Control system for, and method of, operating toy vehicles

Information

  • Patent Grant
  • 6666746
  • Patent Number
    6,666,746
  • Date Filed
    Thursday, May 23, 2002
    22 years ago
  • Date Issued
    Tuesday, December 23, 2003
    21 years ago
Abstract
Each of first vehicles has an individual address dependent upon an insertion of a selective one of different keys into a socket in the vehicle. Each vehicle is movable in any desired direction on a first support structure formed by intercoupling male detents on first beams and female detents on other beams and on blocks. The first support structure may be, but does not have to be, intercoupled with a second support structure. The second structure may define a track on which an additional vehicle (e.g., a monorail) is movable in first and second opposite directions. Each of a plurality of manually operated pads generates signals for addressing any unaddressed vehicle and for providing movements of, and the performance of functions in, the vehicle when addressed. Each pad communicates the pad-generated signals to a connected central station. The central station communicates these signals by wireless to the vehicles.
Description




This invention relates to a system for pleasurable use by people of all ages with youthful minds in operating remotely controlled vehicles simultaneously in a somewhat confined area. In the system of this invention, the vehicles can be remotely controlled to perform competitive or cooperative tasks. The system of this invention includes pads for operation by the users, vehicles remotely controlled in accordance with the operation of the pads and a central station for coordinating the operation of the pads and the vehicles. The invention additionally relates to methods of controlling the operation of the vehicles on a remotely controlled basis.




The system and method of this invention include first and second intercoupled support structures which may, but do not have to be, intercoupled. The first support structure provides for the movement of first vehicles in any direction on the support structure. The second support structure provides a track for a movement of an additional vehicle on the track. The additional vehicle may be a monorail. The first and second support structures are formed from coupling members (e.g. beams), all of the same construction, intercoupled to one another and to blocks, all of the same construction.




BACKGROUND OF THE PREFERRED EMBODIMENT




Various types of play systems exist, and have existed for some time, in which vehicles are moved on a remotely controlled basis. However, such systems generally provide one hand-held unit and one remotely controlled vehicle for operation by the hand-held unit. Examples of a vehicle in such a system are a toy automobile or a toy airplane. Furthermore, the functions of the remotely controlled unit, other than movement along a floor or along the ground or in the air, are quite limited.




Other types of play systems involve the use of blocks for building structures. These blocks often include detents for providing an interlocking relationship between abutting blocks. In this way, elaborate structures can be created by users with creative minds. These systems do not involve the use of a plurality of vehicles, each of which is individually addressed and each of which is controlled on a remote basis.




Tests have indicated that there is a desirability, and even a need, for play systems in which vehicles are remotely operated to perform functions other than to move aimlessly along a floor or along the ground. For example, tests have indicated that there is a desirability, and even a need, for play systems in which the remotely controlled vehicles can transport elements such as blocks to construct creative structures. There is also a desirability, and even a need, for play systems in which a plurality of vehicles can be remotely controlled by switches in hand-held pads to compete against one another in performing a first task or to cooperate in performing a second task. Such a desirability, or even a need, has existed for a long period of time, probably decades, without a satisfactory resolution.




U.S. Pat. No. 5,944,607 issued to John J. Crane on Aug. 31, 1999, for a “Remote Control System for Operating Toys” and assigned of record to the assignee of record of this application discloses and claims a play system for use by people of all ages with youthful minds. It provides for a simultaneous control by each player of an individual one of a plurality of remotely controlled vehicles. This control is provided by the operation by each player of switches in a hand-held unit or pad. The operation of each switch in such hand-held unit provide for an addressing of an individual one of the remotely controlled vehicles and for a control of a different function in the vehicle. Each of the remotely controlled vehicles in the system disclosed and claimed in U.S. Pat. No. 5,944,607 can be operated in a competitive relationship with others of the remotely controlled vehicles or in a cooperative relationship with others of the remotely controlled vehicles. The vehicles can be constructed to pick up and transport elements such as blocks or marbles and to deposit such elements at displaced positions.




When manually closed in one embodiment of the system disclosed and claimed in U.S. Pat. No. 5,944,607, switches in pads control the selection of toy vehicles and the operation of motors for moving the selected vehicles forwardly, rearwardly, to the left and to the right and control the movement moving upwardly and downwardly (and rightwardly and leftwardly) of a receptacle for holding transportable elements (e.g. marbles or blocks).




When interrogated by a central station, each pad in the system disclosed and claimed in U.S. Pat. No. 5,944,607 sends through wires to the central station signals indicating the switch closures in such pad. Such station produces first binary signals addressing the vehicle selected by such pad and second binary signals identifying the motor control operations in such vehicle. Thereafter the switches identifying in such pad the motor control operations in such selected vehicle can be closed without closing the switches addressing such vehicle. The central station then identifies the vehicle on the basis of the command signals from the pad even though the pad does not identify the vehicle. The central station identifies the vehicle in this manner because the central station stores the relationship between the pad and the vehicle.




The first and second signals for each vehicle in the system disclosed and claimed in U.S. Pat. No. 5,944,607 are transmitted by wireless by the central station to all of the vehicles at a common carrier frequency modulated by the first and second binary signals. The vehicle identified by the transmitted address demodulates the modulating signals and operates its motors in accordance with such demodulation. When the vehicle fails to receive signals from a pad for a particular period of time, the vehicle previously selected by such pad becomes available for selection by that pad or any other pad and that pad can select that vehicle or another vehicle.




In the preferred embodiment disclosed and claimed in U.S. Pat. No. 5,888,135 issued on Mar. 30, 1999, and assigned of record to the assignee of record of this application, a key in a vehicle socket closes contacts to reset a microcontroller in the vehicle to a neutral state. Ribs disposed in a particular pattern in the key operate switches in a particular pattern in the vehicle to provide an address for the vehicle and to dispose the vehicle in an inactive but powered state.




As disclosed and claimed in U.S. Pat. No. 5,888,135, when the vehicle receives such individual address from an individual one of the pads, the vehicle is operated by commands transmitted by the pad to the vehicle within a first particular time thereafter. Such individual pad operates such vehicle as long as such vehicle receives commands from such individual pad within the first particular period after the previous command from such individual pad. During this period, the vehicle has a first illumination to indicate that it is being operated in an active and powered state.




When the individual pad in U.S. Pat. No. 5,888,135 fails to provide commands to such vehicle within such first particular time period, the vehicle becomes inactive but powered and provides a second illumination. While inactive but powered, the vehicle can be addressed and subsequently commanded by any pad including the individual pad and the addressing pad thereafter commands the vehicle. The vehicle becomes deactivated and not illuminated if (a) the vehicle is not selected by any of the pads during a second particular time period after becoming inactivated but powered or, alternatively, (b) all of the vehicles become inactivated but powered and none is selected during the second particular period. The key can thereafter be actuated to operate the vehicle to the inactive but powered state.




U.S. Pat. No. 5,826,394 issued on Oct. 27, 1998, and assigned of record to the assignee of record of this application discloses and claims preferred embodiments of coupling members (e.g. beams) which can be intercoupled or can be coupled to blocks to form support structure on which the vehicles can be transported in any desired direction. Each of the beams has the same male detents, and the same female detents, as the other beams. The blocks have only the female detents. The male detent on each beam intercouples with a female detent on any other coupling beam, or intercouples with one of the female detents on one of the blocks, to form the support structure. This support structure can be of any complex configuration involving some creativity. The support structure can have any desired configuration. Furthermore, the female detents on a single block can operate in conjunction with a number of beams to extend the support structure in as many as six (6) different directions. The male and female detents can be easily coupled to one another and can be easily separated from one another. However, when the beams are intercoupled or the beams and blocks are intercoupled, a strong and effective relationship exists between them.




An opening is provided in at least a particular one of the faces, and preferably in the four (4) faces defining a closed loop, in the beam disclosed and claimed in U.S. Pat. No. 5,826,394. These openings define the female detents. Substantially parallel snaps extend from the other two (2) beam walls and have at their outer ends portions shaped to facilitate (a) insertion of such snaps into the opening in the particular face of the block or into the opening in a face of another beam, (b) retention of the snaps by the inner surface of the face defining the opening and (c) removal of the snaps from the opening. Such portions are shaped for the snaps on the beams to be pulled, peeled or bent from the faces in the blocks. When the beams become decoupled from the blocks the snaps may be considered as the male detents.




When the block disclosed and claimed in U.S. Pat. No. 5,826,394 has an opening in each of its six (6) faces, snaps from six (6) different beams can extend into the six (6) different openings in six (6) different directions in the block without any interference in the block between the snaps in the six (6) beams. In this way, complex structures can be formed from the blocks and the beams. Other structures such as vehicle ramps, building roofs, awnings and corbels can be disposed in cooperative relationship with structure formed from the blocks and the beams and can be intercoupled into the supporting structure by male and female detents in the vehicle ramps, building roofs, awnings and corbel.




Since the block and the beams disclosed and claimed in U.S. Pat. No. 5,826,394 have the shapes of rectangular prisms, they have a uniform disposition on a support surface such as a floor or a table. Furthermore, since such block preferably has six (6) faces all of substantially identical construction and all defining female detents, children can easily assembly the snaps at either of the opposite ends of the beam into the opening in any one of the faces in the block without affecting the relationship between the block and the beam when other beams are attached to other faces of the block.




The blocks and the beams disclosed and claimed in U.S. Pat. No. 5,826,394 also have other advantages. Only blocks and beams are required to construct complex structures. This is in contrast to the prior art where a number of different types of members are required to construct complex structures. Furthermore, the openings in the blocks in the system of this invention constitute female members. This provides for a universality in the use of the blocks. When the blocks have openings in all six (6) of their faces, any of the faces can be coupled to one of the beams. This enhances the universality in the usage of the system in constructing creative structures of some complexity.




The blocks and beams have been disclosed in U.S. Pat. No. 5,826,394 as being preferably rectangular. However, the beams can be curved in any desired shape as a practical manner without departing from the scope of the preferred embodiment disclosed in U.S. Pat. No. 5,826,394. Even when curved, the beam can be intercoupled with a block and with other beams in the same manner as described above.




BRIEF DESCRIPTION OF THE INVENTION




The preferred embodiment of this invention utilizes features disclosed and claimed in U.S. Pat. No. 5,944,607, U.S. Pat. No. 5,888,135 and U.S. Pat. No. 5,826,394, all assigned of record to the assignee of record of this application. The preferred embodiments of this invention combine these features with features individual to the preferred embodiments of this invention to obtain a unique and patentable toy system with enhanced features. In this toy system, one of the vehicles can constitute a monorail constructed to ride on a track formed from the beams and the blocks.




In a preferred embodiment of this invention, each of first vehicles has an individual address dependent upon an insertion of a selective one of different keys into a socket in the vehicle. Each of the first vehicles is movable in any desired direction on a first support structure formed by intercoupling male detents on first beams and female detents on other beams, all of them having the same construction, and by intercoupling the male detents on the beams to female detents on blocks, all having an identical construction.




The first support structure may be, but does not have to be, intercoupled with a second support structure formed by intercoupling beams and blocks of the same type as the beams and blocks in the first structure. The second structure defines a track on which an additional vehicle addressable in the same manner as the first vehicles is movable in first and second opposite directions. The additional vehicle may constitute a monorail.




The additional vehicle has rollers for driving the vehicle (e.g., monorail) on the track and has guides (e.g., positioning rollers) disposed contiguous to the side surfaces of the track blocks for retaining the vehicle on the track during the vehicle movement on the track. Each vehicle has motor(s) for moving the vehicle on its support structure and has members for performing function(s) other than vehicular movements. The members may be controlled by motors different from the motors for moving the vehicles.




