One-Handed Joystick For Excavators

Abstract

A one-handed joystick for excavators allows an operator to make all necessary motions with a single hand and arm for manipulating an excavator tool. The one-handed joystick includes a rotatable cylinder bar, a rotatable ring and an industrial joystick base. The rotatable cylinder bar is grasped with a hand. The industrial base is moved front to back, or right to left. The following are preferable hand/arm motions. A downward hand curl is associated with a bucket digging motion; an upward hand curl is associated with a bucket dump; a forearm forward push is associated with a boom/stick extension; a forearm reward pull is associated with a boom/stick retraction; a left-hand movement is associated with swinging the excavator left; a right-hand movement is associated with swinging the excavator right; a clockwise hand twist is associated with a stick/boom extension; and a counter clockwise hand twist is associated with a stick/boom retraction.

Claims

1. A joystick for operating a tool of an excavator, comprising: a joystick base providing a first electrical output for left to right movement, a second electrical output for forward to backward movement; an outer base ring extends from a top of said joystick base; and a rotatable cylinder bar is rotatably retained in said outer base ring, said rotatable cylinder bar is sized to be grasped, said rotatable cylinder bar includes a lengthwise axis, said rotatable cylinder bar rotates about said lengthwise axis, wherein rotation of said rotatable cylinder bar in one direction causes the tool to have a first movement, rotation of said rotatable cylinder bar in an opposite direction causes the tool to have a second movement.

2. The joystick for operating a tool of an excavator of claim 1 wherein: a left movement of said joystick base is associated with swinging the excavator in a leftward direction.

3. The joystick for operating a tool of an excavator of claim 1 wherein: a right movement of said joystick base is associated with swinging the excavator in a rightward direction.

4. The joystick for operating a tool of an excavator of claim 1 wherein: a forward movement of said joystick base is associated with a boom extension or a stick extension.

5. The joystick for operating a tool of an excavator of claim 1 wherein: a rear movement of said joystick base is associated with a boom retraction or a stick retraction.

6. The joystick for operating a tool of an excavator of claim 1 wherein: a SAE-ISO pattern switch is formed in said rotatable cylinder bar for switching from a SAE pattern to an ISO pattern.

7. The joystick for operating a tool of an excavator of claim 1, further comprising: a hydraulic controller receiving entry from an input device to change a motion association between the tool and said joystick.

8. The joystick for operating a tool of an excavator of claim 1 wherein: the tool is a bucket, said rotation of said rotatable cylinder bar in the one direction is associated with a digging motion of the bucket; and said rotation of said rotatable cylinder bar in the opposite direction is associated with dumping the bucket.

9. A joystick for operating a tool of an excavator, comprising: a joystick base providing an electrical output for left, right, forward and backward movement; an outer base ring extends from a top of said joystick base, wherein moving said joystick base to the left causes a first tool to have a first movement, moving said joystick base to the right causes the first tool to have a second movement, moving said joystick base forward causes a second tool to have a third movement, moving said joystick base backward causes the second tool to have a fourth movement; an inner base ring is rotatably retained in an inner perimeter of said outer base ring; and a cylinder bar is retained in said inner base ring, said cylinder bar is sized to be grasped, wherein rotation of said inner base ring in one direction causes a third tool to have a fifth movement, rotation of said inner base ring in an opposite direction causes the third tool to have a sixth movement.

10. The joystick for operating a tool of an excavator of claim 9 wherein: the first tool is an excavator base, a left movement of said joystick base is associated with swinging the excavator base in a leftward direction.

11. The joystick for operating a tool of an excavator of claim 9 wherein: the first tool is an excavator base, a right movement of said joystick base is associated with swinging the excavator base in a rightward direction.

12. The joystick for operating a tool of an excavator of claim 9 wherein: the second tool is a stick or a boom, a forward movement of said joystick base is associated with a boom extension or a stick extension.

