This invention relates to training devices and methods. More particularly, it relates to a device and method for use in teaching and demonstrating the principles and techniques of problem solving based on statistical concepts, Six Sigma, and lean manufacturing.
In conventional training for statistical, Six Sigma, lean manufacturing, and other process excellence applications, training devices previously have been used. Such devices have included small catapults designed to provide an output (i.e., the launching of a ball), which varies in response to certain inputs that can be varied (e.g, variable mechanical characteristics of the catapult).
These previously known devices, however, have suffered from a number of shortcomings. For example, they have been limited in setting input variables. Previously known devices do not offer the instructor the flexibility to vary inputs using a combination of discrete, continuous, FPI (foot-pound-inches) and SI (International System) units of measurement. Additionally, prior devices lack features and flexibility to demonstrate in a classroom environment or in the field how improvements in a design or process can be made. Also, in previous designs, output data collection is based on visual observation of the user and is susceptible to manual error. Retrieval of a launched ball, which is the output of the device, is inconvenient. Also, previously known devices are susceptible to damage and premature breakage, which requires significant repair efforts or even replacement of an entire unit. Typically, these devices have been manufactured from wood. This material can be severely affected by operational environment factors. A broken part calls for the replacement of an entire unit, making it expensive to repair or maintain. Previously known devices also use rubber bands to generate the force to launch balls, which are likely to relax, fail or wear without any prior warning. This will seriously impact the results of the operation by infecting the mathematical model between the input and output variables. In addition, previously known devices are inconvenient to store and transport. Moreover, as investment in training dollars have decreased, self-training has become desirable. Previously known devices, however, are inadequate to address this need.
There is a need, therefore, for an improved device and method for providing training for statistical, Six Sigma, lean manufacturing, and other process excellence applications. It is an object of the present invention to provide in improved training device and method that satisfies this need and that is easy to use.
Another object of the present invention is to provide a training device that is lightweight and portable and that can be readily disassembled for ease of packaging.
Yet another object of the present invention is to provide a training device that is relatively easy to manufacture, durable and that can be easily and inexpensively repaired without having to replace the entire device.
Still another object of the present invention is to provide a training device that is flexible enough to be used to train students of different skill levels such as beginner, intermediate and advanced.
Another objective of the present invention is to provide a training device with which a user can interactively exchange information electronically, thereby eliminating the probability of error in manual data transmission, saving time and money in training efforts and providing a device that can be used for online training sessions.
Additional objects and advantages of the invention will be set forth in the description that follows, and in part will be apparent from the description, or may be learned by practice of the invention. The objects and advantages of the invention may be realized and obtained by means of the instrumentalities and combinations pointed out in the appended claims.
To achieve the foregoing objects, and in accordance with the purposes of the invention as embodied and broadly described in this document, there is provided an improved training system and for teaching and demonstrating the principles of problem solving using tools and techniques of applied statistics, Six Sigma, lean manufacturing and other process excellence techniques. A training system according to the present invention includes an interactive catapult training device. The device includes a base and a hub fixed to a position with respect to the base and removable from the base. A swing arm is coupled to and rotatable about the hub from a first angle to a second angle, the swing arm being removable from the hub. A cup is fixed to a position with respect to the swing arm and adapted to receive a projectile, the cup being removable from the swing arm. A spring is coupled between a first coupling point fixed with respect to the base and a second coupling point on the swing arm. The spring provides tension for setting the swing arm in motion from the first angle to the second angle. The spring can be removable from the first and second coupling points. The device preferably also includes means for varying and measuring each of the first coupling point, the second coupling point, the first swing arm angle, the second swing arm angle, the hub position with respect to the base and the cup position with respect to the swing arm.
The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate the presently preferred embodiments of the invention and, together with the general description given above and the detailed description of the preferred methods and embodiments given below, serve to explain the principles of the invention.
a and 12b show graph sheets of a graphical measurement system according to the invention, which can be used to characterize the output of the training device as either linear distance of launch or angle of deviation of launch from the launch center line.
Although preferred embodiments and methods of the invention are described in the following description and illustrated in the accompanying drawings, it will be understood that the invention is not limited to the drawings disclosed, but is capable of numerous rearrangements, modifications, and substitutions of parts and elements without departing from the spirit of the invention. The present invention is therefore intended to encompass such rearrangements, modifications and substitutions of parts and elements as fall within the scope of the invention.
The present invention provides an improved training system for characterizing and optimizing a process output variable as a function of the process input variables to help the user comprehend how businesses today can reduce their internal cost of operation and grow their top line of sales for overall profitability.
