IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0298645
(2014-06-06)
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등록번호 |
US-9849723
(2017-12-26)
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발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
Martin Spencer Garthwaite
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인용정보 |
피인용 횟수 :
0 인용 특허 :
9 |
초록
▼
Disclosed is a cyclic mechanism for engaging or disengaging a switch with the stage of the cycle being determined by a height to which a first object is lifted relative to a second object. The mechanism has few moving parts, is inexpensive to manufacture, is reliable, can be incorporated into a wide
Disclosed is a cyclic mechanism for engaging or disengaging a switch with the stage of the cycle being determined by a height to which a first object is lifted relative to a second object. The mechanism has few moving parts, is inexpensive to manufacture, is reliable, can be incorporated into a wide range of devices or structures, and operates as an incident to raising or lowering a first object relative to a second.
대표청구항
▼
1. A kinematic state machine comprising: a first rigid body with a first surface, wherein the first surface defines a first coordinate function;a second rigid body with a second surface, wherein the second surface defines a second coordinate function;a switch with a switch geometry; whereinthe first
1. A kinematic state machine comprising: a first rigid body with a first surface, wherein the first surface defines a first coordinate function;a second rigid body with a second surface, wherein the second surface defines a second coordinate function;a switch with a switch geometry; whereinthe first and second rigid bodies have an allowed range of motion relative to one another and, together, form a composite surface, wherein at least a portion of the composite surface contacts the switch geometry and wherein the composite surface and the switch geometry define a composite coordinate function, wherein the composite coordinate function varies with the relative position of the first and second rigid bodies;the kinematic state machine may be in a plurality of states comprising a first state and a second state, wherein a plurality of events cause the composite coordinate function to transmit a plurality of forces at a plurality of force vectors to the switch, thereby moving the switch between a plurality of potential energy wells and causing the kinematic state machine to transition between the plurality of states;when the kinematic state machine is in the first state in the plurality of states, movement of the first and second rigid bodies relative to one another through a first state transition causes a first event in the plurality of events, wherein the first event transitions the kinematic state machine from the first state to the second state in the plurality of states;when the kinematic state machine is in the second state in the plurality of states, movement of the first and second rigid bodies relative to one another through a second state transition causes a second event in the plurality of events, wherein the second event transitions the kinematic state machine from the second state to the first state in the plurality of states,wherein in the first event the composite coordinate function transmits a first force in the plurality of forces at a first force vector in the plurality of force vectors to the switch and transitions the switch from a first potential energy well in the plurality of potential energy wells over a potential energy barrier into a second potential energy well in the plurality of energy wells and in the second event the composite coordinate function transmits a second force in the plurality of forces at a second force vector in the plurality of force vectors to the switch and over the potential energy barrier. 2. The kinematic state machine of claim 1 wherein the first state comprises when the switch is in the first potential energy well and does not transmit a load greater than a force produced by a weight of the switch, through the switch, to the second rigid body and the second state comprises when the switch is in the second potential energy well and transmits the load greater than the force produced by the weight of the switch from the first rigid body, through the switch, to the second rigid body. 3. The kinematic state machine of claim 2 wherein the first state further comprises when the first rigid body and the second rigid body rest upon an external surface. 4. The kinematic state machine of claim 2 wherein the second state further comprises the first rigid body resting upon the switch and, via the switch, upon the second rigid body. 5. The kinematic state machine of claim 1 further comprising a third state in the plurality of states, wherein when the kinematic state machine is in the third state, the switch transmits a third force in the plurality of forces from the first rigid body, through the switch, to the second rigid body, wherein the third force lifts the second rigid body. 6. The kinematic state machine of claim 1 wherein the range of motion allows the second rigid body to be lifted vertically, relative to the first rigid body. 7. The kinematic state machine of claim 1 wherein the switch is rotated during the first event. 8. The kinematic state machine of claim 1 wherein the switch is subject only to i) gravity, ii) the plurality of forces, or iii) a load from the first rigid body, wherein the load is transferred from the first surface to the second surface by the switch. 9. A kinematic state machine comprising: a first rigid body with a first surface, where the first surface defines a first coordinate function;a second rigid body with a second surface, wherein the second surface defines a second coordinate function;a switch with a switch geometry; whereinthe first and second rigid bodies have an allowed range of motion relative to one another and, together, form a composite surface, wherein at least a portion of the composite surface contacts the switch geometry and wherein the composite surface and the switch geometry define a composite coordinate function, wherein the composite coordinate function varies with the relative position of the first and second rigid bodies within the allowed range of motion;wherein the kinematic state machine may be in a plurality of states comprising a first state, a second state and a third state, wherein a plurality of events cause the composite coordinate function to transmit a plurality of forces at a plurality of force vectors to the switch, thereby moving the switch between a plurality of potential energy wells and causing the kinematic state machine to transition between the