Each of a plurality of manually operated pads generates signals for addressing any unaddressed vehicle (including the first vehicles and the additional vehicle) and for providing movements of, and the performance of functions in, the vehicle when addressed. Each pad may control the operation of one of the vehicles not addressed by the other pads. Each pad communicates to a central station the signals generated by the pad. This communication is through wires connected between the pad and the central station. The central station communicates these signals by wireless to the vehicles.











BRIEF DESCRIPTION OF THE DRAWINGS




In the drawings:





FIG. 1

is a schematic diagram, primarily in block form, of a system constituting one embodiment of the invention;





FIG. 2

is a schematic diagram, primarily in block form, of the different features in a pad included in the system shown in

FIG. 1

;





FIG. 3

is a schematic diagram, primarily in block form, of the different features included in a central station included in the system shown in

FIG. 1

;





FIG. 4

is a schematic diagram, primarily in block form, of the different features in a vehicle included in the system shown in

FIG. 1

;





FIG. 5

is an exploded perspective view of a vehicle and a key which is insertable into a socket in the vehicle to provide an individual address for the vehicle;





FIG. 6

is a top plan view of the vehicle and the key with the key inserted into the vehicle;





FIG. 7

is an enlarged perspective view of the key as seen from a position in front of and to one side of the key;





FIG. 8

is an enlarged perspective view of the key as seen from a position in back of and to one side of the key;





FIGS. 9



a


-


9




h


are front elevational views of different keys each with an individual combination of ribs to provide an individual address in accordance with the individual combination of the ribs, to a vehicle in which such key is inserted;





FIGS. 10



a


-


10




h


are bottom plan views respectively of the keys shown in

FIGS. 9



a


-


9




h


and particularly show the disposition of the ribs which provide the individual address for each of the different keys;





FIG. 11

is a fragmentary side elevational view, partly in section, of a vehicle and a key with the key partially inserted into a socket in the vehicle and shows the disposition of first switches in the vehicle with such partial insertion of the key into the socket;





FIG. 12

is a fragmentary side elevational view, partly in section, of the vehicle and key shown in FIG.


11


and is similar to

FIG. 11

except that it shows the key fully inserted into the socket in the vehicle and shows the disposition of the first switches in the vehicle with such full insertion of the key into the socket;





FIG. 13

is a fragmentary side elevational view, partly in section, of the vehicle and the key shown in

FIGS. 11 and 12

and shows a first particular disposition of the key in the vehicle socket and the disposition of electrical contacts in the vehicle with such a relationship between the key and the vehicle;





FIG. 14

is a fragmentary side elevational view, partly in section, of the vehicle and the key shown in

FIGS. 11-13

and shows a second particular disposition of the key in the vehicle socket and the disposition of the electrical contacts in the vehicle with the key in the second particular disposition in the vehicle socket;





FIG. 15

is a fragmentary side elevational view, partly in section, of the vehicle and the key shown in

FIGS. 11-14

and shows a third particular disposition of the key in the vehicle socket and the disposition of the electrical contacts in the vehicle with the key in the third particular disposition in the vehicle socket;





FIG. 16

is a perspective view of a block constituting one of the basic members for building a complex structure of any desired creativity for supporting the vehicles shown in the previous Figures;





FIG. 17

is an enlarged exploded perspective view of two (2) duplicative sections which can be combined to form the block shown in

FIG. 15

;





FIG. 18

is a perspective view of a beam which can be cooperatively coupled to the block shown in

FIG. 16

to provide for the creation of complex structures when a plurality of blocks and beams are coupled to one another in original patterns;





FIG. 19

is an enlarged exploded perspective view of two (2) duplicative sections which can be combined to form the beam shown in

FIG. 18

;





FIG. 20

is a schematic perspective view of the block and the beam in an exploded relationship and shows how the beam can be coupled to the block;





FIG. 21

is an elevational view of the block and the beam in a coupled relationship with the block partially broken away to show how the block and the beam are coupled to each other;





FIG. 22

is a view similar to that shown in FIG.


21


and shows the beam partially removed from the block when a force indicated by an arrow is imposed on the beam in a direction away from the block;





FIG. 23

is a view similar to that shown in

FIGS. 21 and 22

and shows the beam partially removed form the block when a bending force indicated by an arrow is imposed on the beam;





FIG. 24

is a view similar to that shown in

FIGS. 21-23

and shows the beam partially removed from the block when a bending force indicated by an arrow is imposed on the beam, the bending force being displaced by an angle of substantially 90° from the bending force shown in

FIG. 23

;





FIG. 25

is a perspective view of a member which incorporates the features of this invention and which has utility as a ramp, an awning or a roof;





FIG. 26

is a perspective view of another member which incorporates the features of this invention and which constitutes a corbel;





FIG. 27

is a perspective view of a simple structure which can be formed from the blocks, the beams, a pair of the roofs, a ramp and several corbels, all of which are shown in the

FIGS. 16-27

;





FIG. 28

constitutes a perspective view of a vehicle (e.g. a monorail) which is movable in selective ones of two (2) opposite directions on a track;





FIG. 29



a


is an elevational view of one embodiment of a vehicular track, and of supports extending from a support surface to the vehicular track, to dispose the track at a position raised from the support for receiving the vehicle shown in

FIG. 28

, the track and the supports being made from the beams and blocks shown in

FIGS. 16-27

;





FIG. 29



b


is an elevational view of another embodiment of a vehicular track and supports made from the beams and blocks shown in

FIGS. 16-27

;





FIG. 30

is a fragmentary plan view of a vehicular track formed from the beam and blocks shown in

FIGS. 16-27

and including beams with curved configurations;





FIG. 31

is an elevational view, partially broken away, of the vehicle (e.g. monorail) shown in

FIG. 28

;





FIG. 32

is a schematic perspective view of a vehicular track for receiving the vehicle shown in

FIG. 28

, the vehicular track being disposed in a closed loop formed from a plurality of interconnected segments extending in different directions;





FIG. 33

is a schematic perspective view of support structure for a movement of vehicles (e.g.

FIG. 1

) in any desired direction and of a track for movement of the monorail (

FIGS. 28 and 31

) and particularly shows a conveyor for loading play elements (e.g. marbles) into the monorail and an arrangement for transferring the play elements from the monorail into vehicles (e.g. FIG.


1


);





FIG. 34

is a schematic perspective view of support structure for the vehicles shown in FIG.


11


and of a track for the monorail shown in

FIGS. 28 and 31

and additionally shows the conveyor also shown in

FIG. 33

;





FIG. 35

is a schematic perspective view of another form of support structure for the vehicles shown in FIG.


1


and then form of the track for the monorail shown in

FIGS. 28 and 31

and the conveyor shown in

FIGS. 33 and 34

;





FIG. 36

is a schematic perspective view of still another form of support structure for the vehicles shown in FIG.


1


and another form of the track for the monorail shown in

FIGS. 28 and 31

and the conveyor shown in

FIGS. 33 and 34

;





FIG. 37

is a schematic elevational view of the track and the monorail on the track and shows how the vehicle is retained on the track during the movement of the monorail on the track;





FIG. 38

is a schematic perspective view of the monorail as seen from a position below the vehicle and shows the arrangement for driving the monorail on the track and for retaining the monorail on the track during the movement of the monorail on the track;





FIG. 39

is an elevational view of the monorail including a bin or acceptable for receiving play elements (e.g. marbles) as from the conveyor shown in

FIGS. 33-36

and for transferring the play elements to bins or containers in the vehicles shown in

FIG. 11

; and





FIG. 40

is an elevational view of the monorail including the bin or receptacle for transferring the play elements (e.g. marbles) in the monorail to the bin or container in one of the vehicles shown in FIG.


1


.











DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION




In one embodiment of the invention, a system generally indicated at


10


in

FIG. 1

is provided for controlling the selection and operation of a plurality of toy vehicles. Illustrative examples of toy vehicles constitute a dump truck generally indicated at


12


, a fork lift generally indicated at


14


, a skip loader generally indicated at


16


and another form of skip loader generally indicated at


17


. The toy vehicles such as the dump truck


12


, the fork lift


14


and the skip loaders


16


and


17


are simplified versions of commercial units performing functions similar to those performed by the toy vehicles


12


,


14


,


16


and


17


. For example, the dump truck


12


may include a working or transport member such as a pivotable bin or container


18


; the fork lift


14


may include a working or transport member such as a pivotable platform


20


; the skip loader


16


may include a working or transport member such as a pivotable bin or container


22


disposed at the front end of the skip loader; and the skip loader


17


may include a working or transport member such as a pivotable bin or container


23


disposed at the rear end of the skip loader. The working or transport members such as the pivotable bin or container


18


, the pivotable platform


20


and the pivotable bins or containers


22


and


23


are constructed to carry storable and/or transportable elements such as blocks


24


or marbles


26


shown schematically in FIG.


1


. The marbles


26


may be constructed in a manner similar to that disclosed and claimed in patent 5 issued on [date] and assigned of record to the assignee of record in this application.




Each of the dump truck


12


, the fork lift


14


and the skip loaders


16


and


17


may include a plurality of motors. For example, the dump truck


12


may include a pair of reversible motors


28


and


30


(

FIG. 4

) operable to move the dump truck forwardly, rearwardly, to the right and to the left. The motor


28


controls the movement of the front and rear left wheels and the motor


30


controls the movement of the front and rear right wheels.




When the motors


28


and


30


are simultaneously operated in one direction, the dump truck


12


moves forwardly. The vehicle


12


moves rearwardly when the motors


28


and


30


are operated in the opposite direction. The vehicle


12


turns toward the left when the motor


30


is operated without simultaneous operation of the motor


28


. The vehicle


12


turns toward the right when the motor


28


is operated without a simultaneous operation of them motor


30


.




The vehicle


12


spins to the left when the motor


30


operates to move the vehicle forwardly at the same time that the motor


28


operates to move the vehicle rearwardly. The vehicle


12


spins to the right when the motors


28


and


30


are operated in directions opposite to the operations of the motors in spinning the vehicle to the left.




Another reversible motor


32


in the dump truck


12


operates in one direction to pivot the bin


18


upwardly and in the other direction to pivot the bin downwardly. An additional motor


33


may operate in one direction to turn the bin


18


to the left and in the other direction to turn the bin to the right.




The construction of the motors


28


,


30


,


32


and


33


and the disposition of the motors in the dump truck to operate the dump truck are considered to be well known in the art. The fork lift


14


and the skip loaders


16


and


17


may include motors corresponding to those described above for the dump truck


12


.




The system


10


may also include stationary plants or accessories. For example, the system


10


may include a pumping station generally indicated at


34


(

FIG. 1

) for pumping elements such as the marbles


26


through a conduit


36


. The system may also include a conveyor generally indicated at


38


for moving the elements such as the marbles


26


upwardly on a ramp


40


. When the marbles reach the top of the ramp


40


, the elements such as the marbles


26


may fall into the bin


18


in the dump truck


12


or into the bin


22


in the skip loader


16


. For the purposes of this application, the construction of the pumping station


34


and the conveyor


38


may be considered to be within the purview of a person of ordinary skill in the art.




The system


10


may also include a plurality of hand-held pads generally indicated at


42




a


,


42




b


,


42




c


and


42




d


(FIG.


1


). Each of the pads


42




a


,


42




b


,


42




c


and


42




d


may have a substantially identical construction. Each of the pads may include a plurality of actuatable buttons. For example, each of the pads may include a 4-way button


44


in the shape of a cross. Each of the different segments in the button


44


is connected to an individual one of a plurality of switches


46


,


48


,


50


and


52


in FIG.


2


.




When the button


44


is depressed at the segment at the top of the button, the switch


46


is closed to obtain the operation of the motors


28


and


30


(

FIG. 4

) in moving the selected one of the vehicle


12


forwardly. Similarly, when the segment at the bottom of the button


44


is depressed, the switch


48


is closed to obtain the operation of the motors


28


and


30


(

FIG. 4

) in moving the vehicle


12


rearwardly. The selective depression of the right and left segments of the button


44


cause the motors


28


and


30


to operate in spinning the vehicle in individual ones of the two (2) opposite directions.