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Integrated into the device base 12 is a self-retracting measuring tape 36. In a preferred embodiment, the measuring tape can be mounted in a recess 38 formed in the bottom surface of the base 12. The measuring tape 36 is aligned so that the tape 40 extends parallel to the base slotted track 14. A lip 42 disposed at the end of the tape of the arch extends beyond the edge of the base 12 and is held against the base by the spring tension of the self-retracing measuring tape. In this configuration, the measuring tape 36 can be used to measure the distance that a ball is launched by the training device 10. Integration of the measuring tape into the base 12 in this manner advantageously avoids having to provide a separate measuring tape which would have to be carried separately and is likely to be misplaced. The base recess 38 also can have hooks 44 mounted within it for storing one or more spring 30, such as during transportation or packaging.
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The tension spring 30 provides the required force for setting the swing arm 26 in motion to launch a ball. Using the spring 30 rather than a rubber band, such as has been used in previous devices, provides a number of advantages. One advantage is that the spring component allows for non-destructive testing and calibration via characterization prior to its use. The spring can be characterized using a tension meter to determine the effect of wear and tear if any. This is impossible with the prior art devices using rubber bands, as testing the rubber band will change its elasticity significantly unless destructive testing is employed at a significant cost in time and money. It will be understood that the tension spring 30 can be implemented using any suitable spring mechanism for providing the necessary spring action to launch a ball from the device.
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An alternative embodiment of the training device 10 can use a torsional, spring mechanism, similar to that found in an airline safety belt, which provides a rotational force about the arch hub 24. Such an embodiment eliminates the need for the linear arm 16. In addition, the arch 20 can be eliminated and additional hooks can be added to the swing arm 26 and base 12 to hold a string that measures the stop angle of the swing arm 26. A linear scale can be added to measure the starting angle position for the swing arm.
The fundamental component parts of the training device according to the present invention can be made of plastic with higher strength-to-weight ratio than that of materials used in previously known devices. The training components can be manufactured either by machining or injection molding processes. The components can be assembled for operation of the training device 10 and disassembled for convenience of storage and portability. They can be of the snap-fit type or threaded type for assembly and operation. For the securing the components in a packed configuration (see
Linear scales used for visual measurement of input variables can be universal. Different units of measurement or modes of input variables can be used. The device can be collapsed using Velcro patching for compact placement. Input and output data can be recorded manually, mechanically, or electronically. The device can be made out of metal, plastic or a combination for durability. Component parts can be made of material that is opaque or transparent for aesthetic appearance. A tape or pre-designed graph can measure the distance/angle output variable. A timer, such as an electronic timer or an integrated clock, can measure the output variable for cycle time. The linear arm can be moved based on the desired combination of input variables. The arch can be moved based on desired combination of input variables. The scales for unit of measurement can be separate or available in one universal system. Discrete input options can be offered through the design of the appropriate scales.
Advantageously, the system and method of the present invention can be used with an interactive system that supports e-learning and online remote instruction. The input and output data can be managed electronically. For example, scanner technology can be used to sense the setting of input variables. Rather than an impact sheet, membrane technology can be used to track the output variable data by recording the point of impact of balls launched by the device. The input and output data can than be transmitted to a user. A two-way digital signal processor can be used to acquire input and output data for receipt and transmission. Electronic data can exchanged wirelessly locally using a wireless technology such as Blutetooth technology or over the Internet using a PDA or other wireless device connected to the Internet.
To operate the training device 10, it must first be assembled. A preferred sequence of assembly of the components and set up of the device will now be described. Preferably, the device is used on a table top. The annular arch 20 is mounted to the base 12 by fitting the arch base 25 into the base slotted track 14 and securing it in place with the arch set screws 72. The linear arm 16 is mounted to the base 12 by fitting the tab 54 into the base slotted track 14 and securing it in place with the linear arm clamping screw 56. The user can then align the base 12 with the edge of the table top 33, as shown in
To launch balls with the assembled device 10, a user places the the graph sheet 84, a transparent sheet 92 and the pressure sheet 90 the with the right graph and left graph portions located on either side of a center line that aligns with the base slotted track 14, as described above. The user then places a ball in the ball cup 32 and pulls the swing arm 26 back toward the portion of the base 12 held by the C-clamps 35 until the swing arm 26 is stopped by the rear clamp bracket 74. When the user releases the swing arm 26, the tension spring 30 will pull the swing arm 26 forward and launch the ball. When the ball lands on the impact sheet 90, it will mark the transparent sheet 92 at the point of impact. The user can measure the point of impact using the graph sheet 84. It is then left to the choice of the user and instructor on how to manage the input variables to modify the launch of the ball and to collect data to create mathematical models. The input variables can be measured using FPI and/or SI Units of measurement and can be varied either discretely or continuously.
