1. An automotive door lock device, comprising: a housing having a housing body including an opening portion, and a cover portion formed integrally with the housing body for opening and closing the opening portion; an operating lever member placed in the housing and having an operating lever connecting portion; and operation means having an operation connecting portion to be connected to the operating lever connecting portion,
wherein the cover portion of the housing has an arc-shaped projecting portion for preventing a dropout of the operation connecting portion of the operation means, and the projecting portion is located along an arc-shaped moving locus of the operation connecting portion.
2. The automotive door lock device recited in claim 1, wherein the projecting portion prevents the dropout by inhibiting movement in a direction to separate from the operating lever connecting portion to which the operation connecting portion is connected.
3. The automotive door lock device recited in claim 1, wherein a convex portion capable of contacting the operating lever member is formed on the housing at a position facing the projecting portion of the cover portion in a closed state.
4. The automotive door lock device recited in claim 3, wherein the convex portion prevents the dropout by inhibiting movement in a direction to separate from the operation connecting portion to which the operating lever connecting portion is connected.
5. The automotive door lock device recited in claim 1, wherein either one of the operating lever connecting portion and the operation connecting portion is constituted by a concave portion, and the other one of the operating lever connecting portion and the operation connecting portion is a spherical portion to be attached and connected to the concave portion.
6. The automotive door lock device recited in claim 5, wherein the operating lever connecting portion is the concave portion and the operation connecting portion is the spherical portion held slidably by the concave portion.
7. The automotive door lock device recited in claim 5, wherein a tapered surface is formed on an opening periphery of the concave portion and a projection is formed inside the opening periphery.
8. The automotive door lock device recited in claim 5, wherein an opening of the concave portion faces the opening portion of the housing body.
9. The automotive door lock device recited in claim 5, wherein space sectioned by the concave portion is hemispherical.
10. The automotive door lock device recited in claim 1, wherein the housing body and the cover portion have distance keeping means for keeping the distance between the housing body and the cover portion constant when the cover portion is in a closed state.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. An electrosurgical generator which supplies a high-frequency, high-voltage electrosurgical output signal to tissue to ornate an electrosurgical effect, the electrosurgical generator including a transformer having a primary winding and a secondary winding, the secondary winding conducting the electrosurgical output signal, the transformer inducing voltage and current signals between the primary and secondary windings that are distorted relative to one another due to inherent characteristics of the transformer at the high frequency and high-voltage of the electrosurgical output signal, the electrosurgical generator further comprising:
a primary voltage sensor connected to the primary winding to supply a primary voltage sense signal related to the voltage across the primary winding;
a primary current sensor connected to the primary winding to supply a primary current sense signal related to the current conducted through the primary winding; and
a simulation circuit receptive of the primary voltage sense signal and the primary current sense signal, the simulation circuit executing a mathematical simulation algorithm to transform at least one of the primary voltage and current sense signals into at least one simulated signal which accurately represents an actual value of the voltage or current of the electrosurgical output signal conducted by the secondary winding of the transformer, the transformation of the one of the primary voltage and current sense signals by the simulation algorithm correcting the distortion introduced by the transformer.
2. An electrosurgical generator as defined in claim 1, wherein:
the simulation algorithm executed by the simulation circuit responds to both the primary voltage and current sense signals to supply the one simulated signal.
3. An electrosurgical generator as defined in claim 1, wherein:
the simulation circuit executes at least one simulation algorithm which responds to both the primary voltage and current sense signals to supply simulated signals which accurately represent accurate values of both the voltage and current of the electrosurgical output signal.
4. An electrosurgical generator as defined in claim 1, wherein:
the simulation circuit responds to both the primary voltage and current sense signals and executes one simulation algorithm to supply one simulated signal which accurately represents the actual value of the voltage of the electrosurgical output signal conducted by the secondary winding of the transformer and executes another simulation algorithm which accurately represents the actual value of the current of the electrosurgical output signal.