It will be appreciated that pairs of segments of the button


44


may be simultaneously depressed. For example, the top and left portions of the button


44


may be simultaneously depressed to obtain a simultaneous movement of the vehicle


12


forwardly and to the left. This is in accordance with the operation of a microcontroller which will be described in detail subsequently. However, a simultaneous actuation of the top and bottom segments of the button


44


will not have any effect since they represent contradictory commands. This is also true of a simultaneous depression of the left and right segments of the button


44


.




Each of the pads


42




a


,


42




b


,


42




c


and


42




d


may include a button


56


(

FIG. 1

) which is connected to a switch


57


(FIG.


2


). Successive depressions of the button


56


on one of the pads within a particular period of time cause different ones of the stationary accessories or plants such as the pumping station


34


and the conveyor


38


to be energized. For example, a first depression of the button


56


in one of the pads


42




a


,


42




b


,


42




c


and


42




d


may cause the pumping station


34


to be energized and a second depression of the button


56


within the particular period of time in such pad may cause the conveyor


38


to be energized. When other stationary accessories are included in the system


10


, each may be individually energized by depressing the button


56


a selective number of times within the particular period to time. When the button


56


is depressed twice within the particular period of time, the energizing of the pumping station


34


is released and the conveyor


38


is energized. This energizing of a selective one of the stationary accessories occurs at the end of the particular period of time.




A button


58


is provided in each of the pads


42




a


,


42




b


,


42




c


and


42




d


to select one of the vehicles


12


,


14


,


16


and


17


. In the system disclosed and claimed in application Ser. No. 08/580,753, the individual one of the vehicles


12


,


14


,


16


and


17


selected at any instant by each of the pads


42




a


,


42




b


,


42




c


and


42




d


is dependent upon the number of times that the button


58


is depressed in that pad within a particular period of time. The system disclosed and claimed in this invention operates in a similar manner. For example, one (1) depression of the button


58


may cause the dump truck


12


to be selected and two (2) sequential selections of the button


58


within the particular period of time may cause the fork lift


14


to be selected.




Every time that the button


58


is actuated or depressed within the particular period of time, a switch


59


(in

FIG. 2

) is closed. The particular period of time for depressing the button


58


may have the same duration as, or a different direction than, the particular period of time for depressing the button


56


. An adder is included in the pad


12


to count the number of depressions of the button


58


within the particular period of time. This count is converted into a plurality of binary signals indicating the count. The count is provided at the end of the particular period of time. The binary signals in the plurality indicate the individual one of the vehicles


12


,


14


,


16


and


17


to be addressed.




Buttons


60




a


and


60




b


are also included on each of the pads


42




a


,


42




b


,


42




c


and


42




d


. When depressed, the buttons


60




a


and


60




b


respectively close switches


62




a


and


62




b


in FIG.


2


. The closure of the switch


62




a


is instrumental in producing an operation of the motor


32


in a direction to lift the bin


18


in the dump truck


12


when the dump truck has been selected by the proper number of depressions of the button


58


within the particular period of time. In like manner, when the dump truck


12


has been selected by the proper number of depressions of the switch


58


within the particular period of time, the closure of the switch


62




b


causes the bin


18


in the dump truck


12


to move downwardly as a result of the operation of the motor


32


in the reverse direction.




It will be appreciated that other controls may be included in each of the pads


42




a


,


42




b


,


42




c


and


42




d


. For example, buttons


61




a


and


61




b


may be included in each of the pads


42




a


,


42




b


,


42




c


and


42




d


to pivot the bin


18


to the right or left when the vehicle


12


has been selected. Such movements facilitate the ability of the bin


18


to scoop elements such as the blocks


24


and the marbles


26


upwardly from the floor or ground or from any other position and to subsequently deposit such elements on the floor or ground or any other position.




Switches


63




a


and


63




b


(

FIG. 2

) are respectively provided in the pad


42




a


in association with the buttons


61




a


and


61




b


and are closed by the respective actuation of the buttons


61




a


and


61




b


to move the bin or the platform in the vehicle


12


to the left or right when the vehicle has been selected. It will be appreciated that different combinations of buttons may be actuated simultaneously to produce different combinations of motions. For example, a bin in a selected one of the vehicles may be moved at the same time that the selected one of the vehicles is moved.




A central station generally indicated at


64


in

FIG. 1

processes the signals from the individual ones of the pads


42




a


,


42




b


,


42




c


and


42




d


and sends the processed signals to the vehicles


12


,


14


,


16


and


17


when the button


58


on an individual one of the pads has been depressed to indicate that the information from the individual ones of the pads is to be sent to the vehicles. The transmission may be on a wireless basis from an antenna


68


(

FIG. 10

in the central station to antennas


69


on the vehicles.




The transmission may be in packets of signals. This transmission causes the selected ones of the vehicles


12


,


14


,


16


and


17


to perform individual ones of the functions directed by the depression of the different buttons on the individual ones of the pads. When the commands from the individual ones of the pads


42




a


,


42




b


,


42




c


and


42




d


are to pass to the §stationary accessories


34


and


38


as a result of the depression of the buttons


56


on the individual ones of the pads, the central station processes the commands and sends signals through cables


70


to the selected ones of the stationary accessories.





FIG. 2

shows the construction of the pad


42




a


in additional detail. It will be appreciated that each of the pads


42




b


,


42




c


and


42




d


may be constructed in a substantially identical manner to that shown in FIG.


2


. As shown in

FIG. 2

, the pad


42




a


includes the switches


46


,


48


,


50


and


52


and the switches


57


,


59


,


62




a


,


62




b


,


63




a


and


63




b


. Buses


74


are shown as directing indications from the switches


46


,


48


,


50


,


52


,


57


,


59


,


62




a


,


62




b


,


63




a


and


63




b


to a microcontroller generally indicated at


76


in FIG.


2


. Buses


78


are shown for directing signals from the microcontroller


76


to the switches.




The microcontroller


76


is shown as including a read only memory (ROM)


80


and a random access memory (RAM)


82


. Such a microcontroller may be considered to be standard in the computing industry. However, the programming in the microcontroller and the information stored in the read only memory


80


and the random access memory


82


are individual to this invention.




The read only memory


80


stores permanent information and the random access memory stores volatile (or impermanent) information. For example, the read only memory


80


may store the sequence in which the different switches in the pad


42




a


provide indications of whether or not they have been closed. The random access memory


82


may receive this sequence from the read only memory


80


and may store indications of whether or not the switches in the particular sequence have been closed for each individual one of the pads


42




a


,


42




b


,


42




c


and


42




d.






The pad


42




a


in

FIG. 2

receives the interrogating signals from the central station


64


through a line


84


. These interrogating signals are not synchronized by clock signals on a line


86


. Each of the interrogating signals intended for the pad


42




a


may be identified by an address individual to such pad. When the pad


42




a


receives such interrogating signals, it sends to the central station


64


through lines


88


a sequence of signals indicating the status of the successive ones of the switches


46


,


48


,


50


and


52


and the switches


57


,


59


,


62




a


,


62




b


,


63




a


and


63




b


. These signals are synchronized by the clock signals on the line


86


. It will be appreciated that the status of each of the switches


57


and


59


probably is the first to be provided in the sequence since these signals indicate the selection of the stationary accessories


34


and


38


and the selection of the vehicles


12


,


14


,


16


, and


17


.




As previously indicated, the pad


42




a


selects one of the vehicles


12


,


14


,


16


and


17


in accordance with the number of closings of the switch


59


. As the user of the pad


42




a


provides successive actuations or depressions of the button


58


, signals are introduced to a shift register


90


through a line


92


to indicate which one of the vehicles


12


,


14


,


16


and


17


would be selected if there were no further depressions of the button in the particular period of time. Each one of the depressions of the button


58


causes the indication to be shifted to the right in the shift register


90


. Such an indication is provided on an individual one of a plurality of light emitting diodes (LED) generally indicated at


93


. The shifting of the indication in the shift register


90


may be synchronized with a clock signal on a line


95


. Thus, the illuminated one of the light emitting diodes


93


at each instant indicates at that instant the individual one of the vehicles


12


,


14


,


16


and


17


that the pad


42




a


has selected at such instant within the particular period of time




The central station


64


is shown in additional detail in FIG.


3


. It includes a microcontroller generally indicated at


94


having a read only memory (ROM)


96


and a random access memory (RAM)


98


. As with the memories in the microcontroller


76


in the pad


42




a


, the read only memory


96


stores permanent information and the random access memory


98


stores volatile (or impermanent) information. For example, the read only memory


96


sequentially selects successive ones of the pads


42




a


,


42




b


,


42




c


and


42




d


to be interrogated by the central station on a cyclic basis. The read only memory


96


also stores a plurality of addresses each individual to a different one of the vehicles


12


,


14


,


16


and


17


.




Since the read only memory


96


knows which one of the pads


42




a


,


42




b


,


42




c


and


42




d


is being interrogated at each instant, it knows the individual one of the pads responding at that instant to such interrogation. The read only memory


96


can provide this information to the microcontroller


94


when the microcontroller provides for the transmittal of information to the vehicles


12


,


14


,


16


and


17


. Alternatively, the microcontroller


76


in the pad


42




a


can provide an address indicating the pad


42




a


when the microcontroller sends the binary signals relating to the status of the switches


46


,


48


,


50


and


52


and the switches


57


,


59


,


62




a


,


62




b


,


63




a


and


63




b


to the central station


64


.




As an example of the information stored in the random access memory


98


in

FIG. 3

, the memory stores information relating to each pairing between an individual one of the pads


42




a


,


42




b


,


42




c


and


42




d


and a selective one of the vehicles


12


,


14


,


16


and


17


in FIG.


1


and between each individual one of such pads and a selective one of the stationary accessories


34


and


38


. The random access memory


98


also stores the status of the operation of switches


46


,


48


,


50


and


52


for each pad and the operation of the switches


57


,


59


,


62




a


,


62




b


,


63




a


and


63




b


for that pad.




When the central station


64


receives from the pad


42




a


the signals indicating the closure (or the lack of closure) of the switches


46


,


48


,


50


and


52


and the switches


57


,


59


,


62




a


,


62




b


,


63




a


and


63




b


, the central station retrieves from the read only memory


96


the address of the individual one of the vehicles indicated by the closures of the switch


59


in the pad. The central station may also retrieve the address of the pad


42




a


from the read only memory


96


.




The central station


64


then formulates in binary form a composite address identifying the pad


42




a


and the selected one of the vehicles


12


,


14


,


16


and


17


and stores this composite address in the random access memory


98


. The central station


64


then provides a packet or sequence of signals in binary form including the composite address and including the status of the opening and closing of each of the switches in the pad


42




a


. This packet or sequence indicates in binary form the status of the closure each of the switches


46


,


48


,


50


and


52


and the switches


57


,


59


,


62




a


,


62




b


,


63




a


and


63




b.






Each packet of information including the composite addresses and the switch closure information for the pad


42




a


is introduced through a line


102


in

FIG. 3

to a radio frequency transmitter


104


in the central station


64


. The radio frequency transmitter


104


is enabled by a signal passing through a line


106


from the microcontroller


94


. This enabling signal is produced by the microcontroller


94


when the microcontroller confirms that it has received signals from the pad


42




a


as a result of the interrogating signals from the central station


64


.




When the radio frequency transmitter


104


receives the enabling signal on the line


106


and the address and data signals on the line


102


, the antenna


68


(also shown in

FIG. 1

) transmits signals to all of the vehicles


12


,


14


,


16


and


17


. However, only the individual one of the vehicles


12


,


14


,


16


and


17


with the address indicated in the packet of signals from the central station


64


will respond to such packet of signals.




