaction, wherein the information in the areas is related, and wherein the detail level of the related information varies between the areas; providing a first image of the machine in a first window area on the GUI wherein the first image represents a high-level image of the machine; displaying a first level of information detail related to the operation of the machine; and detecting the cursor position and varying the information displayed in the first area or the second area based upon the cursor position and, in response, displaying a second level of information detail that is greater in detail than the first level of information.
A computer implemented interactive machine maintenance support system is disclosed, the system comprising: a database device capable of providing detailed information regarding a given machine; a first computing device operably coupled with the database device and operably configured to provide a graphical user interface (GUI) capable of user interaction, the GUI comprising: a first area for displaying a first level of information detail regarding the machine, the first area including one or more hot-spots for user interaction; and a second area for displaying a second level of information detail that is greater in detail than the first level of information detail provided in the first area, wherein the second level of information is related to the first level of information, the second area including one or more hot-spots for user interaction; wherein a user may interact with a hot-spot by manipulating a cursor with respect to the first or second area hot-spots, wherein manipulation of the cursor occurs through manipulation by the user of an input device, and wherein interaction with a hot-spot in one area influences the information displayed in the other area.
The present invention will be more fully understood by reference to the following detailed description of the preferred embodiments of the present invention when read in conjunction with the accompanying drawings, wherein:
The above figures are provided for the purpose of illustration and description only, and are not intended to define the limits of the disclosed invention. Use of the same reference number in multiple figures is intended to designate the same or similar parts. Furthermore, when the terms “top,” “bottom,” “first,” “second,” “upper,” “lower,” “height,” “width,” “length,” “end,” “side,” “horizontal,” “vertical,” and similar terms are used herein, it should be understood that these terms have reference only to the structure shown in the drawing and are utilized only to facilitate describing the particular embodiment. The extension of the figures with respect to number, position, relationship, and dimensions of the parts to form the preferred embodiment will be explained or will be within the skill of the art after the following teachings of the present invention have been read and understood.
A portion of the disclosure of this patent document contains material which is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the patent document or the patent disclosure, as it appears in the Patent and Trademark Office patent file or records, but otherwise reserves all copyright rights whatsoever.
Certain terms used herein are defined as follows:
The Visual Intuitive Interactive Interwoven Multi-Layered Maintenance Support Graphical User Interface (GUI) of the present invention uses sophisticated information-packing techniques that enable both operational and technical users to locate non-obvious detailed maintenance support information easily without any prior machine specific technical training or maintenance documentation. The system utilizes information-packing to make virtually an unlimited number of pages of information available to the user on one window. It is not uncommon to have more than 100 pages of related information available to the user in a single window.
Unlike previous technical information accessing systems (books, hardcopy, web based training, computer base training, etc.) that move from one page or window to another in a linear fashion, the GUI of the present embodiment relies on visual information to stimulate intuitive interactions with both operational and technical users alike.
Operational and technical users are familiar with what a given machine does and how it operates. For example, a particular machine may print checks and address information on envelopes. The machine then inserts the checks into the envelopes and then sorts the envelopes according to the address into plastic bins. How the inner workings of the machine function may not be readily apparent, but what the machine does is obvious to the user that has observed the machine during operations.
The GUI employs an outside-in approach to locating detailed technical information by using the machine's visual appearance and operations (functions) to lead the user to detailed non-obvious technical information. Learning how to use the GUI to locate detailed maintenance information turns a machine novice into a machine expert in a relatively short amount of time.
The GUI also tracks the users and creates detailed user and machine related records, makes parts fulfillment quick and easy by automatically providing all the information needed to order parts, saves parts usage information to the data base (tracks every part on the machine by the parts unique location). The information saved to the data base also allows for parts failure trends to be recorded and analyzed.
The GUI of the present embodiment displays equipment (or machine) operations and maintenance support information (pictures, text, line art, etc) in multiple layers, beginning with an Overall Layer (020) as depicted in
The GUI operates as a conventional user interface that allows the user to select, or “click,” an onscreen link to perform a particular function. Clicking on one of the options at the Overall Layer (020) “drills down” to the Intermediate Layer (025). The Intermediate Layer (025) displays machine maintenance information in additional detail. The user may “drill down” further, from the Intermediate Layer (025) to the Detailed Layer (026). The Detailed Layer (026) contains all maintenance information necessary to support the given overall piece of equipment. This detailed information includes, but is not limited to, Detailed Block Diagrams (schematics); Removal & Replacement Procedures; Adjustment & Alignment procedures; parts ordering forms, and all other maintenance tasks and information required to support and maintain the machine. The Management Software (027) monitors any machine maintenance activities.