The output variables that can be monitored include the linear distance from the base 12, the angle of deviation either to the left or right of the center line of the base 12, and the cycle time conduct a given operation. The linear distance output variable can be measured using the integrated measuring tape 36 or the graphical measurement system previously described, which provides the user and instructor greater speed, accuracy and precision in comparison to the measuring tape 36.
The training device 10 can be disassembled as follows for convenient and compact storage in a storage box (not shown). The ball cup 32 can be loosened and removed from the swing arm 26, leaving the swing arm bracket 60 in place. The arch clamp brackets 74 can be loosened and moved apart on the arch 20, leaving them positioned on the arch 20. The spring 30 can be removed from the hooks 50, 64 and stored in the base recess 38 after the C-clamps 35 are removed. The swing arm 26 can be removed by loosening the hub bolt 29, washer and nut. The linear arm 16 can be removed from the base 12 by unscrewing the clamping screw 56. The annular arch 20 with clamp brackets 74 can be removed from the base 12 by unscrewing the arch screws 72. All of these components can be stored in the storage box along with balls used for launching.
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As can be seen form the foregoing, the device according to the invention has numerous benefits over previously known devices. It is versatile and easy to use for both instructors and students. It provides a significantly higher number of controllable input variables than do previous devices, as well as multiple output variables, for simulating actual processes. It provides options for variable input or output technology based on the appropriate level of training. It provides options to address different skill levels of training for user and instructor in applied statistics. A user or instructor at a very basic level has the choice to either restrict the use of the system to meet his simple needs or utilize the available options for advanced learning and application. It can be set up in various configurations by removing or substituting certain components without changing the fundamental component parts. It can be used to demonstrate the effects of variables in any given process and is not limited to any specific industry or process application. It is versatile enough to demonstrate the advantages of incorporating continuous inputs technology and data transfer technology. The invention is applicable to and suits academic, industrial, government, military as well as nonprofit business operation type environments. With the device of my invention, training is faster and costs less time and manpower to operate. It makes true mathematical modeling possible.
The device of my invention also is easy to use and provides improved speed, ease, precision and accuracy of measurement. It utilizes an integrated, graphic input and output measurement system that reduces time and error in measuring time, angle and distance output variables. The system can use a combination of discrete, continuous, FPI and SI units of measurement by simply swapping appropriate linear scales. The system effectively eliminates the possibility of error in the setting of the input variables. The inputs and outputs can be managed manually or electronically. Management of the inputs and outputs electronically can allow for instruction and use of the training system by people with a limited mobility, hearing, sight, or our use of their hands. The electronic data management also can allow for avoiding mistakes in the input process, such as by using an alert system to warn the user in the event an input variable is in error, thereby eliminating the chance of an unwanted run or operating step. Recording the data electronically or through an automated measurement system, as opposed to reading it visually, also can help eliminate or reduce errors as well as the system operation time. Because it is easy to use, the device allows the user and instructor to manage in-class training activity with less manpower and without a group of trainees per system and trainees having to necessarily leave their desk for practical demonstration sessions.
The device of my invention is easy and inexpensive to manufacture and repair. It can be fabricated using automated machining processes, thereby eliminating the opportunities for variation due to operator skills. Its components can be constructed of durable, lightweight material that is resistant to wear. If a component is damaged, it can be replaced without the need of replacing the entire device. The device is easy to store and transport. It is lightweight and can be readily disassembled for storage and transportation.
The device is suitable for use in e-training or online training. Because input and output variable data can be managed electronically, e training can be achieved through Internet web hosting of the input and output variable data, either locally or remotely.
It will be understood by those of ordinary skill in the art that other arrangements and disposition of the aforesaid components, the descriptions of which are intended to be illustrative only and not limiting, may be made without departing from the spirit and scope of the invention, which must be identified and determined from the following claims and equivalents thereof.
This application is based on and claims the benefit of U.S. Provisional Patent Application No. 60/549,592 filed on Mar. 2, 2004, the disclosure of which is incorporated herein by this reference.
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4111179 | Hashimoto | Sep 1978 | A |
4327913 | Bock | May 1982 | A |
4860717 | Powell et al. | Aug 1989 | A |
6182648 | Lundgren | Feb 2001 | B1 |
6343597 | Spikes | Feb 2002 | B1 |
Number | Date | Country | |
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20050279339 A1 | Dec 2005 | US |
Number | Date | Country | |
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60549592 | Mar 2004 | US |