The microcontroller


94


stores in the random access memory


98


the individual ones of the vehicles such as vehicles


12


,


14


,


16


and


17


respectively being energized at such instant by the individual ones of the pads


42




a


,


42




b


,


42




c


and


42




d


. Because of this, the central station


64


is able to prevent the interrogated one of the pads


42




a


,


42




b


,


42




c


and


42




d


from selecting one of the energized vehicles. Thus, for example, when the vehicle


14


is being energized by one of the pads


42




a


,


42




b


,


42




c


and


42




d


at a particular instant, a first depression of the button


58


in the pad being interrogated at that instant will cause the vehicle


12


to be initially selected and a second depression of the button by such pad will cause the vehicle


14


to be skipped and the vehicle


16


to be selected.




Furthermore, in the example above where the pad


42




a


has previously selected the vehicle


14


, the microcomputer


94


in the central station


64


will cause the vehicle


14


to be released when the pad


42




a


selects any of the vehicles


12


,


16


and


17


. When the vehicle


14


becomes released, it becomes available immediately thereafter to be selected by any one of the pads


42




a


,


42




b


,


42




c


and


42




d


. The release of the vehicle


14


by the pad


42




a


and the coupling between the pad


42




a


and a selected one of the vehicles


12


,


14


,


16


and


17


are recorded in the random access memory


98


in the microcontroller


94


.




The vehicles


12


,


14


,


16


and


17


are battery powered. As a result, the energy in the batteries in the vehicles


12


,


14


,


16


and


17


tends to become depleted as the batteries provide the energy for operating the vehicles. The batteries in the vehicles


12


and


14


are respectively indicated at


108


and


110


in FIG.


3


. The batteries


108


and


110


are chargeable by the central station


64


because the central station may receive AC power from a wall socket. The batteries are charged only for a particular period of time. This particular period of time is preset in the read only memory


96


. When each battery is being charged for the particular period of time, a light


109


in a circuit with the battery becomes illuminated. The charging current to each of the batteries


108


and


110


may be limited by a resistor


111


. The light


109


becomes extinguished when the battery has been charged.




Each central station


64


may have the capabilities of servicing only a limited number of pads. For example, each central station


64


may have the capabilities of servicing only the four (4) pads


42




a


,


42




b


,


42




c


and


42




d


. It may sometimes happen that the users of the system may wish to be able to service more than four (4) pads. Under such circumstances, the microcontroller


94


in the central station


64


and a microcontroller, generally indicated at


94




a


, in a second central station corresponding to the central station


64


may be connected by cables


114




a


and


114




b


to an adaptor generally indicated at


115


.




One end of the cable


114




b


is constructed so as to be connected to a ground


117


in the adaptor


115


. This ground operates upon the central station to which it is connected so that such central station is a slave to, or subservient to, the other central station. For example, the ground


117


in the adaptor


115


may be connected to the microcomputer


94




a


so that the central station including the microcomputer


94




a


is a slave to the central station


64


. When this occurs, the microcontroller


94


in the central station


64


serves as the master for processing the information relating to the four (4) pads and the four (4) vehicles in its system and the four (4) pads and the four (4) vehicles in the other system.




The expanded system including the microcomputers


94


and


94




a


may be adapted so that the address and data signals generated in the microcomputer


94




a


may be transmitted by the antenna


68


in the central station


64


when the central station


64


serves as the master station. The operation of the central station


64




a


may be clocked by the signals extending through a line


118


from the central station


64


to the adaptor


115


and through a corresponding line from the other central station to the adaptor.




The vehicle


12


is shown in additional detail in FIG.


4


. Substantially identical arrangements may be provided for each of the vehicles


14


,


16


and


17


. The vehicle


12


includes the antenna


69


for receiving from the central station


64


signals with the address of the vehicle and also includes a receiver


121


for processing the received signals. The vehicle


12


also includes the motors


28


,


30


,


32


and


33


. Each of the motors


28


,


30


,


32


and


33


receives signals from an individual one of transistor drivers


120


connected to a microcontroller generally indicated at


122


.




The microcontroller


122


includes a read only memory (ROM)


124


and a random access memory (RAM)


126


. As with the memories in the pad


42




a


and the central station


64


, the read only memory


124


may store permanent information and the random access memory


126


may store volatile (or impermanent) information. For example, the read only memory


124


may store information indicating the sequence of the successive bits of information in each packet for controlling the operation of the motors


28


,


30


,


32


and


33


in the vehicle


12


. The random access memory


126


stores information indicating whether there is a binary 1 or a binary 0 at each successive bit in the packet.




The vehicle


12


includes a plurality of switches


128


,


130


and


132


. These switches are generally pre-set at the factory to indicate a particular Arabian number such as the number “5”. However, the number can be modified by the user to indicate a different number if two central stations are connected together as discussed above and if both stations have vehicles identified by the numeral “5”. The number can be modified by the user by changing the pattern of closure of the switches


128


,


130


and


132


. The pattern of closure of the switches


128


,


130


and


132


controls the selection of an individual one of the vehicles such as the vehicles


12


,


14


,


16


and


17


.




The pattern of closure of the switches


128


,


130


and


132


in one of the vehicles can be changed when there is only a single central station. For example, the pattern of closure of the switches


128


,


130


and


132


can be changed when there is only a single central station with a vehicle identified by the numeral “5” and when another user brings to the central station, from such other user's system, another vehicle identified by the numeral “5”.




The vehicle


12


also includes a light such as a light emitting diode


130


. This diode is illuminated when the vehicle


12


is selected by one of the pads


42




a


,


42




b


,


42




c


and


42




d


. In this way, the other users can see that the vehicle


12


has been selected by one of the pads


42




a


,


42




b


,


42




c


and


42




d


in case one of the users (other than the one who selected the vehicle


12


) wishes to select such vehicle. It will be appreciated that each of the vehicles


12


,


14


,


16


and


17


may be generally different from the others so each vehicle may be able to perform functions different from the other vehicles. This is another way for each user to identify the individual one of the vehicles that the user has elected.




As previously indicated, the user of one of the pads such as the pad


42




a


selects the vehicle


12


by successively depressing the button


58


a particular number of times within the particular time period. This causes the central station


64


to produce an address identifying the vehicle


12


. When this occurs, the central station


64


stores information in its random access memory


98


that the pad


42




a


has selected the vehicle


12


. Because of this, the user of the pad


42




a


does not thereafter have to depress the button


58


during the time that the pad


42




a


is directing commands through the central station


64


to the vehicle


12


. As long as the buttons on the pad


42




a


are depressed within a particular period of time to command the vehicle


12


to perform individual functions, the microprocessor


94


in the central station


64


will direct the address of the vehicle


12


to be retrieved from the read only memory


96


and to be included in the packet of the signals transmitted by the central station to the vehicle


12


. This particular period of time may be different from the particular period of time for addressing the vehicle.




The read only memory


96


in the microprocessor


94


at the central station


64


stores information indicating a particular period of time in which the vehicle


12


has to be addressed by the pad


42




a


in order for the selective coupling between the pad and the vehicle to be maintained. The random access memory


98


in the microcontroller


94


stores the period of time from the last time that the pad


42




a


has issued a command through the central station


64


to the vehicle


12


. When the period of time in the random access memory


98


equals the period of time in the read only memory


96


, the microcontroller


94


will no longer direct commands from the pad


42




a


to the vehicle


12


unless the user of the pad


42




a


again depresses the button


58


the correct number of times within the particular period of time to select the vehicle


12


. When the pad


42




a


fails to issue a command to the vehicle


12


within the particular period of time, the vehicle


12


becomes converted from an active and powered state to an inactive but powered state.




The vehicle


12


also stores in the read only memory


124


indications of the particular period of time in which the vehicle


12


has to be addressed by the pad


42




a


in order for the selective coupling between the vehicle and the pad to be maintained. This period of time is the same as the period of time specified in the previous paragraph. The random access memory


126


in the microcontroller


122


stores the period of time from the last time that the pad


42




a


has issued a command to the vehicle


12


.




As previously indicated, the button


58


in the pad


42




a


does not have to be actuated or depressed to issue the command after the pad


42




a


has initially issued the command by the appropriate number of depressions of the button. When the period of time stored in the random access memory


126


of the microcomputer


122


in the vehicle equals the period of time in the read only memory


124


, the microcontroller


122


issues a command to extinguish the light emitting diode


130


. This indicates to the different users of the system, including the user previously controlling the operation of the vehicle


121


, that the vehicle is available to be selected by one of the users including the user previously directing the operation of the vehicle.




When one of the vehicles such as the vehicle


12


is being moved in the forward direction, the random access memory


126


records the period of time during which such forward movement of the vehicle


12


is continuously occurring. This period of time is continuously compared in the microcontroller


122


with a fixed period of time recorded in the read only memory


124


. When the period of time recorded in the random access memory


126


becomes equal to the fixed period of time recorded in the read only memory


124


, the microcontroller


122


provides a signal for changing the speed of the movement of the vehicle


12


in the forward direction. Similar arrangements are provided for each of the vehicles


14


,


16


and


17


. This change in speed may illustratively be twice that of the original speed. It will be appreciated that the change in speed may constitute a decrease in the speed of the vehicle


42




a.






The system and method described above and disclosed and claimed in U.S. Pat. No. 5,944,607 have certain important advantages. They provide for the individual operation of a plurality of vehicles (e.g., the vehicles


12


,


14


,


16


and


17


) by a plurality of users, either on a competitive or a cooperative basis. Furthermore, the vehicles can be operated on a flexible basis in that a vehicle can be initially selected for operation by one user and can then be selected for operation by another user after the one user has failed to operate the vehicle for a particular period of time. The vehicles being operated at each instant are also easily identified visually by the illumination of the lights


130


on the vehicle. The apparatus and method of this invention are also advantageous in that the vehicles are operated by the central station


64


on a wireless basis without any physical or cable connection between the central station and the vehicles.




Furthermore, the central station


64


is able to communicate with the vehicles in the plurality through a single carrier frequency. The system and method are also advantageous in that the vehicles can selectively perform a number of different functions including movements forwardly and rearwardly and to the left and the right and including movements of a container or bin or platform on the vehicle upwardly and downwardly or to the left or the right. Different movements can also be provided simultaneously in any one of the addressed vehicles on a coordinated basis.




There are also other significant advantages in the system and method in the preferred embodiments of this invention. Two or more systems can be combined to increase the number of pads


42


controlling the operation of the vehicles


12


,


14


,


16


and


17


. In effect, this increases the number of users capable of operating the system. This combination of systems can be provided so that one of the systems is a master and the other is a slave. This prevents any confusion from occurring in the operation of the system. The system is also able to recharge the batteries in the vehicles so that use of the vehicles can be resumed after the batteries have been charged.




The system and method in the preferred embodiments of this invention are also advantageous in the provision of the pads


42


and the provision of the buttons and switches in the pads. As will be appreciated, the pads


42


are able to select vehicles and/or stationary accessories through the operation of a minimal number of buttons and to provide for the operation of a considerable number of different functions in the vehicles with a minimal number of buttons. In cooperation with the central station


64


, the pads


42


are able to communicate the selection of vehicles (e.g.,


12


,


14


,


16


and


17


) to the central station


64


without indicating to the central station, other than on a time shared basis, the identities of the vehicles being selected. After selecting a vehicle, each pad does not thereafter have to indicate the identity of the vehicle as long as the pad operates the vehicle through the central station within a particular period of time from the last operation of the vehicle by the pad through the central station.




