Temperature-controlled enclosures and temperature control system using the same
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F25D-023/12
F25D-011/00
F25D-017/04
F25D-017/08
H05K-007/20
G01N-015/00
G01K-001/00
F16L-005/02
F16L-017/06
출원번호
US-0612028
(2009-11-04)
등록번호
US-8408020
(2013-04-02)
발명자
/ 주소
Cole, Sr., Kenneth M.
Conroy, Michael F.
Lowerre, Edward
Pelrin, James
출원인 / 주소
Temptronic Corporation
대리인 / 주소
Lathrop & Gage LLP
인용정보
피인용 횟수 :
3인용 특허 :
16
초록▼
A temperature chamber in which a device is tested is connected to a temperature-controlled air source for controlling temperature of the chamber. The temperature chamber includes thermal insulation formed on side surfaces of the chamber. A universal manifold adaptor for directing the temperature-con
A temperature chamber in which a device is tested is connected to a temperature-controlled air source for controlling temperature of the chamber. The temperature chamber includes thermal insulation formed on side surfaces of the chamber. A universal manifold adaptor for directing the temperature-controlled air directly to a device being tested is connected to the chamber. The temperature chamber also includes an exhaust system. A self-closing cable feed-through module is connected to an outer surface of the chamber. The feed-through module includes a first portion and a second portion, wherein cables are fed through the first and second portions into the chamber in a first position and the first and second portions form a leak tight seal around the cables in a second position.
대표청구항▼
1. A temperature chamber, comprising: a chamber in which a device can be located, the chamber being connectable to a temperature-controlled source for providing a temperature-controlled fluid to the chamber to control temperature of the chamber; anda self-closing cable feed-through module being moun
1. A temperature chamber, comprising: a chamber in which a device can be located, the chamber being connectable to a temperature-controlled source for providing a temperature-controlled fluid to the chamber to control temperature of the chamber; anda self-closing cable feed-through module being mounted to an outer surface of the chamber, the self-closing cable feed-through module comprising: a first portion;a second portion; anda joint at which the second portion is rotatable relative to the first portion to create an opening between the first portion and the second portion, wherein cables are feedable through the joint and the first and second portions into an opening in the chamber in an opened first position of the self-closing cable feed-through module, and the first and second portions form a leak tight seal around the cables in a closed second position of the self-closing cable feed-through module. 2. The temperature chamber of claim 1, further comprising an exhaust system for exhausting the fluid from the chamber. 3. The temperature chamber of claim 2, wherein the exhaust system comprises a plurality of exhaust ports connected internal to the chamber and a single outlet port for allowing the fluid to exit the chamber. 4. The temperature chamber of claim 2, wherein the exhaust system comprises a plurality of exhaust ports connected internal to the chamber and multiple outlet ports for allowing the fluid to exit the chamber. 5. The temperature chamber of claim 2, wherein the exhaust system comprises an exhaust port centrally located in the bottom of the chamber and an outlet port for allowing the fluid to exit the rear of the chamber. 6. The temperature chamber of claim 2, wherein a location of an exhaust is selectable by a user. 7. The temperature chamber of claim 1, further comprising thermal insulation material. 8. The temperature chamber of claim 7, wherein the chamber has a hood configuration. 9. The temperature chamber of claim 8, wherein a thin layer of silicone is bonded to the surface of the thermal insulation material. 10. The temperature chamber of claim 7, wherein the thermal insulation material is positioned between an outer shell of the chamber and an inner liner of the chamber. 11. The temperature chamber of claim 10, wherein the inner liner of the chamber is thermally decoupled from the outer shell. 12. The temperature chamber of claim 11, wherein the chamber has a clamshell configuration in which a top portion of the chamber is connected to a bottom portion of the chamber such that the top portion is opened in order to load the device into the chamber. 13. The temperature chamber of claim 11, wherein the chamber has a front-loader configuration in which a front portion of the chamber is connected to a rear portion of the chamber such that the front portion is opened in order to load the device into the chamber. 14. The temperature chamber of claim 1, wherein the fluid is air. 15. The temperature chamber of claim 1, further comprising a universal manifold adaptor for directing the temperature-controlled fluid directly to the device. 16. The temperature chamber of claim 15, wherein interchangeable manifolds are attachable to the universal manifold to direct the fluid to the device. 17. The temperature chamber of claim 16, wherein a manifold comprises a single horizontal tube with multiple small holes for discharge of the fluid. 18. The temperature chamber of claim 16, wherein a manifold comprises a plurality of horizontal tubes with multiple small holes for discharge of the fluid. 19. The temperature chamber of claim 16, wherein a manifold has a shower-head configuration to provide uniform distribution of the fluid. 20. The temperature chamber of claim 16, wherein a manifold comprises a baffle system. 