The present embodiment utilizes Cursor Windows to display information related to the position of the cursor. Cursor Windows interact with the cursor, items-of-interest, and hot-spots to display detailed information about the item-of-interest. Hot-spots are created over items-of-interest. Items-of-interest are usually machine components that are associated with machine operation. In this embodiment, multiple items-of-interest exist on a particular window. Each item-of-interest has one or more hot-spots. When the cursor is placed over such a hot-spot, a mouse-over action causes detailed information related to the item-of-interest to be displayed in the associated one or more Cursor Windows.
Each Cursor Window has two frames, with only one frame active at any given time. When the cursor isn't over a hot-spot the associated Cursor Window/Windows are considered inactive and a black frame is displayed around the window. However, when the cursor is positioned over a hot-spot (i.e., item-of-interest), a dashed yellow/black Working Area Frame is displayed around the associated active Cursor Windows. Thus, the presence of the Working Area Frame indicates that the cursor is over additional information that is related to the base information being displayed in the active Cursor Window.
In the present embodiment there can be as many Cursor Windows, of same or different physical dimension, as necessary to communicate the pertinent technical information the user needs to know about an item-of-interest. The Cursor Windows is intended to provide the user enough information to make the decision of whether or not to select and navigate into the item-of-interest.
The Working Area Frames (300) frame Cursor Windows that are displaying detailed information related to the item-of-interest beneath the cursor. As depicted, Unit 1 has the access doors open, showing Unit 1's internal items-of-interest. If the user wants to know more about Unit 1, clicking on Unit 1 causes a window to be displayed, providing additional detailed information about Unit 1. A white Moving Shape Box (201) is used to pinpoint an item-of-interest, in this case Unit 1 inside of the Cursor Window's Working Area Frame. Thus, Unit 1 of the machine depicted at the top of the GUI is essentially highlighted, magnified, and exploded in the Cursor Window near the bottom of the GUI to provide greater detail.
In
In
In another example,
In the present embodiment the Information Packing design anticipates what the user is looking for and packs the surrounding area with related assistive information. Information Packing is a design concept that uses the cursor, hot-spots, and Cursor Windows to pack information around items-of-interest. Items-of-interest are chosen in advance by the designer of the embodiment, who then creates corresponding hot-spots and additional detailed information to be displayed in the associated Cursor Windows. Hot-spots typically consist of hyperlinks to the additional data. The hot-spots can be created by use of embedded links, inline links, and/or image maps.
The information in the Cursor Windows is not displayed until the cursor is positioned over the item-of-interest's hot-spot. When the Cursor is over an item-of-interest's hot-spot, the detailed information about the item-of-interest is displayed in Cursor Windows that are framed with the Working Area Frame. The information displayed can be any form of multi-media, such as pictures, text, audio, video, line art, etc. To view additional information about the item-of-interest the user need only click (or select) the hot-spot.
The GUI relies on visual information to stimulate intuitive interactions with operators and technical users. Operators and technical users are typically intimately familiar with what the machine does and how it functions. For example, consider a machine that prints checks and address information on envelopes. The machine inserts the checks into envelopes and sorts the envelopes according to the address into plastic bins. To the user it may not be obvious exactly how the inner workings of the machine function, but that same user has a clear understanding of what the machine accomplishes.
In the past, an inside-out approach to training/maintenance documentation has been used. This inside-out approach required leader-led training, computer based training, self-study, and years on the job to attain an expert level of knowledge of a complex machine. The inside-out approach concentrates on how the machine achieves its results.
The GUI of the present invention uses an outside-in approach that employs location and appearance, fault, symptoms, and what the machine does (functions) to guide the user to very detailed maintenance information without any prior machine specific technical training or maintenance documentation. Learning how to use The GUI to locate detailed information turns a novice machine operator into a machine expert almost instantly and learning how to use the GUI is quick and easy.