plurality of states; whereinwhen the kinematic state machine is in the first state in the plurality of states, movement within the allowed range of motion of the first and second rigid bodies relative to one another through a first state transition causes a first event in the plurality of events, wherein the first event transitions the kinematic state machine from the first state to the second state in the plurality of states;when the kinematic state machine is in the second state in the plurality of states, movement within the allowed range of motion of the first and second rigid bodies relative to one another through a second state transition causes a second event in the plurality of events, wherein the second event transitions the kinematic state machine from the second state to the third state in the plurality of states; andwhen the kinematic state machine is in the third state in the plurality of states, movement within the allowed range of motion of the first and second rigid bodies relative to one another through a third state transition causes a third event in the plurality of events, wherein the third event transitions the kinematic state machine from the third state to the first state in the plurality of states: whereinin the first event the composite coordinate function transmits a first force in the plurality of forces at a first force vector in the plurality of force vectors to the switch geometry and transitions the switch from a position intermediate between a first potential energy well in the plurality of potential energy wells and a potential energy barrier over the potential energy barrier into a second potential energy well in the plurality of potential energy wells, in the second event the composite coordinate function transmits a second force in the plurality of forces at a second force vector in the plurality of force vectors to the switch geometry and transitions the switch from the second potential energy well into the first potential energy well over the potential energy barrier; and in the third event the composite coordinate function transmits a third force in the plurality of forces at a third force vector in the plurality of force vectors to the switch geometry and transitions the switch out of the first potential energy well into the position intermediate between the first potential energy well and the potential energy barrier. 10. The kinematic state machine of claim 9 wherein the first state comprises when the switch is intermediate between the first potential energy well and the potential energy barrier and does not transmit a load greater than a force produced by a weight of the switch, through the switch, to the second rigid body; the second state comprises when the switch is in the second potential energy well; and the third state comprises when the switch is in the first potential energy well and transmits the load greater than the force produced by the weight of the switch from the first rigid body, through the switch, to the second rigid body. 11. The kinematic state machine of claim 10 wherein the first state further comprises the first rigid body and the second rigid body resting upon an external surface. 12. The kinematic state machine of claim 10 wherein the third state further comprises the first rigid body resting upon the switch and, via the switch, upon the second rigid body. 13. The kinematic state machine of claim 9 further comprising a fourth state in the plurality of states, wherein when the kinematic state machine is in the fourth state, the switch transmits a fourth force in the plurality of forces from the first rigid body, through the switch, to the second rigid body, wherein the fourth force lifts the second rigid body. 14. The kinematic state machine of claim 9 wherein the switch has a round vertical cross-section. 15. The kinematic state machine of claim 14 wherein the potential energy barrier is provided by a vertical apex in the composite surface, wherein the switch must surmount the vertical apex during the first event. 16. The kinematic state machine of claim 15 wherein vertical translation of the first rigid body produces a fifth force in the plurality of forces at a horizontal force vector in the plurality of force vectors on the switch, wherein the fifth force and horizontal force vector is converted to vertical translation of the switch by the vertical apex. 17. The kinematic state machine of claim 9 wherein the switch has a non-round vertical cross-section or a non-uniform density. 18. The kinematic state machine of claim 17 wherein the potential energy barrier is provided by the third event, wherein the third event rotates the switch and raises a potential energy of the switch. 19. The kinematic state machine of claim 18 wherein the third event obtains energy for the third event to occur from vertical translation of the first rigid body while the second rigid body remains stationary. 20. The kinematic state machine of claim 18 wherein the third event obtains energy for the third event to occur from vertical translation of the first rigid body while the second rigid body rotates about an axle. 21. The kinematic state machine of claim 18 wherein the switch rotates about a contact between the switch and the second rigid body, energy for the third event comes from vertical translation of the first rigid body, and rotation of the switch is produced by the third force and third force vector acting on the switch and the switch being constrained by the contact between the switch and the second rigid body. 22. The kinematic state machine of claim 9 wherein the switch is subject only to i) gravity, ii) the plurality of forces, or iii) a load from the first rigid body, wherein the load is transferred from the first surface to the second surface by the switch. 23. The kinematic state machine of claim 9 wherein the second event allows the switch to lose potential energy and drop into the first potential energy well. 24. The kinematic state machine of claim 9 wherein the range of motion allows the second rigid body to be lifted vertically, relative to the first rigid body. 25. The kinematic state machine of claim 9 wherein the first rigid body and the second rigid body are attached at an axle. 26. The kinematic state machine of claim 25 wherein the range of motion allows the second rigid body to rotate about the axle. 27. The kinematic state machine of claim 9 wherein the first and second rigid bodies may have any shape i) consistent with the allowed range of motion and ii) which does not impinge on the area occupied by the switch. 28. The kinematic state machine of claim 9 wherein the kinematic state machine is embedded in a larger object.
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