The preferred embodiments of this invention provide an improved system for providing selectable addresses in the vehicles


12


,


14


,


16


and


17


. The preferred embodiments of the invention include a plurality of keys generally indicated at


150


and individually indicated at


150




a


,


150




b


,


150




c


,


150




d


,


150




e


,


150




f


,


150




g


and


150




h


in

FIGS. 9 and 10

. Each of the keys may have substantial dimensions so that they will not be easily lost by children using the vehicles. For example, the height of each key may be about three inches (3″) and the width of each key may be about one and one half inches (1 ½′). The thickness of each key may be relatively small. Each key may be disposed in a vehicle (e.g., the vehicles


12


,


14


,


16


and


17


) which has a length of about six inches (6″) and a width of about three inches (3″) and a height of about three inches Each of the keys


150


has a body


151


(FIGS.


7


and


8


). As will be seen from the subsequent discussion, each of the keys


150


is constructed to provide an address individual to that key. This may be seen from the following table where the left column indicates the individual ones of the keys


150




a


-


150




h


and the right column indicates an address individually distinguishing each of the keys from the others:



















Key




Individual Address













150a




1







150b




2







150c




3







150d




4







150e




5







150f




6







150g




7







150h




8















Although the individual address for each key is shown as an Arabian integer, it will be appreciated that the individual address for such vehicle will probably be in an individual pattern of binary signals.




The body


151


on each of the keys


150




a


-


150




h


is provided with an individual pattern of ribs


152




a


,


152




b


,


152




c


and


152




d


. (FIGS.


9


and


10


). This may be seen from the following table indicating the individual pattern of ribs for each of the keys


150




a


-


150




h


:
















Key




Individual Address-Pattern of Ribs











150a




152a, 152b, 152c, 152d






150b




152a, 152b, 152c






150c




152a, 152b, 152d






150d




152a, 152b






150e




152b, 152c, 152d






150f




152b, 152c






150g




152b, 152d






150h




152b














It will be appreciated that sixteen (16) different combinations may be provided with the four (4) ribs


152




a


-


152




d


. Only eight (8) combinations are shown in the table above and in

FIGS. 9



a


-


9




h


and


10




a


-


10




h


on the assumption that the system will contain only eight (8) vehicles. However, sixteen (16) different vehicles may be identified by the different patters of the ribs


152




a


-


152




d


. It will also be appreciated that a different number of ribs then four (4) may be provided to change the number of vehicles that can be provided in the system.




Each of the keys


150




a


-


150




h


is adapted to be disposed in a socket


154


(

FIGS. 5 and 6

) in any one of the vehicles


12


,


14


,


16


and


17


. Each of the keys


150




a


-


150




h


may be provided with guides


156


at its opposite sides (1) to fit in slots


157


in the socket and provide for a snug fit of the keys in the socket


154


, (2) to provide for a controlled movement of the key into the socket, (3) to provide lateral stability to the key after the disposition of the key in the socket and (4) to prevent the key from coming out of the socket except by manual removal of the key from the socket. When one of the keys


150


(e.g. the key


150




d


) is disposed in the socket


154


of one of the vehicles (e.g. the vehicle


12


), the ribs


152




a


and


152




b


in the key


150




d


engage springs


158




a


and


158




b


(

FIGS. 11 and 12

) operatively coupled to the movable contacts of a pair of switches


160




a


and


160




b


(included in a bank of switches


160




a


,


160




b


,


160




c


and


160




d


) and move these contacts from engagement with the stationary contacts of the switches. As a result, only the switches


160




c


and


160




d


remain closed. This causes the vehicle


12


to have an address identified by a binary pattern of 0011. As will be seen from the subsequent discussion, any one of the pads


42




a


,


42




b


,


42




c


and


42




d


can select the vehicle


12


by three (3) manual depressions of the button


58


in such pad within a particular period of time. The manual depression of the button


58


in the pad three (3) times within the particular period of time provides for the binary address of 0011 where the least significant bit is at the right.




The number of manual depressions of the button


58


to select an individual one of the vehicles may actually be dependent upon the previous actuation of the button. For example, the button


58


in a pad may have been previously actuated twice to select the vehicle identified by the number “2”. If the user of such pad now desires to select the vehicle identified by the numeral “


3


”, such user would only have to actuate the button


58


once. Similarly, if the user has previously selected the vehicle identified by the numeral “2” by actuating the pad twice and now desires to select vehicle identified by the numeral “1” the user would have to actuate the button


58


in the pad an additional seven (7) times.




An electrically conductive shorting bar


164


(

FIGS. 8 and 9

) is disposed between the ribs


152




a


and


152




b


and the ribs


152




c


and


152




d


. The bar


164


engages a pair of contacts


166




a


to the microcontroller


122


in the vehicle


12


. This causes the microcontroller


122


in the vehicle


12


to reset all of the different parameters in the random access memory


126


to initializing values. For example, the random memory


126


in the vehicle


12


may be set to initializing values of zero (0) for the switches


160




a


-


160




d


. After a brief period of time (e.g. ½ second) provided in the microcontroller


122


, the microcontroller may then cause the pattern of 0011 to be provided in the random access memory


126


in the vehicle


12


in accordance with the pattern of the ribs in the key


150




d.






A decal


166


(

FIGS. 5 and 7

) is disposed on the front and the rear of each of the keys


150


to identify that key by an individual Arabian number. For example, the Arabian number “3” is provided on the decal


166


which is disposed on the front of the key


150




d


to identify such key and distinguish such key from the other keys. A V-shaped cut


168


is provided on the top of each key


150


at the front and rear of the key. A light emitting diode (LED)


170


is disposed in each of the keys


150


at a position just below the neck of the V-shaped cut


168


. A clear light conducting plastic


172


is disposed in the V-shaped cut


168


to conduct light from the light emitting diode


170


. Electrically conductive pins


174


are provided on the opposite sides of each of the keys


150


near the bottom of the key to establish a continuous circuit to the light emitting diode


170


when the key is inserted in the socket


154


in the vehicle such as the vehicle


12


.




A finger


176


made from a suitable material such as rubber and looking like an antenna (but not actually an antenna) may extend upwardly from the top of each of the keys


150


. The finger


176


is provided to add a semblance of high level technology to the key


150


, particularly for young children. However, the finger


176


has no utility in the key. A button


178


below the decal


166


also has no utility in the key.




When the key


150




d


is inserted into the socket


154


of the vehicle


12


, the bar


164


establishes an electrical circuit across the switches


166




a


and


166




b


and causes the microcontroller


122


to initialize all of the parameters in the random access memory


126


and to initialize the address of the vehicle in the random access memory


126


. Although the switches


150




b


and


150




d


are closed at the same time as the switches


166




a


and


166




b


, the microcontroller


122


in the vehicle


12


does not establish the address of the vehicle in the random access memory


126


until after the parameters have been initialized by the closure of the switches


166




a


and


166




b


as discussed above.




The microcontroller


122


causes the vehicle


12


to operate in the inactive but powered state when the address of the vehicle


12


has been entered into the random access memory


126


as a result of the disposition of the key


150




d


in the socket


154


. In the inactive but powered state, the vehicle


12


is capable of receiving from any of the pads


42




a


,


42




b


,


42




c


and


42




d


the address entered into the random access memory


126


. When the vehicle


12


receives this address from an individual one of the pads


42




a


-


42




d


, it operates thereafter in accordance with commands received from such individual one (e.g. the pad


42




b


) of the pads.




The light emitting diode


170


is continuously illuminated in accordance with instructions from the microcontroller


122


during the time that the individual one of the pads


42




a


-


42




d


(e.g. the pad


42




b


) is operating the vehicle. This illumination is visible to the users of all of the pads


42




a


-


42




d


because of the diffusion of the light from the light emitting diode


170


through the light conducting plastic


172


. It indicates to all of the users that the vehicle


12


is being commanded by one of the pads (e.g. the pad


42




b


) and is not available to be operated by any of the other pads.




The continuous illumination of the light emitting diode


170


exists as long as the user of the pad


42




b


continues to issue commands to the vehicle


12


within a first particular period of time after the last time that such pad has issued a command to such vehicle. If the pad


42




b


fails to issue any command to the vehicle


12


within such first particular period of time, the microcontroller


122


in the vehicle


12


causes the vehicle to become operative in the inactive but powered state. In this state, the vehicle is able to be selected by any of the pads including the pad


42




b


. In the inactive but powered state of the vehicle


12


, the microcontroller


122


causes the light emitting diode


170


to be illuminated periodically. In other words, the light emitting diode


170


is blinked on and off at a particular rate.




When the vehicle


12


is in the inactive but powered state, it can be addressed by any of the pads


42




a


-


42




d


including the pad


42




b


, which previously addressed the vehicle. Assume that the pad


42




c


addresses the vehicle


12


while the vehicle is in the inactive but powered state. The vehicle


12


will now be commanded by the pad


42




c


to operate until such time as the pad


42




c


fails to issue a command to the vehicle within the first particular period of time after the last issuance of a command from the pad to the vehicle. The vehicle will also operate in the inactive but powered state when the pad


42




a


has previously selected and operated the vehicle and the pad now selects and operates a different vehicle such as the vehicle


14


. The microcontroller


94


in the central station keeps account of this.




As will be seen, the vehicle


12


is in the inactive but powered state under three (3) different circumstances. One circumstance occurs when one of the keys


150


is inserted in the socket


154


in the vehicle


12


. The second circumstance occurs when one of the pads (e.g. the pad


42




a


) selects the vehicle


12


and then fails to issue a command to the vehicle within the first particular time after the last issuance of a command from the pad to the vehicle. The third circumstance occurs when one of the pads (e.g., the pad


42




a


) has previously selected and operated the vehicle


12


and the pad thereafter selects and operates a different vehicle (e.g., the vehicle


14


) then the vehicle


12


.




The vehicle


12


is programmed to remain n the inactive but powered state for a second particular period of time independent of the first particular period of time. If the vehicle


12


is not addressed by any of the pads


42




a


-


42




d


in the second particular period of time, the vehicle becomes deactivated. Alternatively, if no commands have been given by any of the pads


42




a


-


42




d


to any of the vehicles in the second particular period of time, all of the vehicles become deactivated. When the vehicle


12


becomes deactivated, the light emitting diode


170


is not illuminated. This indicates to the users that power has been removed from the vehicle and that the vehicle is in the depowered state.




As previously described, the bar


164


establishes an electrical continuity between the switches


166




a


and


166




b


when the key


150


is inserted into the socket


154


in the vehicle


12


. To insure that the ribs


152




a


and


152




b


in the key


150




d


will continue to engage the movable contacts of the associated switches


160




a


and


160




b


, the key


150




d


continues to move into the socket


154


to a position between the bar


164


and a bar


180


directly above the bar


164


. This is indicated in FIG.


15


. The bar


180


corresponds in construction and operation to the bar


164


. In the position shown in

FIG. 15

, the contacts


166




a


and


166




b


are not shorted.




If the vehicle


12


should become deactivated as discussed above and a user should thereafter wish to operate the vehicle, the user presses the key


150




d


downwardly until the bar


180


engages the contacts


166




a


and


166




b


. This is shown in FIG.


15


. This causes the contacts


166




a


and


166




b


to be shorted, causing the microcontroller


122


to be initialized and the random access memory


126


to receive the address of the key


150




d


. The vehicle


12


then becomes operative in the inactive but powered state as discussed above. When the key


150




d


is released, the key is moved by the action of a spring


182


back to a position where the contacts are between the bars


164


and


180


in displaced relationship to the bars. This position is shown in FIG.


15


. In this way, the key


150




d


can be moved downwardly again into continuity with the contacts


166




a


and


166




b


(which constitute a switch with the bar


164


or the bar


180


) if the vehicle should thereafter be deactivated again. This continuity is established by the action of the bar


180


on the switches


166




a


and


166




b


as shown in FIG.


14


.





FIG. 13

shows the key in position in the socket so that the bar


164


establishes continuity with the contacts


166




a


and


166




b


.