The present embodiment provides three diagram levels; overall, intermediate, and detailed. The levels enable the user to move from a high level (coarse detail) through an intermediate functional level to a maintenance support or highly-detailed functional level. The Overall Block Diagram (OBD) is designed to get the user to the right circuit or function's Intermediate Block Diagram (IBD). To do this the OBD uses text, visual images of the machine, and a functional circuit layout that the user can relate to. The functional layout relates to what the machine does, allowing a user with no technical training or maintenance documentation on the machine, but knows what the machine does, to trouble shoot at an expert level. The IBDs and Detailed Block Diagrams (DBD) work together to make understanding and troubleshooting of complex circuits or functions relatively quick and easy.
The IBD is an intermediate level diagram that shows relationships between all the components (items-of-interest) in a circuit or function, the DBD shows technical details about the components (items-of-interest) in a circuit or function. The IBD is typically a one window Block Diagram but can require multiple windows. IBDs have electrical and/or mechanical signal connections to other circuits or functions IBDs. A DBD typically has multiple windows, but can be only one window. The DBD's contain the most technical information required to maintain/repair the machine.
The OBD usually requires only one window, but complex systems can require multiple windows. Unlike the IBDs and DBDs, the OBD shows all of the systems circuits or functions. The OBD provides links from each circuit or function to that circuit's or function's IBD. Each circuit or function has its own IBD and DBD.
IBDs have signal links to follow signals to and from other IBDs. The IBDs also have level links to move from the IBD item-of-interest to the item-of-interest's DBD. The DBDs have signal links to follow signals inside the circuit or function and links to follow signals to/from other circuits or function's DBDs. Multiple window DBDs have signaling links connecting to the other windows off a DBD. The DBDs also have level links to move from the DBD item-of-interest to the IBD item-of-interest. This capability is very useful when trouble shooting an item-of-interest in a large complex circuit.
Navigating into the Three-Layered Diagrams
Referring again to
The Lane Motors Control Circuit IBD window is depicted in
Navigating from IBD to IBD
Signal links are provided for the user to follow the signals going to or from one IBD window to another IBD window. For example, in
Navigating from DBD to DBD
An additional Lane Motor Control DBD window is displayed in
Multiple Entrances into the GUI
The intuitive interactions between the user and The GUI are stimulated by visual reactions to images displayed on the active-window. The visual information can be pictures, line art, text, animation, video, audio, or any combination of such multimedia. The intuitive interaction begins after logging in with the user looking at the home page window as shown again in
The user can locate detailed technical information about any item-of-interest on the machine by simply knowing its location and its appearance. For example, consider the following fault Symptom Scenario. As product is moving through the machines transport system it is repeatedly jamming at the same spot. The user has noticed that the machine is jamming repeatedly at the same spot. After a visual inspection the user discovers that a motor isn't turning and that product is repeatedly jamming at that motor. The user is tasked with Removing & Replacing (R&R) the faulty motor.
At this point, the user doesn't know the name of the motor or the name of the unit (location) the motor is in. The user can see where the motor is located (location) and what it looks like (its appearance). The user then logs into the GUI of the present invention. The GUI displays the home page as shown in
The user positions the cursor (100) over the location on the machine in which the motor resides in the top image as in
A detailed picture of Unit 1 is now displayed in
The Lane Motors Control DBD window is now displayed as shown in
In
Consider the following intermittent fault scenario. There have been an unacceptable number of intermittent product jams at Unit 1's 1R and 1L Lane Motors. A jam causes the machine to stop. After the jam has been cleared, the machine restarts and runs, but soon jams again at 1R and 1L Lane Motors. Intermittent faults are typically the hardest faults to identify and isolate. The user decides to use the circuit functional diagrams to identify the component causing the intermittent product jams.
The user suspects the circuit that powers Unit 1's Lane Motors is opening up due to vibrations, heat, and/or product pressure. The Lane Motors stop when the circuit opens, resulting in product jamming in the 1R and 1L Lane Motor area. The user isn't sure what is causing the jams, even after a visual inspection during operations. At this point, the user wants to learn about the circuit that controls the Lane Motors so the user can look for possible causes of the product jams.