21. A temperature control system for controlling temperature of a device, comprising: a chamber in which the device can be located;a temperature-controlled source connected to the chamber for providing a temperature-controlled fluid to the chamber to control temperature in the chamber; anda self-closing cable feed-through module being mounted to an outer surface of the chamber, the self-closing cable feed-through module comprising: a first portion;a second portion; anda joint at which the second portion is rotatable relative to the first portion to create an opening between the first portion and the second portion, wherein cables are feedable through the joint and the first and second portions into an opening in the chamber in an opened first position of the self-closing cable feed-through module, and the first and second portions form a leak tight seal around the cables in a closed second position of the self-closing cable feed-through module. 22. The temperature control system of claim 21, further comprising a universal manifold adaptor for directing the temperature-controlled fluid directly to the device. 23. The temperature control system of claim 22, wherein interchangeable manifolds are attachable to the universal manifold to direct the fluid to the device. 24. The temperature control system of claim 23, wherein a manifold comprises a single horizontal tube with multiple small holes for discharge of the fluid. 25. The temperature control system of claim 23, wherein a manifold comprises a plurality of horizontal tubes with multiple small holes for discharge of the fluid. 26. The temperature control system of claim 23, wherein a manifold has a shower-head configuration to provide uniform distribution of the fluid. 27. The temperature control system of claim 23, wherein a manifold comprises a baffle system. 28. The temperature control system of claim 21, further comprising an exhaust system for exhausting the fluid from the chamber. 29. The temperature control system of claim 28, wherein the exhaust system comprises a plurality of exhaust ports connected internal to the chamber and a single outlet port for allowing the fluid to exit the chamber. 30. The temperature control system of claim 28, wherein the exhaust system comprises a plurality of exhaust ports connected internal to the chamber and multiple outlet ports for allowing the fluid to exit the chamber. 31. The temperature control system of claim 28, wherein the exhaust system comprises an exhaust port centrally located in the bottom of the chamber and an outlet port for allowing the fluid to exit the rear of the chamber. 32. The temperature control system of claim 28, wherein a location of an exhaust is selectable by a user. 33. The temperature control system of claim 21, further comprising thermal insulation material formed on side surfaces of the chamber. 34. The temperature control system of claim 33, wherein the chamber has a hood configuration. 35. The temperature control system of claim 34, wherein a thin layer of silicone is bonded to the surface of the thermal insulation material. 36. The temperature control system of claim 33, wherein the chamber has a clamshell configuration in which a top portion of the chamber is connected to a bottom portion of the chamber such that the top portion is opened in order to load the device being tested into the chamber. 37. The temperature control system of claim 36, wherein the thermal insulation material is positioned between an outer shell of the chamber and an inner liner of the chamber. 38. The temperature control system of claim 37, wherein the inner liner of the chamber is thermally decoupled from the outer shell. 39. The temperature control system of claim 33, wherein the chamber has a front-loader configuration in which a front portion of the chamber is connected to a rear portion of the chamber such that the front portion is opened in order to load the device into the chamber. 40. The temperature control system of claim 39, wherein the thermal insulation material is positioned between an outer shell of the front-loader and an inner liner of the chamber. 41. The temperature control system of claim 40, wherein the inner liner of the chamber is thermally decoupled from the outer shell. 42. The temperature control system of claim 21, wherein the fluid is air. 43. The temperature control system of claim 21, wherein the self-closing cable feed-through module is removable from the chamber. 44. The temperature control system of claim 21, wherein the self-closing cable feed-through module is installed into a wall of the chamber, and clamps secure the self-closing cable feed-through module to the chamber. 45. The temperature control system of claim 21, further comprising a dry air source for providing dry air to the self-closing cable feed-through module. 46. The temperature control system of claim 21, wherein the self-closing cable feed-through module further comprises insulation. 47. An environmental control system, comprising: a chamber in which a device can be located; anda self-closing cable feed-through module, comprising: a first portion;a second portion; anda joint for rotating the second portion relative to the first portion to create an opening between the first portion and the second portion, wherein cables are feedable through the joint and the first and second portions into an opening in the chamber in an opened first position of the module, the self-closing cable feed-through module being mounted to an outer surface of the chamber, and the first and second portions form a leak tight seal around the cables in a closed second position of the module. 48. The environmental control system of claim 47, wherein the self-closing cable feed-through module is removable from the chamber. 49. The environmental control system of claim 47, further comprising a dry air source for providing dry air to the self-closing cable feed-through module. 50. The environmental control system of claim 47, wherein the self-closing cable feed-through module further comprises insulation. 51. The environmental control system of claim 47, wherein the environmental control system is a temperature control system for controlling a temperature of the device.
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