13. The joystick for operating a tool of an excavator of claim 9 wherein: the second tool is a stick or a boom, a rear movement of said joystick base is associated with a boom retraction or a stick retraction.

14. (canceled)

15. The joystick for operating a tool of an excavator of claim 9, further comprising: a hydraulic controller receiving entry from an input device to change a motion association between the tool and said joystick.

16. The joystick for operating a tool of an excavator of claim 9 wherein: the tool is a boom or a stick, rotation of said inner base ring in the one direction is associated with extending the stick or the boom; and rotation of said inner base ring in the opposite direction is associated with retracting the stick or the boom.

17. A joystick for operating a tool of an excavator, comprising: a joystick base providing a first electrical output for left to right movement, a second electrical output for forward to backward movement; an outer base ring extends from a top of said joystick base; an inner base ring is rotatably retained in an inner perimeter of said outer base ring, wherein rotation of said inner base ring in one direction is associated with a first movement of the tool, rotation of said inner base ring in an opposite direction is associated with a second movement of the tool; and a rotatable cylinder bar is rotatably retained in said inner base ring, said rotatable cylinder bar is sized to be grasped, said rotatable cylinder bar includes a lengthwise axis, said rotatable cylinder bar rotates about said lengthwise axis, wherein rotation of said rotatable cylinder bar in one direction is associated with a third movement of the tool, rotation of said rotatable cylinder bar in an opposite direction is associated with a fourth movement of the tool.

18. The joystick for operating a tool of an excavator of claim 17, further comprising: a hydraulic controller receiving entry from an input device to change a motion association between the tool and said joystick.

19. The joystick for operating a tool of an excavator of claim 17 wherein: the tool is a bucket, said rotation of said rotatable cylinder bar in the one direction is associated with a digging motion of the bucket; and said rotation of said rotatable cylinder bar in the opposite direction is associated with dumping the bucket.

20. (canceled)

21. The joystick for operating a tool of an excavator of claim 17 wherein: said lengthwise axis of said rotational cylinder bar is disposed in a horizontal orientation during rotation.

22. The joystick for operating a tool of an excavator of claim 17 wherein: an axis of said inner base ring rotates parallel with an axis of said outer base ring.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] FIG. 1 is a perspective view of an improved joystick in accordance with the present invention.

[0014] FIG. 2 is a perspective view of an improved joystick illustrating rotation of a ring portion and a rotatable cylinder bar in accordance with the present invention.

[0015] FIG. 3 is a perspective view of an improved joystick illustrating x-axis motion and y-axis motion of a rotary upper handle in accordance with the present invention.

[0016] FIG. 4 is a perspective view of a rotatable cylinder bar of an improved joystick in accordance with the present invention.

[0017] FIG. 5 is a perspective view of a ring portion of an improved joystick in accordance with the present invention.

[0018] FIG. 6 is a perspective view of an outer base ring of an improved joystick in accordance with the present invention.

[0019] FIG. 7 is a cross-sectional view of a rotary upper handle of an improved joystick in accordance with the present invention.

[0020] FIG. 8 is a schematic diagram of left and right SAE joystick motion patterns.

[0021] FIG. 9 is a schematic diagram of left and right ISO joystick motion patterns.

[0022] FIG. 10 is a table of hand and forearm motions associated with movements of an excavator of an improved joystick in accordance with the present invention.

[0023] FIG. 11 is a schematic diagram illustrating how to reprogram a hydraulic controller to change the association of motions of an improved joystick with an excavator in accordance with the present invention.

[0024] FIG. 12 is a side view of an excavator with labeled arrows that correspond to movements of an improved joystick in FIGS. 2-3 and a table in FIG. 10 to provide a pattern similar to SAE in accordance with the present invention.

[0025] FIG. 13 is a side view of an excavator with labeled arrows that correspond to movements of an improved joystick in FIGS. 2-3 and a table in FIG. 10 to provide a pattern similar to ISO in accordance with the present invention.