5. An electrosurgical generator as defined In claim 4, wherein:
one of the simulation algorithms is derived from a lumped parameter, equivalent circuit model over a range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied; and
the other of the simulation algorithms is derived from iterative numerical comparison of the primary voltage and current sensed signals and the voltage and current of the electrosurgical output signal over a range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied.
6. An electrosurgical generator as defined in claim 1, wherein:
the simulation circuit comprises an array of logic gates which receive the primary voltage and current sense signals and execute the simulation algorithm in response to the primary voltage and current sense signals.
7. An electrosurgical generator as defined In claim 1, wherein:
the primary current and voltage sensors supply the primary current and voltage sense signals as analog signals, respectively; and further comprising:
an analog-to-digital converter for converting the primary voltage and current sense analog signals into primary voltage and current sense digital signals, respectively; and wherein:
the simulation circuit comprises an array of logic gates which receive the primary voltage and current sense digital signals and execute the simulation algorithm directly in response to the primary voltage and current sense digital signals.
8. An electrosurgical generator as defined in claim 1, wherein:
the simulation circuit comprises an array of logic gates which am programmed to execute the simulation algorithm.
9. An electrosurgical generator as defined in claim 1, wherein:
the transformer comprises part of a sensor, the secondary winding of the transformer conducts the electrosurgical output signal, and the primary winding of the transformer conducts at least one of the primary voltage and current sense signals.
10. An electrosurgical generator as defined in claim 1, wherein:
the transformer comprises a power output transformer of the electrosurgical generator, the secondary winding of the power output transformer supplies the electrosurgical output signal, and the primary winding of the power output transformer conducts an input voltage and an input current applied to induce the electrosurgical output signal from the secondary winding.
11. An electrosurgical generator as defined in claim 10, wherein:
the primary voltage sensor comprises a portion of the primary winding.
12. An electrosurgical generator as defined in claim 10, wherein:
the power output transformer comprises part of a power output circuit of the electrosurgical generator which also includes isolating capacitors connected in series with the secondary winding; and
the simulation circuit is responsive to both the primary voltage sense signal and the primary current sense signal and executes at least one mathematical simulation algorithm to transform the primary voltage and current sense signals into at least one simulated signal which accurately represents an actual value of voltage or current of the electrosurgical output signal conducted by the power output circuit, the simulation algorithm correcting for distortion introduced by the power output transformer and for any signal anomalies introduced by the isolation capacitors.
13. An electrosurgical generator as defined in claim 12, wherein:
the simulation algorithm is derived from a lumped parameter, equivalent circuit model of the power output circuit over a range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied.
14. An electrosurgical generator as defined in claim 13, wherein:
the simulation algorithm derived from the lumped parameter, equivalent circuit model supplies the simulated signal representative of voltage of the electrosurgical output signal.
15. An electrosurgical generator as defined in claim 12, wherein the simulation algorithm comprises a mathematical function which has a first variable formed by the primary-voltage sense signal, a second variable formed by the primary current sense signal, and a set of coefficients determined from an equivalent circuit model of the power output circuit.
16. An electrosurgical generator as defined in claim 12, wherein:
the simulation algorithm Is derived from iterative numerical comparison of the primary voltage and current sense signals and voltage and current of the electrosurgical output signal over a range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied.
17. An electrosurgical generator as defined in claim 12, wherein the simulation algorithm comprises a mathematical function which has a first variable formed by the primary voltage sense signal, a second variable formed by the primary current sense signal, and a set of coefficients determined by an iterative numerical comparison of the primary voltage and current sense signals and voltage and current of the electrosurgical output signal over a range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied:
18. An electrosurgical generator as defined in claim 12, wherein:
the simulation circuit executes at least one simulation algorithm which supplies a simulated signal that accurately represents the power of the electrosurgical output signal.
19. An electrosurgical generator as defined in claim 18, wherein:
the simulated signal supplied represents a mathematical product of accurate values of the voltage and current of the electrosurgical output signal.
20. An electrosurgical generator as defined in claim 18, wherein:
the simulated signal supplied represents a mathematical product of the primary voltage sense signal and the primary current sense signal from which is subtracted a value representative of core losses of the transformer.
