IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0029850
(2002-01-03)
|
발명자
/ 주소 |
- Dreiman, Nelik I.
- Bunch, Rick L.
|
출원인 / 주소 |
- Tecumseh Products Company
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
6 인용 특허 :
15 |
초록
▼
A hermetic refrigerant compressor including a compressor mechanism and a motor including a stator surrounded by a rotor attached to a crankshaft drivingly linked to the compressor mechanism. A first gap is formed between the rotor and stator, and a second gap is formed between the stator and the com
A hermetic refrigerant compressor including a compressor mechanism and a motor including a stator surrounded by a rotor attached to a crankshaft drivingly linked to the compressor mechanism. A first gap is formed between the rotor and stator, and a second gap is formed between the stator and the compressor mechanism. During compressor operation discharge gas expelled from the gas compression chamber travels through a discharge passage and a discharge plenum, and then through the first and second gaps. The rotor spinning during compressor operation causing a spinning vortex of refrigerant gas to occur in the discharge plenum, the vortex having an outer flow path of warmer gas and an inner flow path of cooler gas. The outer flow path of warmer gas generally travels through the second gap and the inner flow path of cooler gas generally travels through the first gap for enhanced motor cooling.
대표청구항
▼
A hermetic refrigerant compressor including a compressor mechanism and a motor including a stator surrounded by a rotor attached to a crankshaft drivingly linked to the compressor mechanism. A first gap is formed between the rotor and stator, and a second gap is formed between the stator and the com
A hermetic refrigerant compressor including a compressor mechanism and a motor including a stator surrounded by a rotor attached to a crankshaft drivingly linked to the compressor mechanism. A first gap is formed between the rotor and stator, and a second gap is formed between the stator and the compressor mechanism. During compressor operation discharge gas expelled from the gas compression chamber travels through a discharge passage and a discharge plenum, and then through the first and second gaps. The rotor spinning during compressor operation causing a spinning vortex of refrigerant gas to occur in the discharge plenum, the vortex having an outer flow path of warmer gas and an inner flow path of cooler gas. The outer flow path of warmer gas generally travels through the second gap and the inner flow path of cooler gas generally travels through the first gap for enhanced motor cooling. ight from said light source off the user's eye, and to determine said gaze information using said distance and predetermined calibration data which defines a relationship between said distance and the point on the image plane the user is currently looking at. 2. The instrument according to claim 1, wherein said eyepiece comprises a lens system for increasing the apparent field of view of the optical instrument. 3. The instrument according to claim 2, wherein said lens associated with said light source is operable to focus the light from said light source substantially at the focal point of said eyepiece lens system. 4. The instrument according to claim 2, wherein said objective lens is operable to form said viewable image at an image plane which is located substantially at the focal point of said eyepiece lens system. 5. The instrument according to claim 1, wherein said imaging transducer is located off the optical axis of said optical instrument. 6. The instrument according to claim 5, further comprising a beam splitter for reflecting the light reflected from the front of the user's eye onto said imaging transducer. 7. The instrument according to claim 1, wherein said imaging transducer comprises a CCD sensor. 8. The instrument according to claim 7, wherein said CCD sensor comprises a 2D CCD sensor. 9. The instrument according to claim 7, wherein said imaging transducer further comprises a lens for focussing the light from the user's eye onto said CCD sensor. 10. The instrument according to claim 9, wherein said imaging transducer lens is operable to focus at a plane located at a predetermined distance in front of said eyepiece. 11. The instrument according to claim 9, wherein said imaging transducer further comprises autofocus means for automatically focussing said imaging transducer lens on the front surface of said user's eye. 12. The instrument according to claim 11, comprising means for varying said calibration data in dependence upon a current focal point of said imaging transducer lens. 13. The instrument according to claim 1, further comprising one or more further light sources for illuminating the user's eye. 14. The instrument according to claim 13, wherein said one or more further light sources are located around an outer rim of said eyepiece. 15. The instrument according to claim 14, wherein two pairs of additional light sources are provided around said rim. 16. The apparatus according to claim 1, wherein said light source is operable to generate near infra-red light. 