The GUI's homepage display is shown in
The Lane Motors Control Circuit's IBD displays the item-of-interests that are used to control the operation of the machines Lane Motors. In
The Lane Motors Control's Detailed Block Diagram (DBD) then displays in
In
The user now knows that there is a maintenance aid LED LA that can be used to isolate the intermittent fault in the Lane Motors Control circuit. The user restarts the machine and observes LED LA. The machine starts but quickly jams. The user observes that LED LA remains on even though the Lane Motors aren't running. This indicates that the signal LA is good at the output of SSRLA pin #2, indicating that the fault is downstream from SSR LA. In
In
The machine operator has been operating the machine long enough to become very familiar with what the machine does or its functions. While running the machine if there is a problem the operator is experienced enough to recognize what the machine isn't doing or in other words, the problems symptom. The operator can use the Trouble Shooting entrance to the GUI to locate the information required to repair the machine by looking up the symptom.
Consider the following fault symptom scenario: the machine's transport system is repeatedly jamming at the same spot. From the home page window of
Consider a situation in which the user notices that product is jamming at Belt 1A. Upon visual inspection of the belt, the user notices that Belt 1 LA isn't turning. The user logs into The GUI, the homepage window displays as in
Moving from Unit to Unit
To improve usability, links that allow the user to navigate from Unit to Unit provides quick and easy access between units of the mechanical system. Consider the following scenario. The home page Window displays as in
The Stop & Go Video (SGV) feature of the present invention is an effective and efficient way to review and learn about many types of complex subjects. For example, consider a parts Removal and Replacement (R&R) procedure. SGV mimics the time-sequence of video frames but provides much more control of the frame size, rate, and direction. Some of the benefits of SGV are the ability to access any frame (step) in the video at anytime, watch the frame (step) for as long as needed, move forward and backward as needed, etc. Most steps presented in SGV have mouse-over action but do not have a link because there is no more information required for that item-of-interest.
The Lane Motor R&R Procedure window is displayed as in
The user may then move the cursor (100) to step 2's hot-spot as depicted in
If the user wishes to review any step, he or she need only select the desired hot-spot. For example, if the user wants to review step 6 the cursor may be moved directly to step 6's hot-spot (852) as depicted in
Stop & Go Animation (SGA) is a learning aid that uses colors to break up complex items. In this example a complex circuit is broken up into smaller less complex items or sub-circuits, while maintaining the relationship of the less complex items or sub-circuits to the larger complex item or circuit. In this embodiment SGA uses the colors (white, red, and yellow) to explain the operations of the complex circuit. The colors are used to break the complex circuit up into associated groups or sub-circuits of items-of-interest. SGA allows the user to study the complex circuit in a logical manner keeping track of the sub-circuits the user has covered, the current sub-circuit being displayed, and the sub-circuits yet not covered. In this embodiment the color white is used to represent sub-circuits not explained yet. The red color represents the current sub-circuits being described. The yellow color represents sub-circuits already explained. However, one skilled in the art will appreciate that any colors, shades of colors, or patterns of colors may be utilized and are within the scope of the invention.
A typical complex circuit is displayed in
When the user moves the cursor over a step's hot-spot certain colors and text change on the active-window. The color changes to focus the users attention on one sub-circuit while maintain the relationship that sub-circuit has with the other circuits that make up the overall complex circuit or function. The intended manner to use SGA is to start at step 1 and continue to the last step, in this case, step 5, but SGA allows the user to review the steps in any order.
In this embodiment, SGA has two distinct modes. The first mode or normal mode uses mouse-over events to display Circuit Operation information associated with that step. The normal mode has a Click to Freeze Window feature. When a Circuit Operation step's hot-spot is clicked on, the active-window for that step enters the frozen mode. The frozen mode freezes the current window in place, allowing the user to move the cursor around the frozen window observing mouse-overs and clicking on links as needed.
In
In
In
In
In
If the user is interested in learning more about the Lane Motor Control sub-circuit, the user may select step 5's hot-spot, freezing the window as shown in
When the cursor is over a hot-spot and a mouse-over action occurs, but when clicking on the hot-spot nothing happens, the user is at the end of information for that item-of-interest. This is similar to coming to the end of a section in a book.
Complex item-of-interests require more information to describe their location and functions. Complex item-of-interests usually perform more than one function in one replaceable part (item-of-interest). Complex items-of-interest can require an associated schematic/schematics or other types of technical information to describe them and their relationship with machine operations.
The following is an example of navigating to and from complex item-of-interests with the present embodiment. Notice in this example the user starts at Physical Appearance and Location and navigates to the complex item-of-interest. The user can also navigate to the complex item-of-interest from the OBD button, Trouble Shooting button, and/or Belting button GUI entrances.