FIG. 14

shows the key in position in the socket so that non-conductive material in the key engages the contacts


166




a


and


166




b


. In this position, no electrical continuity is established between the contacts


166




a


and


166




b


.

FIG. 15

shows the key in position in the socket so that the bar


180


establishes continuity with the contacts


166




a


and


166




b.






The system and method disclosed above have certain important advantages. They provide for the insertion of one of the keys


150


(e.g. the key


150




d


) into the socket


154


in one of the vehicles (e.g. the vehicle


12


) to provide the vehicle with an address individual to such key. They also provide for the initializing of the parameters in the random access memory


126


in the vehicle


12


. The vehicle


12


can then be selected by any of the pads


42




a


-


42




b


by operating the button


58


a number of times dependent upon the individual number (e.g. “3”) provided for the vehicle by the key


150




d.






The system and method disclosed above have other important advantages. They provide for the operation of the vehicle


12


by the pad


42




a


(by way of example) after the vehicle is selected by the pad. If the pad


42




a


fails to operate the vehicle within the first particular period of time, the vehicle becomes inactive but powered and can be selected by any of the pads including the pad


42




a


. If any of the three (3) circumstances discussed above then occurs, the vehicle becomes deactivated. The vehicle can again become inactive but powered by pressing the key


150




d


downwardly in the socket


154


.




In a preferred embodiment of the invention, a hollow block generally indicated at


210


(

FIGS. 16 and 17

) is provided. The block


210


may be made from a suitable thermoplastic material such as an acrylonitrile-butadiene-styrene (ABS). The block may preferably be in the form of a rectangular prism with six (6) substantially identical faces


212


. Each of the faces


212


may have a configuration of a square with a suitable length such as approximately twenty millimeters (20 mm) for each side of the square, a thickness of approximately two millimeters (2 mm) and a centrally disposed square openings


14


of approximately twelve millimeters (12 mm) for each side of the opening.




Openings


214


are preferably provided in each of the faces


212


. It will be appreciated, however, that the opening


214


may be provided in any number of the faces from one (1) to six (6). A number of the blocks


210


may be provided with the openings


214


in only a limited number of the faces


212


. Of course, limiting the number of the faces


212


with the openings


214


in the blocks


210


limits the utility which can be provided for the blocks. Grooves


216


may be provided in the faces


212


for decorative purposes.




The blocks


210


may be formed in two sections respectively designated as


210




a


and


210




b


. The sections


210




a


and


210




b


may be identical although this is not a requirement. Each of the sections


210




a


and


210




b


may be provided with pegs


218


at a pair of diagonally opposite ends of such section. Each of the sections


210




a


and


210




b


may also be provided with sockets


220


at the other pair of the diagonally opposite ends of such section. The pegs


218


on each of the sections


210




a


and


210




b


are adapted to fit snugly in the sockets


220


in the other one of the sections


210




a


and


210




b


. The sections


210




a


and


210




b


may then be joined to each other as by brazing or locally heating the pegs


218


and


220


to a temperature for melting and fusing the pegs and the sockets or they may be joined by any other method well known in the art. Alternatively, the pegs


210


may be provided in the section


210




a


and the sockets


220


may be provided in the other section


210




b.






A beam generally indicated at


222


(

FIGS. 18 and 19

) is adapted to be used in conjunction with the block


210


. The beam


222


may be made from a suitable thermoplastic material such as an acrylonitrile-butadiene-styrene (ABS). The beam may preferably be in the form of a rectangular prism with four (4) substantially identical faces


224


defining a rectangle in section and with two substantially identical end faces


226


in opposed relationship at the opposite ends of the faces


224


.




The beam


222


may also be formed in two sections


222




a


and


222




b


in a manner similar to the formation of the block


210


. For example, each of the beam sections


222




a


and


222




b


may be provided with diametrically disposed pegs


223


for each of the sections


222




a


and


222




b


and with a pair of diametrically disposed sockets


225


for receiving the pegs


223


in the other one of the beam sections


222




a


and


222




b


. After the pegs


223


in each of the sections


222




a


and


222




b


have been press fitted into the sockets


225


in the other one of the sections


222




a


and


222




b


, the two sections may be attached to each other as by brazing or by heating the pegs


223


and the sockets


225


to melt and fuse the pegs and the sockets or by any other suitable method well known in the prior art. Alternatively, the pegs


223


may be provided in the beam section


222




a


and the sockets


225


may be provided in the beam section


222




b.






Each of the faces


224


may have a plurality of face sections


224




a


,


224




b


, etc. and a plurality of openings


228




a


,


228




b


, etc., respectively corresponding to the openings


214


in the faces


212


of the block


210


. Each of the openings


228




a


,


228




b


, etc. is respectively provided in one of the face sections


224




a


,


224




b


, etc. Each of the openings


228




a


,


228




b


, etc. in the beam


222


may be substantially identical to the openings


214


in the block


210


. Although seven (7) openings are shown in each of the faces


224


, the number of openings in each face


224


may be different from seven (7) without departing from the scope of the invention. Furthermore, the openings


228


do not have to be provided in every face. For example, the openings


228


may be provided in only one (1) of the faces


224


without departing from the scope of the invention.




Snaps generally indicated at


230


are preferably provided in the two (2) end faces


226


. Preferably two (2) snaps


230


extend from each of the end faces


226


. The snaps


230


on each of the end faces


226


are substantially identical and are substantially parallel to each other. Each of the snaps


230


has at its outer end a portion which may be considered as a detent


232


(FIGS.


20


and


21


). Each detent


232


has a first portion


234


which progressively increases in thickness with progressive distances from the end faces


226


. Each of the detents


232


has a second portion


236


which progressively decreases in thickness with progressive distances from the end faces


226


. The first detent portion


234


and the second detent portion


236


have a common boundary


238


at the positions of their maximum thicknesses. As will be seen, the detent portions


232


and


234


of each snap


230


have a bulbous shape.




The snaps


230


are constructed to be inserted into the openings


214


in the block


210


. The progressive increase in thickness of the detent portion


236


facilitates this insertion. When the snaps


230


have been inserted into one of the openings


214


, the detent portions


234


and


236


are disposed internally of the internal surface of the face


212


defining such opening. The snaps


230


may also be removed easily from the opening


214


in the face


212


by pulling the snaps outwardly from the opening. This is indicated by an arrow


237


in FIG.


22


. The progressive increase in the thickness of the detent portions


234


in the snaps


230


facilitates the removal of the snaps from the opening


214


.




At the positions of the detent portions


234


and


236


in each snap


230


, the snap is provided with a rounded surface


239


(

FIG. 20

) at the opposite ends of the snap. The rounded surface


239


on each snap


230


provides for the removal of each snap from the opening


214


in the face


212


of the block


210


by bending the snap from the opening. This may be seen from

FIG. 24

where the snaps


230


on one of the beams


222


have been partially bent out of the opening


214


. The direction of such bending is indicated by an arrow


241


in FIG.


24


. As will be appreciated, the detent portions


234


also facilitate the bending action to remove the snaps


230


from the opening


214


. This bending is indicated by an arrow


243


in FIG.


23


. This bending is in a direction perpendicular to the bending shown in FIG.


24


. This may be seen from

FIG. 23

which shows the snap


230


partially removed from the opening


214


in the block


210


as a result of the bending of the beam


222


in the direction


243


.




It should be appreciated that the beam


222


does not have to be coupled to one of the openings


214


in the block


210


. The beam


222


can also be coupled to one of the openings


228


in another one of the beams


222


. However, the coupling of two (2) beams can occur in only one of four (4) different directions because the snaps


230


are disposed on the beams in the other two (2) directions. However, the coupling of one of the beams


222


and one of the blocks


210


can occur in any of six (6) different directions. It will thus be seen that a coupling of one of the beams


222


to one of the blocks


210


is preferable to a coupling of two (2) beams.





FIG. 25

shows a miniramp generally indicated at


250


. As will be seen, the miniramp


250


has an inclined surface


252


and has a pair of snaps


254


near one lateral end of the miniramp


250


and has a pair of snaps


256


near the other lateral end of the miniramp. The snaps


254


and


256


correspond in construction to the snaps


230


. The snaps in each pair have the same spacing as the snaps


230


on one of the end faces


226


in the beam


222


.




An opening


258


corresponding in construction and dimensions to the opening


214


in the block


210


is provided between the snaps


254


and the adjacent lateral extremity of the miniramp


250


. In like manner, an opening


260


is provided between the snaps


254


and


256


but adjacent to the snaps


256


. Two of the miniramps


250


can be illustratively coupled to each other to form a roof by disposing the snaps


254


in a first one of the miniramps in the opening


260


in the other miniramp and by disposing the snaps


256


in the other miniramp in the opening


258


in the first one of the miniramps.




As shown in

FIG. 27

, the miniramp


250


may be coupled to a structure, generally indicated at


252


, formed from a plurality of the blocks


210


and a plurality of the beams


222


so as to define a ramp


254


leading into the structure. When children are engaged im creative play, vehicles may be moved along the ramp


254


by the children into and out of the structure. Alternatively, as shown in

FIG. 27

, two (2) miniramps


250


may be used as roof overhangs


262


for the structure


252


in addition to the use of an additional one of the miniramps as the ramp


254


. The snaps


230


from one of the beams


222


may be inserted into the miniramp


250


when the miniramp is used as the roof overhang


262


.




The structure


252


shown in

FIG. 27

includes a plurality of corbels. One of the corbels is shown in FIG.


26


and is generally indicated at


272


. Each of the corbels


272


is disposed to provide support to the structure


252


in FIG.


27


. Each of the corbels


272


includes a pair of snaps


274


having the same construction and disposition relative to each other as the snaps


230


in the beam


222


. As will be seen, the snaps


274


are disposed in one of the openings


228


in one of the blocks


210


.




The blocks


210


and the beams


222


have certain important advantages when used in a cooperative relationship. The blocks


210


preferably have six (6) identical faces


212


and preferably have identical openings


214


in the different faces. Because of this, all of the faces


212


in the block


210


are female. The beams


222


can be considered as being partially female and partially male. The male members in the beam


222


constitute the snaps


230


.




The snaps


230


can be disposed in any of the openings


214


in the blocks


212


without interfering with the snaps in any of the other openings in such blocks. When the snaps


230


from different ones of the beams


222


are in all of the six (6) openings


214


in the block


210


, the beams


222


including the snaps extend outwardly from the block


210


in six (6) different directions. This provides for the extension of the structure, such as the structure


252


, in six (6) different directions. The snaps


230


in the beams


222


can also be disposed in the openings


228


in others of the beams


222


.




When the snaps


230


in one of the beams


222


have been inserted into the opening


214


in the block


210


, they can be removed from the openings by pulling (

FIG. 22

) the snaps out of the openings or by bending (

FIGS. 23 and 24

) the snaps from the openings in either of two (2) different rotary directions displaced by 90° from each other. This provides for a relatively simple coupling and decoupling of the blocks


210


and the beams


222


.




The blocks


210


and the beams


222


have a uniform disposition on a support surface such as a platform or a floor. This simplifies the ability of children to form creative structures from the blocks


210


and the beams


222


. It also facilitates the ability to stack the blocks


210


and the beams


222


compactly in an enclosure such as a box when the blocks and the beams are not being used.




As will be seen, each of the vehicles


12


,


14


,


16


and


17


is addressable with an individual address dependent upon the insertion of an individual one of the keys


150




a


-


150




h


in the socket


154


in the vehicle. When addressed, each of the vehicles


12


,


14


,


16


and


17


is movable on support structure, generally indicated at


301


in

FIGS. 33-36

, provided by an intercoupling between individual ones of the beams


222


and the blocks


210


. This support structure


301


may have any one of an infinite number of different configurations. This structure may be formed so that each of the vehicles


12


,


14


,


16


and


17


may be movable in any direction on the structure. This structure may be disposed on a platform or a floor and the addressed vehicles


12


,


14


,


16


and


17


may also be movable on the platform or floor between different portions of the support structure.