[0026] FIG. 14 is a top view of an excavator with labeled arrows that correspond to movements of an improved joystick in FIGS. 2-3 and a table in FIG. 10 in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0027] With reference now to the drawings, and particularly to FIG. 1, there is shown a perspective view of an improved joystick 1. With reference to FIGS. 2-3, the improved joystick 1 preferably includes a state-of-the art joystick base for heavy equipment (industrial joystick base) 100 with x-axis and y-axis movement, and a rotary upper handle 10. There are numerous ways in the art of implementing a two-axis joystick. Therefore, a further explanation of the operation of a two-axis joystick is not necessary.

[0028] With reference to FIGS. 4-7, the rotary upper handle 10 preferably includes an outer base ring 12, a rotatable ring 14, a position sensor 16 and a base portion 18. A bottom of the base portion 18 extends from a top of the industrial joystick base 100. The outer base ring 12 extends upward from a top of the base portion 18. The rotatable ring 14 is rotatably retained in an inner perimeter of the outer base ring 12. The outer base ring 12 preferably includes a pair of opposing grooves 20 for preventing axial movement of the rotatable ring 14. One of the opposing grooves 20 is preferably retained in a detachable ring 22. The detachable ring 22 is secured to one side of the outer base ring with any suitable attachment device, such as a plurality of fasteners 23, a bonding agent, snap arrangement or any other suitable attachment method.

[0029] A sensor cavity 25 is formed in an inner perimeter of the outer base ring 12 and below a bottom of the pair of opposing grooves 20 for receiving the position sensor 16. The position sensor 16 is preferably a PCAP (projective capacitive) touch sensor. However, other types of sensors may also be used. The position sensor 16 must be curved along a lengthwise axis or be flexible to conform to an inner perimeter of the sensor cavity 25. The rotatable ring 14 preferably includes a ring portion 24 and a rotatable cylinder bar 26. A pair of opposing bosses 30 preferably extend inward from an inner perimeter of the ring portion 24. A through hole 32 is formed through the pair of opposing bosses 30.

[0030] The ring portion 24 preferably includes first and second halves 27, 29. Each end of the first half 27 includes an attachment area 31 for attaching an opposing half. Each end of the second half 29 includes an attachment area 33 for attaching an opposing half. The first and second halves 27, 29 may be attached to each other with fasteners, adhesive, snaps or any other suitable attachment method. A pair of opposing bosses 30 preferably extend inward from an inner perimeter of the ring portion 24. A through hole 32 is formed through the pair of opposing bosses 30. The rotatable cylinder bar 26 includes an inner diameter 34. The inner diameter 34 of the rotatable cylinder bar 26 is sized to rotatably receive an outer diameter of the pair of opposing bosses 30. A contact plug 36 is preferably pressed into the inner diameter 34 of the rotatable cylinder bar 26. However, the contact plug 36 may be molded into the inner perimeter of the rotatable cylinder bar 26. The contact plug 36 preferably includes a biased center conductive contact 38 and a biased peripheral conductive contact 40. However, the contact plug 36 may only include a center conductive contact 38, if an electrical output from the rotatable cylinder bar 26 is not needed. A compression spring 44 and set screw 46 are preferably used to bias the center and peripheral conductive contacts against the position sensor 16. The heights of the center and peripheral conductive contacts 38, 40 are equal.