21. A method of accurately simulating at least one of voltage or current of an electrosurgical output signal conducted by a secondary winding of a transformer which has inherent characteristics that distort the respective values of the current and voltage induced between a primary winding and the secondary winding of the transformer, comprising:
sensing a primary voltage across the primary winding of the transformer and supplying a primary voltage sense signal related to the voltage across the primary winding;
sensing a primary current conducted through the primary winding of the transformer and supplying a primary current sense signal related to the current conducted through the primary winding;
executing a mathematical simulation algorithm in response to the primary voltage and current sensed signals to transform at least one of the primary voltage and current sensed signals into at least one simulated signal which accurately represents an actual value of the voltage or current of the electrosurgical output signal conducted by the secondary winding of the transformer; and
compensating for the distortion Induced by the transformer in the mathematical simulation algorithm.
22. A method as defined in claim 21, further comprising:
executing the simulation algorithm to supply simulated signals which accurately represent actual values of both the voltage and current of the electrosurgical output signal.
23. A method as defined in claim 21, further comprising:
executing one simulation algorithm to supply one simulated signal which accurately represents the actual value of the voltage of the electrosurgical output signal conducted by the secondary winding of the transformer; and
executing another simulation algorithm to supply another simulated signal which accurately represents the actual value of the current of the electrosurgical output signal.
24. A method as defined in claim 23, further comprising:
deriving one of the simulation algorithms from a lumped parameter, equivalent circuit model over a range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied; and
deriving the other of the simulation algorithms from iterative numerical comparison of the primary voltage and current sensed signals and the voltage and current of the electrosurgical output signal over the range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied.
25. A method as defined in claim 21, further comprising:
executing the simulation algorithm in an array of logic gatos in response to the primary voltage and current sense signals.
26. A method as defined In claim 21 wherein the transformer comprises part of a sensor and the primary winding of the transformer conducts at least one of the primary voltage and current sense signals.
27. A method as defined in claim 21, wherein the transformer comprises a power output transformer of the electrosurgical generator, the secondary winding of the power output transformer supplies the electrosurgical output signal, and the primary winding of the power output transformer conducts an input voltage and an input current applied to induce the electrosurgical output signal from the secondary winding.
28. A method as defined in claim 27, wherein the power output transformer comprises part of a power output circuit of the electrosurgical generator which also Includes isolating capacitors connected In series with the secondary winding.
29. A method as defined in claim 28, further comprising:
deriving the simulation algorithm from a lumped parameter, equivalent circuit modal of the power output circuit over a range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied.
30. A method as defined in claim 28, further comprising:
forming the simulation algorithm as a mathematical function which supplies the simulated signal from a first variable formed by the primary voltage sense signal and from a second variable formed by the primary current sense signal and a set of coefficients determined from one of either an equivalent circuit model of the transformer or iterative numerical comparison of the voltage and current signals from the primary winding and the voltage and current of the electrosurgical output signal over a range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied.
31. A method as defined in claim 21, further comprising:
deriving the simulation algorithm from iterative numerical comparison of the primary voltage and current sense signals and the voltage and current of the electrosurgical output signal over a range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied.
32. A method as defined in claim 21, further comprising:
forming the mathematical algorithm as a mathematical function which supplies the simulated signal from a first variable formed by the primary voltage sense signal and a second variable formed by the primary current sense signal and a set of coefficients determined by an iterative numerical comparison of the primary voltage arid current sense signals and the voltage and current of the electrosurgical output signal over a range of load parameters representative of the electrosurgical loads to which the electrosurgical output signal is normally applied.
33. A method as defined in claim 21, further comprising:
executing at least one simulation algorithm which supplies a simulated signal that accurately represents the power of the electrosurgical output signal.
34. A method as defined in claim 33, wherein the simulated signal supplied represents a mathematical product of accurate values of the voltage and current of the electrosurgical output signal.
35. A method as defined in claim 33, wherein the a simulated signal supplied represents a mathematical product of the primary voltage sense signal and the primary current sense signal from which is subtracted a value representative of core losses of the transformer.