In
The Unit 1 Control Computer's PCB Blocked Schematic window then displays as in
As depicted in
In
In the present embodiment the GUI may also be used to locate and order parts. The user doesn't have to know the part name or part number, just the parts location and appearance. The Management Software (MS) also records parts usage, including the location of a faulty part, that part's replacement history, etc. The MS records the parts used, time it takes to replace the part, and displays the time it should take to replace the part. The MS reports all machine information to a system database.
Consider an example in which a user has been tasked with ordering two replacement 1R Lane Motors. The user knows the location and appearance of Lane Motor 1R. The user logins in and the homepage window displays as in
Once the user has moved the cursor (100) and clicked Unit 1's hot-spot (873) as in
Next the user has moved the cursor (100) to the Order Lane Motor button's hot-spot (875) as depicted in
Electro-mechanical signals illustrate the mechanical connectivity between electrical and mechanical items-of-interests. The types of connections can be electro-pneumatic, electro-hydraulic, electro-mechanical, mechanical-mechanical and/or any other type of connectivity. The interface of the present invention is also intuitive in processing and displaying this information.
A Lane Belt 1A Detailed Mechanical Diagram (DMD) window is available as depicted in
If selected, the Lane Motors Control DBD window displays as in
Mechanical Links illustrate the connectivity between mechanical item-of-interests and their information. Such a display is depicted in
The present invention also includes Management Software (MS). The MS supports creating and using security log-ins, creating user's activity logs, generating customized user/task/time reports, parts usage trends/ordering/logs, task management, user access, and GUI access. The MS structure of this embodiment is depicted in
The present invention is designed to run as a system that utilizes one or more computing platforms capable of generating a graphical user interface (GUI). The functionality described herein may be implemented using standard programming languages that include, but are not limited to, C, C++, C#, Java, Visual Basic, VBScript, JavaScript, Pearl, Ruby, Assembly, or any other programming language capable of generating computer machine code to produce or support a graphical user interface for user interaction. One of ordinary skill will understand that any such language, or a combination, may be utilized and is within the scope of the invention.
The present embodiment may be designed to operate as a dedicated GUI that is supported by a single operating system, or may be developed using software that is portable across multiple operating systems. Further, the GUI may be implemented on a Web server using HTML code to generate the GUI to operate in a user's Web browser. Thus, the system may be accessed over a private network, the Internet, or may run on an isolated computer system.
The computing device as utilized herein may be a single computer or may consist of multiple computers. The computing device may be a general purpose computer or may be a dedicated computer. In any event, the computing device is capable of operating machine program code to provide the desired functionality. Such computing devices may utilize RISC or CISC processors, DSP, FPGA, ASIC, CPLD, or other such devices, or any combination thereof.
As used herein, a system database can be any device capable of interfacing with the computing device and capable of storing data generated by the computing device. The database device may also consist of any semiconductor or hardware volatile or non-volatile memory storage technologies or a combination of the two. For example, the GUI of the present invention may extract its operational data from a removable flash memory device that holds relevant machine maintenance and operation information. Such a system would allow rapid reconfiguration of the GUI for any number of machines. Likewise, in another embodiment, relevant machine information may be stored on a hard drive storage device or similar non-volatile storage medium. For rapid and efficient data access it is also possible to utilize volatile RAM memory as the storage medium.
As indicated above, aspects of this invention pertain to specific “method functions” implementable through various computer systems. In an alternate embodiment, the invention may be implemented as a computer program product for use with a computer system. Those skilled in the art should readily appreciate that programs defining the functions of the present invention can be delivered to a computer in many forms, which include, but are not limited to: (a) information permanently stored on non-writeable storage media (e.g. read only memory devices within a computer such as ROMs or CD-ROM disks readable only by a computer I/O attachment); (b) information alterably stored on writeable storage media (e.g. floppy disks and hard drives); or (c) information conveyed to a computer through communication media, such as a local area network, a telephone network, or a public network like the Internet. It should be understood, therefore, that such media, when carrying computer readable instructions that direct the method functions of the present invention, represent alternate embodiments of the present invention.