17. The instrument according to claim 16, wherein said light source comprises an 850 nm LED. 18. The instrument according to claim 1, wherein said processing means is operable to determine said pupil centre by thresholding the image to locate the boundary between the pupil and the iris and by identifying the centre of the circle which best fits the located boundary. 19. The instrument according to claim 1, wherein said calibration data is generated in advance during a calibration routine in which the user looks at different preselected locations on the image plane and in which the processing means is operable to correlate the determined distances between pupil center and light source reflection from the corresponding electrical image signals with the preselected locations. 20. The instrument according to claim 1, wherein said calibration data comprises a scaling factor for scaling said distance between said two locations. 21. The instrument according to claim 20, wherein said calibration data comprises a scaling factor for an x component of said distance and a scaling factor for a y component of said distance. 22. The instrument according to claim 21, wherein said calibration data further comprises an offset for an x direction and an offset for a y direction. 23. The instrument according to claim 1, wherein at least two further light sources are provided for illuminating the user's eye and wherein the instrument further comprises illumination cont rol means for selectively illuminating different ones of said at least two further light sources and wherein said imaging transducer is operable to generate an image of the user's eye when different ones of said at least two further light sources are illuminated and is operable to generate a highlight-free image by combining the images output from said transducer when the different light sources are illuminated. 24. The instrument according to claim 23, wherein said processing means is operable to determine the centre of said pupil from said highlight-free image. 25. The instrument according to claim 23, wherein said illumination control means is operable to illuminate a first pair of said at least two further light sources during a first time interval and is operable to illuminate a second different pair of said at least two further light sources during a second time interval and wherein said imaging transducer is operable to generate an image of the user's eye during said first time interval and during said second time interval. 26. The instrument according to claim 25, wherein said illumination control means is operable to switch on said light source for outputting light through said eyepiece during said first time interval and wherein said processing means is operable to determine the location of said reflection of said light from said light source by locating reflections from said first pair of further light sources, estimating a position of said reflection of said light from said light source based on said reflection locations from said first pair of further light sources, and thresholding the image around said estimated position. 27. The apparatus according to claim 1, wherein said light source for outputting light through said eyepiece is located off the axis of said optical instrument. 28. The instrument according to claim 27, further comprising a beam splitter located on the optical axis of the instrument for reflecting the light from said source onto the user's eye. 29. The instrument according to claim 1, wherein said imaging transducer is operable to output an image signal a plurality of times per second and wherein said processing means is operable to determine repeatedly said gaze information from said images. 30. The instrument according to claim 29, wherein said imaging transducer is operable to output an image signal between ten and fifty times per second. 31. The instrument according to claim 1, wherein said controllable function is automatic focussing of the objective lens so that the point in the field of view which the user is looking at is in focus. 32. The instrument according to claim 1, wherein said controllable function is movement of the optical instrument over the object being viewed. 33. The instrument according to claim 1, wherein said controllable function is content of a display which is optically superimposed on the field of view of the instrument. 34. The instrument according to claim 1, which is a microscope. 35. The instrument according to claim 1, which is a camera. 36. A method of operating an optical instrument for forming a viewable image of an object, comprising the steps of: providing an objective lens for forming a viewable image of the object at an image plane; viewing the viewable image through an eyepiece; sensing a direction of gaze of a user viewing the image; and controlling a controllable function of the optical instrument in dependence upon the sensed direction of gaze; characterised in that said sensing step comprises the steps of: (i) using a light source to output light through said eyepiece towards the user's eye; (ii) providing a lens associated with said light source for causing the light from said source to be substantially collimated when it exits said eyepiece towards said user's eye; (iii) providing an imaging transducer for imaging the front of the user's eye through said eyepiece for generating an electrical image signal of the front of the user's eye;
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