It will be appreciated that the beams


222


may be provided with curved configurations rather than the straight configurations shown in

FIGS. 16-24

. For example, a beam


300


with a curved configuration is shown in FIG.


30


. The beams


222


with straight configurations and the beams


300


with the curved configurations may be interconnected with individual ones of the blocks


210


to form a track


302


. The track


302


may be disposed in a closed loop as illustrated in

FIG. 32

or it may be disposed in an open loop as shown in FIG.


35


. Different embodiments of the track


302


are shown in

FIGS. 32 through 36

.




A vehicle generally indicated at


304


(

FIGS. 31

,


33


-


34


and


37


-


38


) is movable in forward and rearward directions on the track


302


. The vehicle may constitute a monorail. The vehicle


304


is provided with a socket


306


(corresponding to the socket


154


in the vehicles


12


,


14


,


16


and


17


) for receiving any one of the keys


150




a


-


150




h


in a manner similar to that described above for the vehicles


12


,


14


,


16


and


17


. Thus, a person operating any one of the pads


42




a


-


42




d


can address the vehicle


304


while other individuals operating other ones of the pads


42




a


-


42




d


can address any one of the vehicles


12


,


14


,


16


and


17


not addressed at that time.




The track


302


can be physically intercoupled with the support structure


301


so as to support, stabilize or rigidify the support structure


301


(FIG.


33


). This intercoupling can be provided by individual ones of the beams


222


(and/or the beams


300


) and the blocks


210


intercoupled between the support structure


301


and the track


302


. Alternatively, the track


302


can be physically intercoupled with the support structure


301


so as to support, stabilize or rigidify the support structure


301


(FIG.


36


). This intercoupling can also be provided by individual ones of the beams


222


(and/or the beams


300


) and the blocks


210


. As another alternative, the support structure


301


and the track


302


can be physically intercoupled without either of the support structure


301


or the track


302


supporting the other one of the support structure


301


or the track


302


. It will be appreciated that, without departing from the scope of the invention, there does not have to be any physical intercoupling between the support structure


301


and the track


302


FIG.


35


). The support structure


201


and the track


302


may be disposed on a platform


307


or a floor


308


.




The vehicle


304


may be formed from an engine


308


(

FIGS. 31

,


37


and


38


) and a caboose


310


(FIG.


31


). The engine


308


and the caboose


310


may be movable on a unitary basis by providing a coupling member


312


between the engine and the caboose. The coupling member


312


may be pivotably coupled to the engine as at


314


and may be fixedly coupled to the caboose


310


as at


316


. The vehicle is separated into the engine


308


and the caboose


310


, rather than being formed as a unitary structure, to facilitate the movement of the vehicle on the track


302


through the curved portions of the track without falling from the track. A shroud


318


may cover the coupling member


312


to provide the vehicle


304


with the appearance of a unitary structure. The vehicle


304


includes a chassis


317


(

FIGS. 31

,


37


and


38


) disposed on the engine


308


and having a pair of spaced side surfaces and a pair of axles


319


disposed on the chassis in a spaced relationship in a longitudinal direction.




The engine


308


may be provided with a pair of longitudinally spaced rollers


320


(

FIGS. 37 and 38

) which are disposed on the axles


319


for rotary movement or the top surface of the track


302


and which extend laterally across substantially the width of the track


302


to roll on the top surface of the track. The rollers


308


are driven by a motor


322


(

FIG. 31

) mounted on the chassis


317


of the engine


308


. In like manner, the caboose


310


may be provided with a pair of longitudinally spaced rollers


324


which extend laterally across substantially the width of the track


302


to roll on the top surface of the track. The rollers


324


on the caboose


310


rotate in accordance with the rotation of the rollers


320


on the engine.




The engine


308


may be provided at its opposite lateral ends with skirts


326


(

FIGS. 37 and 38

) which extend below the top of the track


302


to a position opposite the side surfaces of the track. Guides


328


may be disposed at the inner surfaces of the skirts


326


in relatively close proximity to the lateral sides of the track


302


. The guides


328


facilitate the retention of the engine


308


on the track


302


during the time that the engine is moving on the track. The guides


328


may constitute wheels supported by the skirts


326


and rotatable in the direction of movement of the vehicle


304


.




It will be appreciated that the guides


328


are normally spaced from the side surfaces of the track


302


and that they engage the side surfaces of the track only occasionally as the engine


308


moves along the track. The guides


328


may be made from a suitable material such as Teflon or ABS plastic which provides a low friction when the guides engage the side surface of the track. The guides


328


may be shaped to provide a contact with the side surfaces of the track in a minimal area of the guides. Guides


330


corresponding to the guides


328


may also be disposed on skirts extending on the caboose


310


along the side surfaces of the track


302


.




The caboose


310


includes apparatus, generally indicated at


332


(

FIGS. 31

,


39


and


40


), for performing functions other than the movement of the vehicle


304


on the track


302


. Some of these functions are shown in the vehicles


12


,


14


,


16


and


17


in FIG.


1


. For example, the apparatus


332


may include a laterally movable bed


334


(

FIGS. 39 and 40

) disposed on the upper surface of the caboose


310


. The bed


334


is movable laterally in a selective one of two (2) opposite directions by a motor


336


operatively coupled to the bed.




A bin or receptacle generally indicated at


338


(

FIGS. 39 and 40

) is disposed on the bed


334


. The bin or receptacle


338


may be rectangular in horizontal section. The bin or receptacle


338


includes a pair of oppositely disposed fixed walls


340




a


(

FIG. 31

) and


340




b


(

FIGS. 31

,


39


and


40


) and a pair of oppositely disposed pivotable wall plates


342




a


and


342




b


(

FIGS. 39 and 40

) which are respectively disposed on pivotable pins


344




a


and


344




b


to provide for a pivotable movement of the wall plates with the pivotable movement of the pins. The opposite ends of a helical spring


346


are respectively coupled to the wall plates


342




a


and


344




b


. The helical spring


346


provides for the return of the pivotable wall plates


342




a


and


342




b


to their at rest positions when the pivotable force on the wall plates is removed.




A conveyor


348


(

FIGS. 33-36

) and a chute


347


extending downwardly from the top of the conveyor may be disposed on one side of the track


302


. When the vehicle


304


is moved on the track


302


to a position such that the bin or receptacle


338


is disposed below the upper end of the chute


347


, with the bed


334


in one (1) of two (2) lateral positions. The wall


342




a


may be pivoted downwardly. This provides for the introduction to the bin or receptacle


338


on the caboose


310


of play elements (such as slotted marbles) movable upwardly along the conveyor


348


to the top of the conveyor and then movable downwardly through the chute


347


to a position above the bin or receptacle in the vehicle


304


. When the bed


334


is in the other of the two (2) lateral positions, the bed


334


may have to be moved laterally to the one (1) lateral position to position the bin or receptacle


338


below the chute


337


.




One of the vehicles (e.g., the vehicle


12


) may be disposed on the side of the track


302


opposite the conveyor


348


and the chute


347


. When the vehicle


304


is thereafter moved to a position above the vehicle


12


, the bed


334


may be moved laterally by the motor


336


to the side of the track where the vehicle


12


is located. The wall


342




b


may then be pivoted to provide for the transfer of the play elements (e.g., marbles) from the bin or receptacle


338


to the bin or container


18


in the dump truck


12


. The bin or container


18


in the dump truck


12


is able to receive the play elements from the vehicle


304


because the vehicle


12


moves on the support structure


301


on the floor


308


to the track


302


which is raised relative to the support structure or floor so that the bin or receptacle on the vehicle


304


is above the bin or container


18


on the vehicle


12


. The skip loaders


16


and


17


also have bins or containers which are able to receive the play elements (e.g. marbles) in the bin or receptacle


338


on the vehicle


304


.




To move the bin or receptacle


338


from the position shown in

FIG. 39

to the position shown in

FIG. 40

, the motor


336


drives a pinion gear


350


which in turn drives a sector gear


352


in a clockwise rotation. The sector gear drives an arm


354


in a direction which causes the bin or receptacle


338


to pivot downwardly (clockwise). This in turn causes the wall plate


342




b


to extend outwardly below a horizontal plan as shown in FIG.


40


. As a result, the play elements (e.g. marbles) roll downwardly into the bin or container


18


on the vehicle


12


. When the bin or receptacle


338


tilts downwardly as shown in

FIG. 40

, it causes the helical spring


346


to become constrained in a direction to facilitate the return of the bin or receptacle to the position shown in FIG.


39


.





FIG. 32

shows one version of the track


302


. As will be seen, the beams


222


and the block


210


are disposed vertically at spaced positions along the track


302


to support a different portion of the track at different vertical levels. Furthermore, the version of the track


302


in

FIG. 32

constitutes a complex structure in which the track extends through a number of turns in different directions and in which the track defines a closed loop where the starting and ending positions are the same.





FIG. 35

shows a deck plate


350


disposed within a curved portion


352


of another version of the track


302


. The deck plate


350


is connected to the track


302


to enhance the stability and rigidity of the track and the support structure


301


. This is different from the previous embodiments since the deck plate may not be considered as a part of the support structure


301


on which the vehicles


12


,


14


,


16


and


17


are movable. Furthermore, as will be seen, the track


302


is not disposed in a closed loop.





FIG. 34

also shows another version of the support structure


301


on which the vehicles


12


,


14


,


16


and


17


are movable. The version of the support structure


301


in

FIG. 35

is intercoupled with the version of the track


302


in

FIG. 34

to enhance the stability and rigidity of the track.

FIG. 34

also shows a deck plate


354


on which the vehicles


12


,


14


,


16


and


17


are movable.





FIG. 36

also shows still another version of the support structure


301


on which the vehicles


12


,


14


,


16


and


17


are movable. The version of the support structure


301


in

FIG. 36

is also intercoupled with the version of the track


302


in

FIG. 36

to enhance the stability and rigidity of the track and the support structure




Although this invention has been disclosed and illustrated with reference to particular embodiments, the principles involved are susceptible for use in numerous other embodiments which will be apparent to persons of ordinary skill in the art. The invention is, therefore, to be limited only as indicated by the scope of the appended claims.