Claim 1. A method for providing a user with dynamically varying levels of operational, support, maintenance, and repair information for a machine or piece of equipment composed of a plurality of subcomponents, the method steps comprising: providing a database device capable of supplying detailed information regarding a machine, and a first computing device operably coupled with the database device and operably configured to provide a graphical user interface (GUI) capable of user interaction, the GUI providing a cursor for manipulation by a user and at least a first area and a second area for display of information detail regarding the machine, the first area and second area including one or more hot-spots for user interaction, wherein the information in the areas is related, and wherein the detail level of the related information varies between the areas; providing a first image of the machine in a first window area on the GUI wherein the first image represents a high-level image of the machine; displaying a first level of information detail related to the operation of the machine; and detecting the cursor position and varying the information displayed in the first area or the second area based upon the cursor position and, in response, displaying a second level of information detail that is greater in detail than the first level of information.
Claim 2. The method of Claim 1, the method steps further comprising: displaying additional machine information detail in response to the user selecting an area hot-spot with the cursor.
Claim 3. The method of Claim 1, the method steps further comprising: displaying a third level of information detail that is greater in detail than the second level of information, in response to the user selecting an area hot-spot with the cursor.
Claim 4. The method of Claim 1, the method steps further comprising: providing Stop-and-Go Video related to the machine information displayed.
Claim 5. The method of Claim 1, the method steps further comprising: providing Stop-and-Go Animation related to the machine information displayed.
Claim 6. The method of Claim 1, the method steps further comprising: providing an order form for automated ordering of replacement machine parts.
Claim 7. The method of Claim 1, the method steps further comprising: displaying a second image of a subcomponent of the machine in response to user selection by the cursor of an area of the first image, wherein the second image represents the subcomponent located within the user-selected area of the machine.
Claim 8. The method of Claim 7, the method steps further comprising: displaying Moving Shapes over the first image to approximate the location of the subcomponent.
Claim 9. A computer implemented interactive machine maintenance support system, the system comprising: a database device capable of providing detailed information regarding a given machine; a first computing device operably coupled with the database device and operably configured to provide a graphical user interface (GUI) capable of user interaction, the GUI comprising: a first area for displaying a first level of information detail regarding the machine, the first area including one or more hot-spots for user interaction; and a second area for displaying a second level of information detail that is greater in detail than the first level of information detail provided in the first area, wherein the second level of information is related to the first level of information, the second area including one or more hot-spots for user interaction, wherein a user may interact with a hot-spot by manipulating a cursor with respect to the first or second area hot-spots, wherein manipulation of the cursor occurs through manipulation by the user of an input device, and wherein interaction with a hot-spot in one area influences the information displayed in the other area.
Claim 10. The system of Claim 9, the GUI further comprising: a third area for displaying a third level of information detail that is greater than the second level of information, wherein the third level of information is related to the second level of information.
Claim 11. The system of Claim 9, wherein interaction with a hot-spot occurs when the cursor is placed over the hot-spot.
Claim 12. The system of Claim 9, wherein interaction with a hot-spot occurs when the cursor is placed over the hot-spot and the user selects the hot-spot by actuating a switch on the input device.
Claim 13. The system of Claim 9, wherein the information detail comprises multimedia.
Claim 14. The system of Claim 9, wherein the second area is capable of providing Stop-and-Go Video or Stop-and-Go Animation.
Claim 15. The system of Claim 9, wherein the second level of information detail comprises an electrical circuit schematic, and wherein related subcomponents of the electrical circuit schematic are grouped for functional representation in the second area display through use of differing colors, and wherein the colors change in relation to the troubleshooting steps performed.
Claim 16. The system of Claim 9, the GUI further comprising: an order feature for allowing the user to order machine repair parts based upon the repair information provided by the system.
Claim 17. The system of Claim 9, wherein the first level of information detail represents an Overall Block Diagram of a subcomponent of the machine, the second level of information detail represents an Intermediate Block Diagram of the subcomponent of the machine, and the third level of information represents a Detailed Block Diagram of the subcomponent of the machine.
Claim 18. The system of Claim 9, the system further comprising: a first image representative of the machine, wherein the first image changes in response to the user's interactions with either the first or second area hot-spots.
Claim 19. The system of Claim 18, wherein Moving Shapes appear on the first image in response to the user's interactions with the first or second area hot-spots.
The invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive. Accordingly, the scope of the invention is established by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Further, the recitation of method steps does not denote a particular sequence for execution of the steps. Such method steps may therefore be performed in a sequence other than that recited unless the particular claim expressly states otherwise.
This application claims the benefit of provisional Application No. 61/190,069, filed Aug. 26, 2008.
Number | Date | Country | |
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61190069 | Aug 2008 | US |