[0031] The ring portion 24 with the rotatable cylinder bar 26 retained therein is inserted into the inner perimeter of the outer base ring 12. The detachable ring 22 is secured to one side of the outer base ring 12 with the plurality of fasteners 23. Sensor wiring (not shown) from the position sensor 16 is run down a side of the outer base ring 12 or molded into the rotary upper handle 10. However, the ring portion 24 may not rotate relative to the outer base ring 12 for some applications. The rotatable cylinder bar 26 would rotate with the center and peripheral conductive contacts 38, 40. The sensor wiring is connected to a suitable ring controller 42 for determining the location of the rotatable cylinder bar 26 and the ring portion 24. The position sensor 16 includes a grid arrangement, which allows a rotational position and an angular position of the ring portion 24 and the rotatable cylinder bar 26 to be determined. When the rotatable cylinder bar 26 is rotated in either a clockwise or counterclockwise direction, the center conductive contact 38 will remain relatively stationary, while the peripheral conductive contact 40 will rotate about the center conductive contact 38. The rotational motion of the rotatable cylinder bar 26 will be picked-up by the ring controller 42 and could be used to control curling or dumping of a bucket. When the rotatable ring 14 is rotated in either a clockwise or counterclockwise direction the angular motion will be processed by the ring controller 42 and could be used to control boom-up or boom-down. Movement of the rotary upper handle 10 in the X-axis and the Y-axis will also be processed by the ring controller 42 and used to operate the appropriate attachment. Buttons, toggle switches, thumb wheels and other control devices may also be added to the rotary upper handle 10.

[0032] FIG. 8 illustrates how left and right SAE joystick motion patterns control the motion of excavator elements. FIG. 9 illustrates how left and right ISO joystick motion patterns control the motion of excavator elements. FIG. 10 provides a list of preferred motions of the improved joystick 1 associated with motions of an excavator. However, the listed motions of the improved joystick 1 could be associated with different motions of the excavator. With reference to FIG. 11, the new association of motions could be made by reprogramming a hydraulic controller 48 through an input device, such as a cab touch screen 50 or a human-machine interface (HMI) device 52. The hydraulic controller 48 operates a hydraulic operated component, such as an excavator tool 108.

[0033] With reference to FIG. 12 in SAE mode, it is preferable to associate a downward hand curl “C” to a bucket 114 digging motion; and an upward hand curl “D” with a bucket 114 dump. It is preferable to associate a forearm forward push “E” to a stick 112 extension; and a forearm reward pull “F” to a stick retraction 112. With reference to FIG. 14, it is preferable to associate a hand movement to the left “G” to swinging the excavator 106 left; and a hand movement to the right “H” to swinging the excavator 106 right. It is preferable to associate a clockwise hand twist “A” to a boom 110 extension; and a counter clockwise hand twist “B” to a boom 110 retraction.

[0034] With reference to FIG. 13 in ISO mode, it is preferable to associate a downward hand curl “C” to a bucket 114 digging motion; and an upward hand curl “D” with a bucket 114 dump. It is preferable to associate a forearm forward push “E” to a boom 110 extension; and a forearm reward pull “F” to a boom 110 retraction. With reference to FIG. 14, it is preferable to associate a hand movement to the left “G” to swinging the excavator 106 left; and a hand movement to the right “H” to swinging the excavator 106 right. It is preferable to associate a clockwise hand twist “A” to a stick 112 extension; and a counter clockwise hand twist “B” to a stick 112 retraction. However, the aforementioned hand and arm motions could be associated with other movements of the boom, stick and bucket through electrical switches and circuits in a harness to activate and deactivate different solenoids to perform the related functions.

[0035] A SAE/ISO pattern switch 54 is preferably located on the rotatable cylinder bar 26 for changing the operation to SAE or ISO. The SAE/ISO pattern switch uses electrical switches and circuits in a harness to activate and deactivate different solenoids to perform the related functions through an electrical hydraulic control system. An enable/disable switch 56 is used to deactivate electrical output from rotation of the rotatable ring 14, while allowing electrical output from the rotatable cylinder bar 26. The SAE/ISO pattern switch 54 and the enable/disable switch 56 may be implemented with any suitable push button switch. Entry of improved joystick 1 and excavator 106 motion associations in the hydraulic controller 48 through the cab touch screen 50 or HMI device 52 preferably over rides the SAE/ISO pattern switch 54 and the enable/disable switch 56.

[0036] While particular embodiments of the invention have been shown and described, it will be obvious to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspects, and therefore, the aim in the appended claims is to cover all such changes and modifications as fall within the true spirit and scope of the invention.