Claims
  • 1. In combination,a first vehicle having first members to provide a movement of the vehicle and having first controls operable on the first members to provide for a movement of the vehicle and having a second member for performing functions other than the movement of the vehicle and having second controls operable on the second member to obtain the performance of the functions by the second member, a support structure defining a path for the movement of the first vehicle, a plurality of pads each having a plurality of switches controlling the addressing of the first vehicle and additional vehicles and controlling the operation of the first and second controls in the first vehicle, and a central station responsive to the operation of the switches in the pads for providing for an operation of the first and second controls in the first vehicle when the first vehicle is addressed by any one of the pads.
  • 2. In a combination as set forth in claim 1 whereinthe support structure defines a track and wherein the first vehicle is constructed to move on the track.
  • 3. In a combination as set forth in claim 2 whereinthe support structure is defined by beams and blocks having particular constructions to provide interconnections between the beams and blocks and wherein the support structure defines a track produced from the beams and blocks having the particular constructions to provide interconnections between the beams and blocks in the track and wherein the first vehicle rides on the track and wherein the track produced from the interconnected beams and blocks in the support structure has characteristics for retaining the vehicle on the track.
  • 4. In a combination as recited in claim 1 whereinthe support structure is manually assembled from beams and blocks interconnected with one another and having an identical construction of the beams and an identical construction of the blocks and wherein the first vehicle constitutes a monorail and the interconnected beams and blocks in the structure define the track for the monorail.
  • 5. In a combination as set forth in claim 4 whereinthe interconnected beams in the support structure include detents providing for the interconnections of the beams and the blocks in the support structure.
  • 6. In combination,a first vehicle constructed to move only in first and second opposite directions and having first controls for providing a movement of the first vehicle in the first and second opposite directions and having second controls for performing functions other than the movement of the first vehicle in the first and second opposite directions, a support structure providing for the movement of the first vehicle in the first and second opposite directions, a plurality of pads each having switches controlling the addressing of any one of the first vehicle in the plurality and additional vehicles and controlling the movement of the first vehicle, when addressed, in the first and second opposite directions and controlling the operation of the second controls in the first vehicle, when addressed, in performing the functions in the first vehicle, and a central station responsive to the operations of the switches in each of the pads for addressing any one of the first vehicle and the additional vehicles not addressed by any of the other pads and for providing for movements of the first vehicle, when addressed, in accordance with the operation of the first controls in the first vehicle and for providing for the performance of the functions in the first vehicle, when addressed, in accordance with the operation of the second controls in the first vehicle.
  • 7. In a combination as set forth in claim 6 whereinthe support structure is defined by beams and blocks manually interconnected in a particular relationship and wherein the interconnection between the beams and blocks in the support structure defines a track for receiving the first vehicle and for providing for the movement of the first vehicle in the first and second opposite directions.
  • 8. In a combination as set forth in claim 7 whereinthe support structure extends from an additional support structure for the additional vehicles, and wherein the extension of the support structure from the additional support structure is defined by beams and blocks manually interconnected in the particular relationship.
  • 9. A method of providing controlled operations, including the steps of:providing a first vehicle having an individual address and having first controls providing for a movement of the additional vehicle when addressed and second controls providing for individual operations of the vehicle, other than movements of the vehicle, when addressed, providing a structure on which the first vehicle is able to move in a pair of opposite directions, providing a plurality of pads each having controls operable to address any one of the first vehicle and additional vehicles and to provide for a movement of the addressed vehicle and for individual operations of the addressed vehicle, operating the controls in each of the pads to address any one of the first vehicle and the additional vehicles and to provide for movements of the addressed vehicle and individual operations of the addressed vehicle, providing for a periodic activation of each of the pads to determine the addressing by the pad of any one of the first vehicle and the additional vehicles and the movement and individual operations of the addressed vehicle, providing for a sequential transmission by the pads, upon the periodic activation of the pads, of signals addressing in each of the pads any one of the first vehicle and the additional vehicles and signals indicating the movements and individual operations to be provided in the addressed vehicle, providing for the reception by the first vehicle and the additional vehicles of the signals indicating the addresses of the vehicles and the signals indicating the movements and individual operations to be provided in the addressed vehicles, and providing movements and individual operations in each of the addressed vehicles in accordance with the operation of the first and second controls in the pad addressing the vehicle.
  • 10. A method as set forth in claim 9, including the steps of:providing in each of the first vehicle and in the additional vehicles, a visual indication individually identifying the vehicle, providing in each of the pads indications visually identifying any individual one of the first vehicle and the additional vehicles, and activating in each of the pads the visual indication individually identifying the vehicle addressed by the pad.
  • 11. In a method as set forth in claim 9, the steps of:providing for the support structure beams having an identical construction, and having detents of an identical construction, and blocks having an identical construction for interconnection between adjacent beams and blocks wherein the blocks and the detents on the beams in the support structure operate in cooperation with one another and with the first vehicle to retain the first vehicle on the track.
  • 12. In a method as set forth in claim 11 whereinthe first vehicle has drive rollers rotatable on the beams and the blocks to propel the additional vehicle on the track and wherein the beams and the blocks have side surfaces and wherein the first vehicle has guides disposable relative to the side surfaces of the beams and the blocks to retain the first vehicle on the track during the movement of the first vehicle on the track.
  • 13. A method of providing a controlled operation of a plurality of toy vehicles and an additional vehicle, including the steps of:providing each of the toy vehicles in the plurality an address different from the addresses provided for the other toy vehicles, providing the additional toy vehicle with an address different from the addresses of the vehicles in the plurality, providing a support structure for the movement of the additional vehicle on the support structure in first and second opposite directions, providing a plurality of pads each having a first control operable to provide for an addressing of any one of the vehicles and each having second controls operable to provide for a movement, and operations other than a movement, of the addressed vehicle, providing a central station for sequentially communicating to all of the vehicles the addresses provided by the operation of the first controls in the pads in the plurality and the movement and other operations of the addressed vehicles as represented by the operations of the second controls in the pads, providing for an addressing by the central station of the vehicles in accordance with the addressing of the vehicles by the first controls in the pads, and providing in the central station for a movement and other operations of each of the addressed vehicles in accordance with the operation of the second controls in the pad addressing the vehicle.
  • 14. A method as set forth in claim 13 whereinthe central station provides for the addressing by each of the pads only of the vehicles not addressed by any of the other pads.
  • 15. A method as set forth in claim 13 whereinthe central station has a memory for indicating the vehicle being addressed by each of the pads and wherein the central station removes from the memory the addressing of each of the vehicles by the pad addressing the vehicle when the pad addressing the vehicle addresses another one of the vehicles or fails to address the vehicle within a particular period of time.
  • 16. A method as set forth in claim 13 whereinthe structure defines a loop for providing a movement of the additional vehicle only in opposite directions in the loop defined by the second support structure.
  • 17. A method as set forth in claim 16 whereinthe structure defines a single track in the loop and wherein the additional vehicle is a monorail which rides on the single track.
  • 18. A method as set forth in claim 17 whereinthe central station provides for the addressing by each of the pads only of the vehicles not addressed by any of the other pads and wherein the central station has a memory for indicating the vehicle being addressed by each of the pads and wherein the central station removes from the memory the addressing of each of the vehicles by the pad addressing the vehicle when the pad addressing the vehicle addresses another one of the vehicles or fails to address the vehicle within a particular period of time.
  • 19. In combination,a vehicle having an individual address and movable in a selective one of two opposite directions, a structure for supporting the vehicle for movement of the vehicle in the selective one of the two opposite direction, and a pad manually operable to address the vehicle and to provide commands for moving the addressed vehicle and for performing functions other than the movement of the vehicle.
  • 20. In a combination as set forth in claim 19,a key providing an individual address, the additional vehicle including a socket for receiving the key and for providing an address corresponding to the address provided by the key, the vehicle being constructed to be addressed by the pad when the key is in the socket.
  • 21. In a combination as set forth in claim 20,the structure being constructed to be formed from a plurality of first elements each having first and second detents and second elements each having the second detents to provide for an intercoupling of the first detents on the first elements with the second detents on the second elements, the vehicle including a motor and rollers driven by the motor for rotation on the track, the first and second elements having side surfaces defining the width of the track, the vehicle including guides disposed relative to the side surfaces of the track for maintaining the vehicle on the track during the movement of the vehicle on the track, and the guides constituting second rollers closely spaced relative to the side surfaces of the tracks and rotatable in the same direction as the movement of the vehicle on the track.
  • 22. In a combination as set forth in claim 19,the structure being constructed to be formed from a plurality of first elements each having first and second detents and second elements each having the second detents to provide for an intercoupling of the first detents on the first elements with the second detents on the second elements.
  • 23. In a combination as set forth in claim 22,the vehicle including a motor and rollers driven by the motor for rotation on the track, the first and second elements having side surfaces defining the width of the track, the vehicle including guides disposed relative to the side surfaces of the track for maintaining the vehicle on the track during the movement of the vehicle on the track.
  • 24. A method of providing a controlled operation of a first toy vehicle, including the steps of:providing an address for the first toy vehicle, providing for the first toy vehicle characteristics for movement in a selective one of two opposite directions, providing for a first intercoupling of first individual ones of first elements and first individual ones of second elements to form a first structure for holding additional toy vehicles for movement in any desired direction, providing for an intercoupling of individual ones of the first elements and individual ones of second elements to form a structure for holding the first toy vehicle for movement at each instant in a selective one of the first and second opposite directions, and providing for the transmission to each of the first toy vehicle and the additional toy vehicles of signals indicating the address of the vehicle and indicating the desired movement of the addressed vehicle and indicating the performance of functions by the vehicle other than the movement of the vehicle.
  • 25. A method as set forth in claim 24, including the steps of,providing a key indicating an individual address, the first toy vehicle and the additional toy vehicles being constructed to receive the key and to operate in conjunction with the key to provide the individual address indicated by the received key.
  • 26. A method as set forth in claim 24 whereineach of the first elements constitutes a beam having male and female detents and each of the second elements constitutes a block having the female detents and wherein the male detents in the first elements releasably intercouple with the female detents in the second elements.
  • 27. A method of providing a controlled operation of a toy vehicle, including the steps of:providing for the toy vehicle an individual address, providing for the toy vehicle characteristics for movement in a selective one of two opposite directions, providing a structure for holding the toy vehicle for movement at each instant in a selective one of the first and second opposite directions, providing a pad constructed to address the vehicle, providing for an operation of the pad to produce, for transmission, first signals addressing the vehicle and second signals providing for a movement of the addressed vehicle in accordance with the characteristics of the second signals and the characteristics provided for the addressed vehicle and third signals for providing for an operation of the vehicle other than the movement of the vehicle, and providing for the reception of the transmitted signals by the vehicle and for the movement of the addressed vehicle in accordance with the characteristics of the second signals and the characteristics provided for the addressed vehicle and providing for the operation of the vehicle, other than the movement of the vehicle, in accordance with the characteristics of the third signal.
  • 28. A method as set forth in claim 27, including the steps of:providing a key with ribs in an individual pattern indicating an individual address, and providing for a disposition of the key in a socket in the toy vehicle to provide for the toy vehicle an address represented by the ribs in the key.
  • 29. A method as set forth in claim 28 whereinthe vehicle is constructed to transfer play elements to and from the vehicle.
  • 30. A method of providing a controlled operation of a toy vehicle, including the steps of:providing an address for the first toy vehicle, providing for the toy vehicle characteristics for movement in a selective one of two opposite directions, providing a structure for holding the toy vehicle for movement at each instant in a selective one of the first and second opposite directions, providing a key indicating an individual address, the vehicle being constructed to receive the key and to operate in conjunction with the key to provide the individual address indicated by the key, and providing for a disposition of the key in the vehicle to provide for the vehicle the address indicated by the key.
  • 31. A method as set forth in claim 30, including the step of:forming the structure from a plurality of the beams each having male and female detents intercoupled with a plurality of the blocks each having the female detents, the structure constituting a track and the vehicle constituting a monorail movable on the track.
  • 32. A method as set forth in claim 31, including the steps of:providing the vehicle with rotary members movable on the track, the beams and the blocks having a pair of spaced side walls defining the width of the track, and disposing guides in closely spaced relationship to the side walls of the beams and the blocks to maintain the vehicle on the track during the movement of the vehicle on the track.
  • 33. A method as set forth in claim 32, whereinthe guides constitute rollers disposable against the side surfaces of the track and rotatable against the side surfaces of the track in accordance with the rotation of the rotary members on the track, the rollers being normally spaced from the side surfaces of the track.
  • 34. A method as set forth in claim 32 whereinthe guides constitute rollers, and wherein the additional vehicle is provided with rotary members movable on the track, and wherein the beams and the blocks have a pair of spaced side walls defining the width of the track, and wherein guides are disposed in closely spaced relationship to the side walls of the beams and the blocks to maintain the vehicle on the track during the movement of the vehicle on the track, and wherein  the guides are rollers movable in the same direction as the direction of movement of the vehicle on the track.
Parent Case Info

This application is a division of application Ser. No. 09/487,010 filed Jan. 19, 2000 (now U.S. Pat. 6,450,856 B1.)

US Referenced Citations (4)
Number Name Date Kind
3722135 Jacobson Mar 1973 A
4334221 Rosenhagen et al. Jun 1982 A
5098110 Yang Mar 1992 A
6450856 Aldred et al. Sep 2002 B1